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Randomized controlled trial

April 17, 2023

A randomized controlled trial (or randomized control trial;[2] RCT) is a form of scientific experiment used to control factors not under direct experimental control. Examples of RCTs are clinical trials that compare the effects of drugs, surgical techniques, medical devices, diagnostic procedures or other medical treatments.

Flowchart of four phases (enrollment, allocation, intervention, follow-up, and data analysis) of a parallel randomized trial of two groups (in a controlled trial, one of the interventions serves as the control), modified from the CONSORT (Consolidated Standards of Reporting Trials) 2010 Statement[1]

Participants who enroll in RCTs differ from one another in known and unknown ways that can influence study outcomes, and yet cannot be directly controlled. By randomly allocating participants among compared treatments, an RCT enables statistical control over these influences. Provided it is designed well, conducted properly, and enrolls enough participants, an RCT may achieve sufficient control over these confounding factors to deliver a useful comparison of the treatments studied.

Definition and examples

An RCT in clinical research typically compares a proposed new treatment against an existing standard of care; these are then termed the 'experimental' and 'control' treatments, respectively. When no such generally accepted treatment is available, a placebo may be used in the control group so that participants are blinded to their treatment allocations. This blinding principle is ideally also extended as much as possible to other parties including researchers, technicians, data analysts, and evaluators. Effective blinding experimentally isolates the physiological effects of treatments from various psychological sources of bias.

The randomness in the assignment of participants to treatments reduces selection bias and allocation bias, balancing both known and unknown prognostic factors, in the assignment of treatments.[3] Blinding reduces other forms of experimenter and subject biases.

A well-blinded RCT is considered the gold standard for clinical trials. Blinded RCTs are commonly used to test the efficacy of medical interventions and may additionally provide information about adverse effects, such as drug reactions. A randomized controlled trial can provide compelling evidence that the study treatment causes an effect on human health.[4]

The terms "RCT" and "randomized trial" are sometimes used synonymously, but the latter term omits mention of controls and can therefore describe studies that compare multiple treatment groups with each other in the absence of a control group.[5] Similarly, the initialism is sometimes expanded as "randomized clinical trial" or "randomized comparative trial", leading to ambiguity in the scientific literature.[6][7] Not all RCTs are randomized controlled trials (and some of them could never be, as in cases where controls would be impractical or unethical to use). The term randomized controlled clinical trial is an alternative term used in clinical research;[8] however, RCTs are also employed in other research areas, including many of the social sciences.

History

The first reported clinical trial was conducted by James Lind in 1747 to identify treatment for scurvy.[9] The first blind experiment was conducted by the French Royal Commission on Animal Magnetism in 1784 to investigate the claims of mesmerism. An early essay advocating the blinding of researchers came from Claude Bernard in the latter half of the 19th century.[vague] Bernard recommended that the observer of an experiment should not have knowledge of the hypothesis being tested. This suggestion contrasted starkly with the prevalent Enlightenment-era attitude that scientific observation can only be objectively valid when undertaken by a well-educated, informed scientist.[10] The first study recorded to have a blinded researcher was conducted in 1907 by W. H. R. Rivers and H. N. Webber to investigate the effects of caffeine.[11]

Randomized experiments first appeared in psychology, where they were introduced by Charles Sanders Peirce and Joseph Jastrow in the 1880s,[12] and in education.[13][14][15]

In the early 20th century, randomized experiments appeared in agriculture, due to Jerzy Neyman[16] and Ronald A. Fisher. Fisher's experimental research and his writings popularized randomized experiments.[17]

The first published Randomized Controlled Trial in medicine appeared in the 1948 paper entitled "Streptomycin treatment of pulmonary tuberculosis", which described a Medical Research Council investigation.[18][19][20] One of the authors of that paper was Austin Bradford Hill, who is credited as having conceived the modern RCT.[21]

Trial design was further influenced by the large-scale ISIS trials on heart attack treatments that were conducted in the 1980s.[22]

By the late 20th century, RCTs were recognized as the standard method for "rational therapeutics" in medicine.[23] As of 2004, more than 150,000 RCTs were in the Cochrane Library.[21] To improve the reporting of RCTs in the medical literature, an international group of scientists and editors published Consolidated Standards of Reporting Trials (CONSORT) Statements in 1996, 2001 and 2010, and these have become widely accepted.[1][3] Randomization is the process of assigning trial subjects to treatment or control groups using an element of chance to determine the assignments in order to reduce the bias.

Ethics

Although the principle of clinical equipoise ("genuine uncertainty within the expert medical community... about the preferred treatment") common to clinical trials[24] has been applied to RCTs, the ethics of RCTs have special considerations. For one, it has been argued that equipoise itself is insufficient to justify RCTs.[25] For another, "collective equipoise" can conflict with a lack of personal equipoise (e.g., a personal belief that an intervention is effective).[26] Finally, Zelen's design, which has been used for some RCTs, randomizes subjects before they provide informed consent, which may be ethical for RCTs of screening and selected therapies, but is likely unethical "for most therapeutic trials."[27][28]

Although subjects almost always provide informed consent for their participation in an RCT, studies since 1982 have documented that RCT subjects may believe that they are certain to receive treatment that is best for them personally; that is, they do not understand the difference between research and treatment.[29][30] Further research is necessary to determine the prevalence of and ways to address this "therapeutic misconception".[30]

The RCT method variations may also create cultural effects that have not been well understood.[31] For example, patients with terminal illness may join trials in the hope of being cured, even when treatments are unlikely to be successful.

Trial registration

In 2004, the International Committee of Medical Journal Editors (ICMJE) announced that all trials starting enrolment after July 1, 2005, must be registered prior to consideration for publication in one of the 12 member journals of the committee.[32] However, trial registration may still occur late or not at all.[33][34] Medical journals have been slow in adapting policies requiring mandatory clinical trial registration as a prerequisite for publication.[35]

Classifications

By study design

One way to classify RCTs is by study design. From most to least common in the healthcare literature, the major categories of RCT study designs are:[36]

  • Parallel-group – each participant is randomly assigned to a group, and all the participants in the group receive (or do not receive) an intervention.[37][38]
  • Crossover – over time, each participant receives (or does not receive) an intervention in a random sequence.[39][40]
  • Cluster – pre-existing groups of participants (e.g., villages, schools) are randomly selected to receive (or not receive) an intervention.[41][42]
  • Factorial – each participant is randomly assigned to a group that receives a particular combination of interventions or non-interventions (e.g., group 1 receives vitamin X and vitamin Y, group 2 receives vitamin X and placebo Y, group 3 receives placebo X and vitamin Y, and group 4 receives placebo X and placebo Y).

An analysis of the 616 RCTs indexed in PubMed during December 2006 found that 78% were parallel-group trials, 16% were crossover, 2% were split-body, 2% were cluster, and 2% were factorial.[36]

By outcome of interest (efficacy vs. effectiveness)

Main article: Pragmatic clinical trial

RCTs can be classified as "explanatory" or "pragmatic."[43] Explanatory RCTs test efficacy in a research setting with highly selected participants and under highly controlled conditions.[43] In contrast, pragmatic RCTs (pRCTs) test effectiveness in everyday practice with relatively unselected participants and under flexible conditions; in this way, pragmatic RCTs can "inform decisions about practice."[43]

By hypothesis (superiority vs. noninferiority vs. equivalence)

Another classification of RCTs categorizes them as "superiority trials", "noninferiority trials", and "equivalence trials", which differ in methodology and reporting.[44] Most RCTs are superiority trials, in which one intervention is hypothesized to be superior to another in a statistically significant way.[44] Some RCTs are noninferiority trials "to determine whether a new treatment is no worse than a reference treatment."[44] Other RCTs are equivalence trials in which the hypothesis is that two interventions are indistinguishable from each other.[44]

Randomization

The advantages of proper randomization in RCTs include:[45]

  • "It eliminates bias in treatment assignment," specifically selection bias and confounding.
  • "It facilitates blinding (masking) of the identity of treatments from investigators, participants, and assessors."
  • "It permits the use of probability theory to express the likelihood that any difference in outcome between treatment groups merely indicates chance."

There are two processes involved in randomizing patients to different interventions. First is choosing a randomization procedure to generate an unpredictable sequence of allocations; this may be a simple random assignment of patients to any of the groups at equal probabilities, may be "restricted", or may be "adaptive." A second and more practical issue is allocation concealment, which refers to the stringent precautions taken to ensure that the group assignment of patients are not revealed prior to definitively allocating them to their respective groups. Non-random "systematic" methods of group assignment, such as alternating subjects between one group and the other, can cause "limitless contamination possibilities" and can cause a breach of allocation concealment.[46]

However empirical evidence that adequate randomization changes outcomes relative to inadequate randomization has been difficult to detect.[47]

Procedures

The treatment allocation is the desired proportion of patients in each treatment arm.

An ideal randomization procedure would achieve the following goals:[48]

  • Maximize statistical power, especially in subgroup analyses. Generally, equal group sizes maximize statistical power, however, unequal groups sizes may be more powerful for some analyses (e.g., multiple comparisons of placebo versus several doses using Dunnett's procedure[49] ), and are sometimes desired for non-analytic reasons (e.g., patients may be more motivated to enroll if there is a higher chance of getting the test treatment, or regulatory agencies may require a minimum number of patients exposed to treatment).[50]
  • Minimize selection bias. This may occur if investigators can consciously or unconsciously preferentially enroll patients between treatment arms. A good randomization procedure will be unpredictable so that investigators cannot guess the next subject's group assignment based on prior treatment assignments. The risk of selection bias is highest when previous treatment assignments are known (as in unblinded studies) or can be guessed (perhaps if a drug has distinctive side effects).
  • Minimize allocation bias (or confounding). This may occur when covariates that affect the outcome are not equally distributed between treatment groups, and the treatment effect is confounded with the effect of the covariates (i.e., an "accidental bias"[45][51]). If the randomization procedure causes an imbalance in covariates related to the outcome across groups, estimates of effect may be biased if not adjusted for the covariates (which may be unmeasured and therefore impossible to adjust for).

However, no single randomization procedure meets those goals in every circumstance, so researchers must select a procedure for a given study based on its advantages and disadvantages.

Simple

This is a commonly used and intuitive procedure, similar to "repeated fair coin-tossing."[45] Also known as "complete" or "unrestricted" randomization, it is robust against both selection and accidental biases. However, its main drawback is the possibility of imbalanced group sizes in small RCTs. It is therefore recommended only for RCTs with over 200 subjects.[52]

Restricted

To balance group sizes in smaller RCTs, some form of "restricted" randomization is recommended.[52] The major types of restricted randomization used in RCTs are:

  • Permuted-block randomization or blocked randomization: a "block size" and "allocation ratio" (number of subjects in one group versus the other group) are specified, and subjects are allocated randomly within each block.[46] For example, a block size of 6 and an allocation ratio of 2:1 would lead to random assignment of 4 subjects to one group and 2 to the other. This type of randomization can be combined with "stratified randomization", for example by center in a multicenter trial, to "ensure good balance of participant characteristics in each group."[3] A special case of permuted-block randomization is random allocation, in which the entire sample is treated as one block.[46] The major disadvantage of permuted-block randomization is that even if the block sizes are large and randomly varied, the procedure can lead to selection bias.[48] Another disadvantage is that "proper" analysis of data from permuted-block-randomized RCTs requires stratification by blocks.[52]
  • Adaptive biased-coin randomization methods (of which urn randomization is the most widely known type): In these relatively uncommon methods, the probability of being assigned to a group decreases if the group is overrepresented and increases if the group is underrepresented.[46] The methods are thought to be less affected by selection bias than permuted-block randomization.[52]

Adaptive

At least two types of "adaptive" randomization procedures have been used in RCTs, but much less frequently than simple or restricted randomization:

  • Covariate-adaptive randomization, of which one type is minimization: The probability of being assigned to a group varies in order to minimize "covariate imbalance."[52] Minimization is reported to have "supporters and detractors"[46] because only the first subject's group assignment is truly chosen at random, the method does not necessarily eliminate bias on unknown factors.[3]
  • Response-adaptive randomization, also known as outcome-adaptive randomization: The probability of being assigned to a group increases if the responses of the prior patients in the group were favorable.[52] Although arguments have been made that this approach is more ethical than other types of randomization when the probability that a treatment is effective or ineffective increases during the course of an RCT, ethicists have not yet studied the approach in detail.[53]

Allocation concealment

Main article: Allocation concealment

"Allocation concealment" (defined as "the procedure for protecting the randomization process so that the treatment to be allocated is not known before the patient is entered into the study") is important in RCTs.[54] In practice, clinical investigators in RCTs often find it difficult to maintain impartiality. Stories abound of investigators holding up sealed envelopes to lights or ransacking offices to determine group assignments in order to dictate the assignment of their next patient.[46] Such practices introduce selection bias and confounders (both of which should be minimized by randomization), possibly distorting the results of the study.[46] Adequate allocation concealment should defeat patients and investigators from discovering treatment allocation once a study is underway and after the study has concluded. Treatment related side-effects or adverse events may be specific enough to reveal allocation to investigators or patients thereby introducing bias or influencing any subjective parameters collected by investigators or requested from subjects.

Some standard methods of ensuring allocation concealment include sequentially numbered, opaque, sealed envelopes (SNOSE); sequentially numbered containers; pharmacy controlled randomization; and central randomization.[46] It is recommended that allocation concealment methods be included in an RCT's protocol, and that the allocation concealment methods should be reported in detail in a publication of an RCT's results; however, a 2005 study determined that most RCTs have unclear allocation concealment in their protocols, in their publications, or both.[55] On the other hand, a 2008 study of 146 meta-analyses concluded that the results of RCTs with inadequate or unclear allocation concealment tended to be biased toward beneficial effects only if the RCTs' outcomes were subjective as opposed to objective.[56]

Sample size

Main article: Sample size determination

The number of treatment units (subjects or groups of subjects) assigned to control and treatment groups, affects an RCT's reliability. If the effect of the treatment is small, the number of treatment units in either group may be insufficient for rejecting the null hypothesis in the respective statistical test. The failure to reject the null hypothesis would imply that the treatment shows no statistically significant effect on the treated in a given test. But as the sample size increases, the same RCT may be able to demonstrate a significant effect of the treatment, even if this effect is small.[57]

Blinding

Main article: Blinded experiment

An RCT may be blinded, (also called "masked") by "procedures that prevent study participants, caregivers, or outcome assessors from knowing which intervention was received."[56] Unlike allocation concealment, blinding is sometimes inappropriate or impossible to perform in an RCT; for example, if an RCT involves a treatment in which active participation of the patient is necessary (e.g., physical therapy), participants cannot be blinded to the intervention.

Traditionally, blinded RCTs have been classified as "single-blind", "double-blind", or "triple-blind"; however, in 2001 and 2006 two studies showed that these terms have different meanings for different people.[58][59] The 2010 CONSORT Statement specifies that authors and editors should not use the terms "single-blind", "double-blind", and "triple-blind"; instead, reports of blinded RCT should discuss "If done, who was blinded after assignment to interventions (for example, participants, care providers, those assessing outcomes) and how."[3]

RCTs without blinding are referred to as "unblinded",[60] "open",[61] or (if the intervention is a medication) "open-label".[62] In 2008 a study concluded that the results of unblinded RCTs tended to be biased toward beneficial effects only if the RCTs' outcomes were subjective as opposed to objective;[56] for example, in an RCT of treatments for multiple sclerosis, unblinded neurologists (but not the blinded neurologists) felt that the treatments were beneficial.[63] In pragmatic RCTs, although the participants and providers are often unblinded, it is "still desirable and often possible to blind the assessor or obtain an objective source of data for evaluation of outcomes."[43]

Analysis of data

The types of statistical methods used in RCTs depend on the characteristics of the data and include:

Regardless of the statistical methods used, important considerations in the analysis of RCT data include:

  • Whether an RCT should be stopped early due to interim results. For example, RCTs may be stopped early if an intervention produces "larger than expected benefit or harm", or if "investigators find evidence of no important difference between experimental and control interventions."[3]
  • The extent to which the groups can be analyzed exactly as they existed upon randomization (i.e., whether a so-called "intention-to-treat analysis" is used). A "pure" intention-to-treat analysis is "possible only when complete outcome data are available" for all randomized subjects;[67] when some outcome data are missing, options include analyzing only cases with known outcomes and using imputed data.[3] Nevertheless, the more that analyses can include all participants in the groups to which they were randomized, the less bias that an RCT will be subject to.[3]
  • Whether subgroup analysis should be performed. These are "often discouraged" because multiple comparisons may produce false positive findings that cannot be confirmed by other studies.[3]

Reporting of results

The CONSORT 2010 Statement is "an evidence-based, minimum set of recommendations for reporting RCTs."[68] The CONSORT 2010 checklist contains 25 items (many with sub-items) focusing on "individually randomised, two group, parallel trials" which are the most common type of RCT.[1]

For other RCT study designs, "CONSORT extensions" have been published, some examples are:

  • Consort 2010 Statement: Extension to Cluster Randomised Trials[69]
  • Consort 2010 Statement: Non-Pharmacologic Treatment Interventions[70][71]

Relative importance and observational studies

Two studies published in The New England Journal of Medicine in 2000 found that observational studies and RCTs overall produced similar results.[72][73] The authors of the 2000 findings questioned the belief that "observational studies should not be used for defining evidence-based medical care" and that RCTs' results are "evidence of the highest grade."[72][73] However, a 2001 study published in Journal of the American Medical Association concluded that "discrepancies beyond chance do occur and differences in estimated magnitude of treatment effect are very common" between observational studies and RCTs.[74] According to a 2014 Cochrane review, there is little evidence for significant effect differences between observational studies and randomized controlled trials, regardless of design, heterogeneity, or inclusion of studies of interventions that assessed drug effects.[75]

Two other lines of reasoning question RCTs' contribution to scientific knowledge beyond other types of studies:

  • If study designs are ranked by their potential for new discoveries, then anecdotal evidence would be at the top of the list, followed by observational studies, followed by RCTs.[76]
  • RCTs may be unnecessary for treatments that have dramatic and rapid effects relative to the expected stable or progressively worse natural course of the condition treated.[77][78] One example is combination chemotherapy including cisplatin for metastatic testicular cancer, which increased the cure rate from 5% to 60% in a 1977 non-randomized study.[78][79]

Interpretation of statistical results

Like all statistical methods, RCTs are subject to both type I ("false positive") and type II ("false negative") statistical errors. Regarding Type I errors, a typical RCT will use 0.05 (i.e., 1 in 20) as the probability that the RCT will falsely find two equally effective treatments significantly different.[80] Regarding Type II errors, despite the publication of a 1978 paper noting that the sample sizes of many "negative" RCTs were too small to make definitive conclusions about the negative results,[81] by 2005-2006 a sizeable proportion of RCTs still had inaccurate or incompletely reported sample size calculations.[82]

Peer review

Peer review of results is an important part of the scientific method. Reviewers examine the study results for potential problems with design that could lead to unreliable results (for example by creating a systematic bias), evaluate the study in the context of related studies and other evidence, and evaluate whether the study can be reasonably considered to have proven its conclusions. To underscore the need for peer review and the danger of overgeneralizing conclusions, two Boston-area medical researchers performed a randomized controlled trial in which they randomly assigned either a parachute or an empty backpack to 23 volunteers who jumped from either a biplane or a helicopter. The study was able to accurately report that parachutes fail to reduce injury compared to empty backpacks. The key context that limited the general applicability of this conclusion was that the aircraft were parked on the ground, and participants had only jumped about two feet.[83]

Advantages

RCTs are considered to be the most reliable form of scientific evidence in the hierarchy of evidence that influences healthcare policy and practice because RCTs reduce spurious causality and bias. Results of RCTs may be combined in systematic reviews which are increasingly being used in the conduct of evidence-based practice. Some examples of scientific organizations' considering RCTs or systematic reviews of RCTs to be the highest-quality evidence available are:

Notable RCTs with unexpected results that contributed to changes in clinical practice include:

  • After Food and Drug Administration approval, the antiarrhythmic agents flecainide and encainide came to market in 1986 and 1987 respectively.[88] The non-randomized studies concerning the drugs were characterized as "glowing",[89] and their sales increased to a combined total of approximately 165,000 prescriptions per month in early 1989.[88] In that year, however, a preliminary report of an RCT concluded that the two drugs increased mortality.[90] Sales of the drugs then decreased.[88]
  • Prior to 2002, based on observational studies, it was routine for physicians to prescribe hormone replacement therapy for post-menopausal women to prevent myocardial infarction.[89] In 2002 and 2004, however, published RCTs from the Women's Health Initiative claimed that women taking hormone replacement therapy with estrogen plus progestin had a higher rate of myocardial infarctions than women on a placebo, and that estrogen-only hormone replacement therapy caused no reduction in the incidence of coronary heart disease.[66][91] Possible explanations for the discrepancy between the observational studies and the RCTs involved differences in methodology, in the hormone regimens used, and in the populations studied.[92][93] The use of hormone replacement therapy decreased after publication of the RCTs.[94]

Disadvantages

Many papers discuss the disadvantages of RCTs.[77][95][96] Among the most frequently cited drawbacks are:

Time and costs

RCTs can be expensive;[96] one study found 28 Phase III RCTs funded by the National Institute of Neurological Disorders and Stroke prior to 2000 with a total cost of US$335 million,[97] for a mean cost of US$12 million per RCT. Nevertheless, the return on investment of RCTs may be high, in that the same study projected that the 28 RCTs produced a "net benefit to society at 10-years" of 46 times the cost of the trials program, based on evaluating a quality-adjusted life year as equal to the prevailing mean per capita gross domestic product.[97]

The conduct of an RCT takes several years until being published; thus, data is restricted from the medical community for long years and may be of less relevance at time of publication.[98]

It is costly to maintain RCTs for the years or decades that would be ideal for evaluating some interventions.[77][96]

Interventions to prevent events that occur only infrequently (e.g., sudden infant death syndrome) and uncommon adverse outcomes (e.g., a rare side effect of a drug) would require RCTs with extremely large sample sizes and may, therefore, best be assessed by observational studies.[77]

Due to the costs of running RCTs, these usually only inspect one variable or very few variables, rarely reflecting the full picture of a complicated medical situation; whereas the case report, for example, can detail many aspects of the patient's medical situation (e.g. patient history, physical examination, diagnosis, psychosocial aspects, follow up).[98]

Conflict of interest dangers

A 2011 study done to disclose possible conflicts of interests in underlying research studies used for medical meta-analyses reviewed 29 meta-analyses and found that conflicts of interests in the studies underlying the meta-analyses were rarely disclosed. The 29 meta-analyses included 11 from general medicine journals; 15 from specialty medicine journals, and 3 from the Cochrane Database of Systematic Reviews. The 29 meta-analyses reviewed an aggregate of 509 randomized controlled trials (RCTs). Of these, 318 RCTs reported funding sources with 219 (69%) industry funded. 132 of the 509 RCTs reported author conflict of interest disclosures, with 91 studies (69%) disclosing industry financial ties with one or more authors. The information was, however, seldom reflected in the meta-analyses. Only two (7%) reported RCT funding sources and none reported RCT author-industry ties. The authors concluded "without acknowledgment of COI due to industry funding or author industry financial ties from RCTs included in meta-analyses, readers' understanding and appraisal of the evidence from the meta-analysis may be compromised."[99]

Some RCTs are fully or partly funded by the health care industry (e.g., the pharmaceutical industry) as opposed to government, nonprofit, or other sources. A systematic review published in 2003 found four 1986–2002 articles comparing industry-sponsored and nonindustry-sponsored RCTs, and in all the articles there was a correlation of industry sponsorship and positive study outcome.[100] A 2004 study of 1999–2001 RCTs published in leading medical and surgical journals determined that industry-funded RCTs "are more likely to be associated with statistically significant pro-industry findings."[101] These results have been mirrored in trials in surgery, where although industry funding did not affect the rate of trial discontinuation it was however associated with a lower odds of publication for completed trials.[102] One possible reason for the pro-industry results in industry-funded published RCTs is publication bias.[101] Other authors have cited the differing goals of academic and industry sponsored research as contributing to the difference. Commercial sponsors may be more focused on performing trials of drugs that have already shown promise in early stage trials, and on replicating previous positive results to fulfill regulatory requirements for drug approval.[103]

Ethics

If a disruptive innovation in medical technology is developed, it may be difficult to test this ethically in an RCT if it becomes "obvious" that the control subjects have poorer outcomes—either due to other foregoing testing, or within the initial phase of the RCT itself. Ethically it may be necessary to abort the RCT prematurely, and getting ethics approval (and patient agreement) to withhold the innovation from the control group in future RCT's may not be feasible.

Historical control trials (HCT) exploit the data of previous RCTs to reduce the sample size; however, these approaches are controversial in the scientific community and must be handled with care.[104]

In social science

Due to the recent emergence of RCTs in social science, the use of RCTs in social sciences is a contested issue. Some writers from a medical or health background have argued that existing research in a range of social science disciplines lacks rigour, and should be improved by greater use of randomized control trials.

Transport science

Researchers in transport science argue that public spending on programmes such as school travel plans could not be justified unless their efficacy is demonstrated by randomized controlled trials.[105] Graham-Rowe and colleagues[106] reviewed 77 evaluations of transport interventions found in the literature, categorising them into 5 "quality levels". They concluded that most of the studies were of low quality and advocated the use of randomized controlled trials wherever possible in future transport research.

Dr. Steve Melia[107] took issue with these conclusions, arguing that claims about the advantages of RCTs, in establishing causality and avoiding bias, have been exaggerated. He proposed the following eight criteria for the use of RCTs in contexts where interventions must change human behaviour to be effective:

The intervention:

  1. Has not been applied to all members of a unique group of people (e.g. the population of a whole country, all employees of a unique organisation etc.)
  2. Is applied in a context or setting similar to that which applies to the control group
  3. Can be isolated from other activities—and the purpose of the study is to assess this isolated effect
  4. Has a short timescale between its implementation and maturity of its effects

And the causal mechanisms:

  2. Are either known to the researchers, or else all possible alternatives can be tested
  3. Do not involve significant feedback mechanisms between the intervention group and external environments
  4. Have a stable and predictable relationship to exogenous factors
  5. Would act in the same way if the control group and intervention group were reversed

Criminology

A 2005 review found 83 randomized experiments in criminology published in 1982–2004, compared with only 35 published in 1957–1981.[108] The authors classified the studies they found into five categories: "policing", "prevention", "corrections", "court", and "community".[108] Focusing only on offending behavior programs, Hollin (2008) argued that RCTs may be difficult to implement (e.g., if an RCT required "passing sentences that would randomly assign offenders to programmes") and therefore that experiments with quasi-experimental design are still necessary.[109]

Education

RCTs have been used in evaluating a number of educational interventions. Between 1980 and 2016, over 1,000 reports of RCTs have been published.[110] For example, a 2009 study randomized 260 elementary school teachers' classrooms to receive or not receive a program of behavioral screening, classroom intervention, and parent training, and then measured the behavioral and academic performance of their students.[111] Another 2009 study randomized classrooms for 678 first-grade children to receive a classroom-centered intervention, a parent-centered intervention, or no intervention, and then followed their academic outcomes through age 19.[112]

Criticism

A 2018 review of the 10 most cited randomised controlled trials noted poor distribution of background traits, difficulties with blinding, and discussed other assumptions and biases inherent in randomised controlled trials. These include the "unique time period assessment bias", the "background traits remain constant assumption", the "average treatment effects limitation", the "simple treatment at the individual level limitation", the "all preconditions are fully met assumption", the "quantitative variable limitation" and the "placebo only or conventional treatment only limitation".[113]

See also

References

  1. ^ a b c Schulz KF, Altman DG, ((Moher D; for the CONSORT Group)) (2010). "CONSORT 2010 Statement: updated guidelines for reporting parallel group randomised trials". Br Med J. 340: c332. doi:10.1136/bmj.c332. PMC 2844940. PMID 20332509.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  2. ^ Chalmers TC, Smith H Jr, Blackburn B, Silverman B, Schroeder B, Reitman D, Ambroz A (1981). "A method for assessing the quality of a randomized control trial". Controlled Clinical Trials. 2 (1): 31–49. doi:10.1016/0197-2456(81)90056-8. PMID 7261638.
  3. ^ a b c d e f g h i Moher D, Hopewell S, Schulz KF, Montori V, Gøtzsche PC, Devereaux PJ, Elbourne D, Egger M, Altman DG (2010). "CONSORT 2010 explanation and elaboration: updated guidelines for reporting parallel group randomised trials". Br Med J. 340: c869. doi:10.1136/bmj.c869. PMC 2844943. PMID 20332511.
  4. ^ Hannan EL (June 2008). "Randomized clinical trials and observational studies: guidelines for assessing respective strengths and limitations". JACC. Cardiovascular Interventions. 1 (3): 211–7. doi:10.1016/j.jcin.2008.01.008. PMID 19463302.
  5. ^ Ranjith G (2005). "Interferon-α-induced depression: when a randomized trial is not a randomized controlled trial". Psychother Psychosom. 74 (6): 387, author reply 387–8. doi:10.1159/000087787. PMID 16244516. S2CID 143644933.
  6. ^ Peto R, Pike MC, Armitage P, Breslow NE, Cox DR, Howard SV, Mantel N, McPherson K, Peto J, Smith PG (1976). "Design and analysis of randomized clinical trials requiring prolonged observation of each patient. I. Introduction and design". Br J Cancer. 34 (6): 585–612. doi:10.1038/bjc.1976.220. PMC 2025229. PMID 795448.
  7. ^ Peto R, Pike MC, Armitage P, Breslow NE, Cox DR, Howard SV, Mantel N, McPherson K, Peto J, Smith PG (1977). "Design and analysis of randomized clinical trials requiring prolonged observation of each patient. II. Analysis and examples". Br J Cancer. 35 (1): 1–39. doi:10.1038/bjc.1977.1. PMC 2025310. PMID 831755.
  8. ^ Wollert KC, Meyer GP, Lotz J, Ringes-Lichtenberg S, Lippolt P, Breidenbach C, Fichtner S, Korte T, Hornig B, Messinger D, Arseniev L, Hertenstein B, Ganser A, Drexler H (2004). "Intracoronary autologous bone-marrow cell transfer after myocardial infarction: the BOOST randomised controlled clinical trial". Lancet. 364 (9429): 141–8. doi:10.1016/S0140-6736(04)16626-9. PMID 15246726. S2CID 24361586.
  9. ^ Dunn PM (January 1997). "James Lind (1716-94) of Edinburgh and the treatment of scurvy". Arch. Dis. Child. Fetal Neonatal Ed. 76 (1): F64–5. doi:10.1136/fn.76.1.f64. PMC 1720613. PMID 9059193.
  10. ^ Daston L (2005). "Scientific Error and the Ethos of Belief". Social Research. 72 (1): 18. doi:10.1353/sor.2005.0016.
  11. ^ Rivers WH, Webber HN (August 1907). "The action of caffeine on the capacity for muscular work". The Journal of Physiology. 36 (1): 33–47. doi:10.1113/jphysiol.1907.sp001215. PMC 1533733. PMID 16992882.
  12. ^ Charles Sanders Peirce and Joseph Jastrow (1885). "On Small Differences in Sensation". Memoirs of the National Academy of Sciences. 3: 73–83. http://psychclassics.yorku.ca/Peirce/small-diffs.htm
  13. ^ Hacking, Ian (September 1988). "Telepathy: Origins of Randomization in Experimental Design". Isis. A Special Issue on Artifact and Experiment. 79 (3): 427–451. doi:10.1086/354775. JSTOR 234674. MR 1013489. S2CID 52201011.
  14. ^ Stephen M. Stigler (November 1992). "A Historical View of Statistical Concepts in Psychology and Educational Research". American Journal of Education. 101 (1): 60–70. doi:10.1086/444032. S2CID 143685203.
  15. ^ Trudy Dehue (December 1997). "Deception, Efficiency, and Random Groups: Psychology and the Gradual Origination of the Random Group Design" (PDF). Isis. 88 (4): 653–673. doi:10.1086/383850. PMID 9519574. S2CID 23526321.
  16. ^ Neyman, Jerzy. 1923 [1990]. "On the Application of Probability Theory to AgriculturalExperiments. Essay on Principles. Section 9." Statistical Science 5 (4): 465–472. Trans. Dorota M. Dabrowska and Terence P. Speed.
  17. ^ According to Denis Conniffe:

    Ronald A. Fisher was "interested in application and in the popularization of statistical methods and his early book Statistical Methods for Research Workers, published in 1925, went through many editions and motivated and influenced the practical use of statistics in many fields of study. His Design of Experiments (1935) [promoted] statistical technique and application. In that book he emphasized examples and how to design experiments systematically from a statistical point of view. The mathematical justification of the methods described was not stressed and, indeed, proofs were often barely sketched or omitted altogether ..., a fact which led H. B. Mann to fill the gaps with a rigorous mathematical treatment in his well known treatise, Mann (1949)."

    Conniffe, Denis (1990–1991). "R. A. Fisher and the development of statistics—a view in his centenary year". Journal of the Statistical and Social Inquiry Society of Ireland. Vol. XXVI, no. 3. Dublin: Statistical and Social Inquiry Society of Ireland. p. 87. hdl:2262/2764. ISSN 0081-4776.

    Mann, H. B. (1949). Analysis and design of experiments: Analysis of variance and analysis of variance designs. New York, N. Y.: Dover Publications, Inc. pp. x+195. MR 0032177.

  18. ^ Streptomycin in Tuberculosis Trials Committee (1948). "Streptomycin treatment of pulmonary tuberculosis. A Medical Research Council investigation". Br Med J. 2 (4582): 769–82. doi:10.1136/bmj.2.4582.769. PMC 2091872. PMID 18890300.
  19. ^ Brown D (1998-11-02). "Landmark study made research resistant to bias". Washington Post.
  20. ^ Shikata S, Nakayama T, Noguchi Y, Taji Y, Yamagishi H (2006). "Comparison of effects in randomized controlled trials with observational studies in digestive surgery". Ann Surg. 244 (5): 668–76. doi:10.1097/01.sla.0000225356.04304.bc. PMC 1856609. PMID 17060757.
  21. ^ a b Stolberg HO, Norman G, Trop I (2004). "Randomized controlled trials". Am J Roentgenol. 183 (6): 1539–44. doi:10.2214/ajr.183.6.01831539. PMID 15547188. S2CID 5376391.
  22. ^ Georgina Ferry (2 November 2020). "Peter Sleight Obituary". The Guardian. Retrieved 3 November 2020.
  23. ^ Meldrum ML (2000). "A brief history of the randomized controlled trial. From oranges and lemons to the gold standard". Hematol Oncol Clin North Am. 14 (4): 745–60, vii. doi:10.1016/S0889-8588(05)70309-9. PMID 10949771.
  24. ^ Freedman B (1987). "Equipoise and the ethics of clinical research". N Engl J Med. 317 (3): 141–5. doi:10.1056/NEJM198707163170304. PMID 3600702.
  25. ^ Gifford F (1995). "Community-equipoise and the ethics of randomized clinical trials". Bioethics. 9 (2): 127–48. doi:10.1111/j.1467-8519.1995.tb00306.x. PMID 11653056.
  26. ^ Edwards SJ, Lilford RJ, Hewison J (1998). "The ethics of randomised controlled trials from the perspectives of patients, the public, and healthcare professionals". Br Med J. 317 (7167): 1209–12. doi:10.1136/bmj.317.7167.1209. PMC 1114158. PMID 9794861.
  27. ^ Zelen M (1979). "A new design for randomized clinical trials". N Engl J Med. 300 (22): 1242–5. doi:10.1056/NEJM197905313002203. PMID 431682.
  28. ^ Torgerson DJ, Roland M (1998). "What is Zelen's design?". Br Med J. 316 (7131): 606. doi:10.1136/bmj.316.7131.606. PMC 1112637. PMID 9518917.
  29. ^ Appelbaum PS, Roth LH, Lidz C (1982). "The therapeutic misconception: informed consent in psychiatric research". Int J Law Psychiatry. 5 (3–4): 319–29. doi:10.1016/0160-2527(82)90026-7. PMID 6135666.
  30. ^ a b Henderson GE, Churchill LR, Davis AM, Easter MM, Grady C, Joffe S, Kass N, King NM, Lidz CW, Miller FG, Nelson DK, Peppercorn J, Rothschild BB, Sankar P, Wilfond BS, Zimmer CR (2007). "Clinical trials and medical care: defining the therapeutic misconception". PLoS Med. 4 (11): e324. doi:10.1371/journal.pmed.0040324. PMC 2082641. PMID 18044980.
  31. ^ Jain SL (2010). (PDF). Public Culture. 21 (1): 89–117. doi:10.1215/08992363-2009-017. S2CID 143641293. Archived from the original (PDF) on 2020-02-20.
  32. ^ De Angelis C, Drazen JM, Frizelle FA, et al. (September 2004). "Clinical trial registration: a statement from the International Committee of Medical Journal Editors". The New England Journal of Medicine. 351 (12): 1250–1. doi:10.1056/NEJMe048225. PMID 15356289.
  33. ^ Law MR, Kawasumi Y, Morgan SG (2011). "Despite law, fewer than one in eight completed studies of drugs and biologics are reported on time on ClinicalTrials.gov". Health Aff (Millwood). 30 (12): 2338–45. doi:10.1377/hlthaff.2011.0172. PMID 22147862.
  34. ^ Mathieu S, Boutron I, Moher D, Altman DG, Ravaud P (2009). "Comparison of registered and published primary outcomes in randomized controlled trials". JAMA. 302 (9): 977–84. doi:10.1001/jama.2009.1242. PMID 19724045.
  35. ^ Bhaumik, S (Mar 2013). "Editorial policies of MEDLINE indexed Indian journals on clinical trial registration". Indian Pediatr. 50 (3): 339–40. doi:10.1007/s13312-013-0092-2. PMID 23680610. S2CID 40317464.
  36. ^ a b Hopewell S, Dutton S, Yu LM, Chan AW, Altman DG (2010). "The quality of reports of randomised trials in 2000 and 2006: comparative study of articles indexed in PubMed". BMJ. 340: c723. doi:10.1136/bmj.c723. PMC 2844941. PMID 20332510.
  37. ^ Kaiser, Joerg; Niesen, Willem; Probst, Pascal; Bruckner, Thomas; Doerr-Harim, Colette; Strobel, Oliver; Knebel, Phillip; Diener, Markus K.; Mihaljevic, André L.; Büchler, Markus W.; Hackert, Thilo (7 June 2019). "Abdominal drainage versus no drainage after distal pancreatectomy: study protocol for a randomized controlled trial". Trials. 20 (1): 332. doi:10.1186/s13063-019-3442-0. PMC 6555976. PMID 31174583.
  38. ^ Farag, Sara M.; Mohammed, Manal O.; EL-Sobky, Tamer A.; ElKadery, Nadia A.; ElZohiery, Abeer K. (March 2020). "Botulinum Toxin A Injection in Treatment of Upper Limb Spasticity in Children with Cerebral Palsy: A Systematic Review of Randomized Controlled Trials". JBJS Reviews. 8 (3): e0119. doi:10.2106/JBJS.RVW.19.00119. PMC 7161716. PMID 32224633.
  39. ^ Jones, Byron; Kenward, Michael G. (2003). Design and Analysis of Cross-Over Trials (Second ed.). London: Chapman and Hall.
  40. ^ Vonesh, Edward F.; Chinchilli, Vernon G. (1997). "Crossover Experiments". Linear and Nonlinear Models for the Analysis of Repeated Measurements. London: Chapman and Hall. pp. 111–202.
  41. ^ Gall, Stefanie; Adams, Larissa; Joubert, Nandi; Ludyga, Sebastian; Müller, Ivan; Nqweniso, Siphesihle; Pühse, Uwe; du Randt, Rosa; Seelig, Harald; Smith, Danielle; Steinmann, Peter; Utzinger, Jürg; Walter, Cheryl; Gerber, Markus; van Wouwe, Jacobus P. (8 November 2018). "Effect of a 20-week physical activity intervention on selective attention and academic performance in children living in disadvantaged neighborhoods: A cluster randomized control trial". PLOS ONE. 13 (11): e0206908. Bibcode:2018PLoSO..1306908G. doi:10.1371/journal.pone.0206908. PMC 6224098. PMID 30408073.
  42. ^ Gladstone, Melissa J.; Chandna, Jaya; Kandawasvika, Gwendoline; Ntozini, Robert; Majo, Florence D.; Tavengwa, Naume V.; Mbuya, Mduduzi N. N.; Mangwadu, Goldberg T.; Chigumira, Ancikaria; Chasokela, Cynthia M.; Moulton, Lawrence H.; Stoltzfus, Rebecca J.; Humphrey, Jean H.; Prendergast, Andrew J.; Tumwine, James K. (21 March 2019). "Independent and combined effects of improved water, sanitation, and hygiene (WASH) and improved complementary feeding on early neurodevelopment among children born to HIV-negative mothers in rural Zimbabwe: Substudy of a cluster-randomized trial". PLOS Medicine. 16 (3): e1002766. doi:10.1371/journal.pmed.1002766. PMC 6428259. PMID 30897095.
  43. ^ a b c d Zwarenstein M, Treweek S, Gagnier JJ, Altman DG, Tunis S, Haynes B, Oxman AD, Moher D; CONSORT group; Pragmatic Trials in Healthcare (Practihc) group (2008). "Improving the reporting of pragmatic trials: an extension of the CONSORT statement". BMJ. 337: a2390. doi:10.1136/bmj.a2390. PMC 3266844. PMID 19001484.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  44. ^ a b c d Piaggio G, Elbourne DR, Altman DG, Pocock SJ, Evans SJ; CONSORT Group (2006). "Reporting of noninferiority and equivalence randomized trials: an extension of the CONSORT statement" (PDF). JAMA. 295 (10): 1152–60. doi:10.1001/jama.295.10.1152. PMID 16522836.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  45. ^ a b c Schulz KF, Grimes DA (2002). "Generation of allocation sequences in randomised trials: chance, not choice" (PDF). Lancet. 359 (9305): 515–9. doi:10.1016/S0140-6736(02)07683-3. PMID 11853818. S2CID 291300.[dead link]
  46. ^ a b c d e f g h Schulz KF, Grimes DA (2002). "Allocation concealment in randomised trials: defending against deciphering" (PDF). Lancet. 359 (9306): 614–8. doi:10.1016/S0140-6736(02)07750-4. PMID 11867132. S2CID 12902486. Archived from the original (PDF) on September 11, 2012.
  47. ^ Howick J, Mebius A (2014). "In search of justification for the unpredictability paradox". Trials. 15: 480. doi:10.1186/1745-6215-15-480. PMC 4295227. PMID 25490908.
  48. ^ a b Lachin JM (1988). "Statistical properties of randomization in clinical trials". Controlled Clinical Trials. 9 (4): 289–311. doi:10.1016/0197-2456(88)90045-1. PMID 3060315.
  49. ^ Rosenberger, James. "STAT 503 - Design of Experiments". Pennsylvania State University. Retrieved 24 September 2012.
  50. ^ Avins, A L (1998). ""Can unequal be more fair? Ethics, subject allocation, and randomized clinical trials"". J Med Ethics. 24 (6): 401–408. doi:10.1136/jme.24.6.401. PMC 479141. PMID 9873981.
  51. ^ Buyse ME (1989). "Analysis of clinical trial outcomes: some comments on subgroup analyses". Controlled Clinical Trials. 10 (4 Suppl): 187S–194S. doi:10.1016/0197-2456(89)90057-3. PMID 2605967.
  52. ^ a b c d e f Lachin JM, Matts JP, Wei LJ (1988). "Randomization in clinical trials: conclusions and recommendations" (PDF). Controlled Clinical Trials. 9 (4): 365–74. doi:10.1016/0197-2456(88)90049-9. hdl:2027.42/27041. PMID 3203526.
  53. ^ Rosenberger WF, Lachin JM (1993). "The use of response-adaptive designs in clinical trials". Controlled Clinical Trials. 14 (6): 471–84. doi:10.1016/0197-2456(93)90028-C. PMID 8119063.
  54. ^ Forder PM, Gebski VJ, Keech AC (2005). "Allocation concealment and blinding: when ignorance is bliss". Med J Aust. 182 (2): 87–9. doi:10.5694/j.1326-5377.2005.tb06584.x. PMID 15651970. S2CID 202149.
  55. ^ Pildal J, Chan AW, Hróbjartsson A, Forfang E, Altman DG, Gøtzsche PC (2005). "Comparison of descriptions of allocation concealment in trial protocols and the published reports: cohort study". BMJ. 330 (7499): 1049. doi:10.1136/bmj.38414.422650.8F. PMC 557221. PMID 15817527.
  56. ^ a b c Wood L, Egger M, Gluud LL, Schulz KF, Jüni P, Altman DG, Gluud C, Martin RM, Wood AJ, Sterne JA (2008). "Empirical evidence of bias in treatment effect estimates in controlled trials with different interventions and outcomes: meta-epidemiological study". BMJ. 336 (7644): 601–5. doi:10.1136/bmj.39465.451748.AD. PMC 2267990. PMID 18316340.
  57. ^ Glennerster, Rachel; Kudzai Takavarasha (2013). ""Chapter 6"". Running randomized evaluations: a practical guide. Princeton: Princeton University Press. ISBN 9780691159249. JSTOR j.ctt4cgd52.
  58. ^ Devereaux PJ, Manns BJ, Ghali WA, Quan H, Lacchetti C, Montori VM, Bhandari M, Guyatt GH (2001). "Physician interpretations and textbook definitions of blinding terminology in randomized controlled trials". J Am Med Assoc. 285 (15): 2000–3. doi:10.1001/jama.285.15.2000. PMID 11308438.
  59. ^ Haahr MT, Hróbjartsson A (2006). "Who is blinded in randomized clinical trials? A study of 200 trials and a survey of authors". Clin Trials. 3 (4): 360–5. doi:10.1177/1740774506069153. PMID 17060210. S2CID 23818514.
  60. ^ Marson AG, Al-Kharusi AM, Alwaidh M, Appleton R, Baker GA, Chadwick DW, et al. (2007). "The SANAD study of effectiveness of valproate, lamotrigine, or topiramate for generalised and unclassifiable epilepsy: an unblinded randomised controlled trial". Lancet. 369 (9566): 1016–26. doi:10.1016/S0140-6736(07)60461-9. PMC 2039891. PMID 17382828.
  61. ^ Chan R, Hemeryck L, O'Regan M, Clancy L, Feely J (1995). "Oral versus intravenous antibiotics for community acquired lower respiratory tract infection in a general hospital: open, randomised controlled trial". BMJ. 310 (6991): 1360–2. doi:10.1136/bmj.310.6991.1360. PMC 2549744. PMID 7787537.
  62. ^ Fukase K, Kato M, Kikuchi S, Inoue K, Uemura N, Okamoto S, Terao S, Amagai K, Hayashi S, Asaka M; Japan Gast Study Group (2008). "Effect of eradication of Helicobacter pylori on incidence of metachronous gastric carcinoma after endoscopic resection of early gastric cancer: an open-label, randomised controlled trial" (PDF). Lancet. 372 (9636): 392–7. doi:10.1016/S0140-6736(08)61159-9. hdl:2115/34681. PMID 18675689. S2CID 13741892.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  63. ^ Noseworthy JH, Ebers GC, Vandervoort MK, Farquhar RE, Yetisir E, Roberts R (1994). "The impact of blinding on the results of a randomized, placebo-controlled multiple sclerosis clinical trial". Neurology. 44 (1): 16–20. doi:10.1212/wnl.44.1.16. PMID 8290055. S2CID 2663997.
  64. ^ Manns MP, McHutchison JG, Gordon SC, Rustgi VK, Shiffman M, Reindollar R, Goodman ZD, Koury K, Ling M, Albrecht JK (2001). "Peginterferon alfa-2b plus ribavirin compared with interferon alfa-2b plus ribavirin for initial treatment of chronic hepatitis C: a randomised trial". Lancet. 358 (9286): 958–65. doi:10.1016/S0140-6736(01)06102-5. PMID 11583749. S2CID 14583372.
  65. ^ Schwartz GG, Olsson AG, Ezekowitz MD, Ganz P, Oliver MF, Waters D, Zeiher A, Chaitman BR, Leslie S, Stern T; Myocardial Ischemia Reduction with Aggressive Cholesterol Lowering (MIRACL) Study Investigators (2001). "Effects of atorvastatin on early recurrent ischemic events in acute coronary syndromes: the MIRACL study: a randomized controlled trial". J Am Med Assoc. 285 (13): 1711–8. doi:10.1001/jama.285.13.1711. PMID 11277825.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  66. ^ a b Rossouw JE, Anderson GL, Prentice RL, LaCroix AZ, Kooperberg C, Stefanick ML, Jackson RD, Beresford SA, Howard BV, Johnson KC, Kotchen JM, Ockene J; Writing Group for the Women's Health Initiative Investigators (2002). "Risks and benefits of estrogen plus progestin in healthy postmenopausal women: principal results from the Women's Health Initiative randomized controlled trial" (PDF). J Am Med Assoc. 288 (3): 321–33. doi:10.1001/jama.288.3.321. PMID 12117397. S2CID 20149703.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  67. ^ Hollis S, Campbell F (1999). "What is meant by intention to treat analysis? Survey of published randomised controlled trials". Br Med J. 319 (7211): 670–4. doi:10.1136/bmj.319.7211.670. PMC 28218. PMID 10480822.
  68. ^ CONSORT Group. "Welcome to the CONSORT statement Website". Retrieved 2010-03-29.
  69. ^ Campbell MK, Piaggio G, Elbourne DR, Altman DG (2012). "Consort 2010 statement: extension to cluster randomised trials". BMJ. 345: e5661. doi:10.1136/bmj.e5661. PMID 22951546.
  70. ^ Boutron I, Moher D, Altman DG, Schulz K, Ravaud P (2008). "Extending the CONSORT Statement to randomized trials of nonpharmacologic treatment: explanation and elaboration". Annals of Internal Medicine. 148 (4): 295–309. doi:10.7326/0003-4819-148-4-200802190-00008. PMID 18283207.
  71. ^ Boutron I, Moher D, Altman DG, Schulz K, Ravaud P (2008). "Methods and Processes of the CONSORT Group: Example of an Extension for Trials Assessing Nonpharmacologic Treatments". Annals of Internal Medicine. 148 (4): W60–6. doi:10.7326/0003-4819-148-4-200802190-00008-w1. PMID 18283201.
  72. ^ a b Benson K, Hartz AJ (2000). "A comparison of observational studies and randomized, controlled trials". N Engl J Med. 342 (25): 1878–86. doi:10.1056/NEJM200006223422506. PMID 10861324.
  73. ^ a b Concato J, Shah N, Horwitz RI (2000). "Randomized, controlled trials, observational studies, and the hierarchy of research designs". N Engl J Med. 342 (25): 1887–92. doi:10.1056/NEJM200006223422507. PMC 1557642. PMID 10861325.
  74. ^ Ioannidis JP, Haidich AB, Pappa M, Pantazis N, Kokori SI, Tektonidou MG, Contopoulos-Ioannidis DG, Lau J (2001). "Comparison of evidence of treatment effects in randomized and nonrandomized studies". J Am Med Assoc. 286 (7): 821–30. CiteSeerX 10.1.1.590.2854. doi:10.1001/jama.286.7.821. PMID 11497536.
  75. ^ Anglemyer A, Horvath HT, Bero L (April 2014). "Healthcare outcomes assessed with observational study designs compared with those assessed in randomized trials". The Cochrane Database of Systematic Reviews. 2014 (4): MR000034. doi:10.1002/14651858.MR000034.pub2. PMC 8191367. PMID 24782322.
  76. ^ Vandenbroucke JP (2008). "Observational research, randomised trials, and two views of medical science". PLoS Med. 5 (3): e67. doi:10.1371/journal.pmed.0050067. PMC 2265762. PMID 18336067.
  77. ^ a b c d Black N (1996). "Why we need observational studies to evaluate the effectiveness of health care". BMJ. 312 (7040): 1215–8. doi:10.1136/bmj.312.7040.1215. PMC 2350940. PMID 8634569.
  78. ^ a b Glasziou P, Chalmers I, Rawlins M, McCulloch P (2007). "When are randomised trials unnecessary? Picking signal from noise". Br Med J. 334 (7589): 349–51. doi:10.1136/bmj.39070.527986.68. PMC 1800999. PMID 17303884.
  79. ^ Einhorn LH (2002). "Curing metastatic testicular cancer". Proc Natl Acad Sci U S A. 99 (7): 4592–5. doi:10.1073/pnas.072067999. PMC 123692. PMID 11904381.
  80. ^ Wittes J (2002). "Sample size calculations for randomized controlled trials". Epidemiol Rev. 24 (1): 39–53. doi:10.1093/epirev/24.1.39. PMID 12119854.
  81. ^ Freiman JA, Chalmers TC, Smith H Jr, Kuebler RR (1978). "The importance of beta, the type II error and sample size in the design and interpretation of the randomized control trial. Survey of 71 "negative" trials". N Engl J Med. 299 (13): 690–4. doi:10.1056/NEJM197809282991304. PMID 355881.
  82. ^ Charles P, Giraudeau B, Dechartres A, Baron G, Ravaud P (2009-05-12). "Reporting of sample size calculation in randomised controlled trials: review". Br Med J. 338: b1732. doi:10.1136/bmj.b1732. PMC 2680945. PMID 19435763.
  83. ^ Richard Harris (22 Dec 2018). "Researchers Show Parachutes Don't Work, But There's A Catch".
  84. ^ National Health and Medical Research Council (1998-11-16). A guide to the development, implementation and evaluation of clinical practice guidelines (PDF). Canberra: Commonwealth of Australia. p. 56. ISBN 978-1-86496-048-8. Retrieved 2010-03-28.
  85. ^ a b Harris RP, Helfand M, Woolf SH, Lohr KN, Mulrow CD, Teutsch SM, Atkins D; Methods Work Group, Third US Preventive Services Task Force (2001). "Current methods of the US Preventive Services Task Force: a review of the process" (PDF). Am J Prev Med. 20 (3 Suppl): 21–35. doi:10.1016/S0749-3797(01)00261-6. PMID 11306229.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  86. ^ Guyatt GH, Oxman AD, Kunz R, Vist GE, Falck-Ytter Y, Schünemann HJ; GRADE Working Group (2008). "What is "quality of evidence" and why is it important to clinicians?". BMJ. 336 (7651): 995–8. doi:10.1136/bmj.39490.551019.BE. PMC 2364804. PMID 18456631.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  87. ^ Oxford Centre for Evidence-based Medicine (2011-09-16). "Levels of evidence". Retrieved 2012-02-15.
  88. ^ a b c Anderson JL, Pratt CM, Waldo AL, Karagounis LA (1997). "Impact of the Food and Drug Administration approval of flecainide and encainide on coronary artery disease mortality: putting "Deadly Medicine" to the test". Am J Cardiol. 79 (1): 43–7. doi:10.1016/S0002-9149(96)00673-X. PMID 9024734.
  89. ^ a b Rubin R (2006-10-16). "In medicine, evidence can be confusing - deluged with studies, doctors try to sort out what works, what doesn't". USA Today. Retrieved 2010-03-22.
  90. ^ Cardiac Arrhythmia Suppression Trial (CAST) Investigators (1989). "Preliminary report: effect of encainide and flecainide on mortality in a randomized trial of arrhythmia suppression after myocardial infarction. The Cardiac Arrhythmia Suppression Trial (CAST) Investigators". N Engl J Med. 321 (6): 406–12. doi:10.1056/NEJM198908103210629. PMID 2473403.
  91. ^ Anderson GL, Limacher M, Assaf AR, Bassford T, Beresford SA, Black H, et al. (2004). "Effects of conjugated equine estrogen in postmenopausal women with hysterectomy: the Women's Health Initiative randomized controlled trial". JAMA. 291 (14): 1701–12. doi:10.1001/jama.291.14.1701. PMID 15082697.
  92. ^ Grodstein F, Clarkson TB, Manson JE (2003). "Understanding the divergent data on postmenopausal hormone therapy". N Engl J Med. 348 (7): 645–50. doi:10.1056/NEJMsb022365. PMID 12584376.
  93. ^ Vandenbroucke JP (2009). "The HRT controversy: observational studies and RCTs fall in line". Lancet. 373 (9671): 1233–5. doi:10.1016/S0140-6736(09)60708-X. PMID 19362661. S2CID 44991220.
  94. ^ Hsu A, Card A, Lin SX, Mota S, Carrasquillo O, Moran A (2009). "Changes in postmenopausal hormone replacement therapy use among women with high cardiovascular risk". Am J Public Health. 99 (12): 2184–7. doi:10.2105/AJPH.2009.159889. PMC 2775780. PMID 19833984.
  95. ^ Bell, S.H., & Peck, L.R. (2012). "Obstacles to and limitations of social experiments: 15 false alarms". Abt Thought Leadership Paper Series.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  96. ^ a b c Sanson-Fisher RW, Bonevski B, Green LW, D'Este C (2007). "Limitations of the randomized controlled trial in evaluating population-based health interventions". Am J Prev Med. 33 (2): 155–61. doi:10.1016/j.amepre.2007.04.007. PMID 17673104.
  97. ^ a b Johnston SC, Rootenberg JD, Katrak S, Smith WS, Elkins JS (2006). "Effect of a US National Institutes of Health programme of clinical trials on public health and costs" (PDF). Lancet. 367 (9519): 1319–27. doi:10.1016/S0140-6736(06)68578-4. PMID 16631910. S2CID 41035177.
  98. ^ a b Yitschaky O, Yitschaky M, Zadik Y (May 2011). "Case report on trial: Do you, Doctor, swear to tell the truth, the whole truth and nothing but the truth?" (PDF). J Med Case Rep. 5 (1): 179. doi:10.1186/1752-1947-5-179. PMC 3113995. PMID 21569508.
  99. ^ "How Well Do Meta-Analyses Disclose Conflicts of Interests in Underlying Research Studies | The Cochrane Collaboration". Cochrane.org. Retrieved 2011-08-19.
  100. ^ Bekelman JE, Li Y, Gross CP (2003). "Scope and impact of financial conflicts of interest in biomedical research: a systematic review". J Am Med Assoc. 289 (4): 454–65. doi:10.1001/jama.289.4.454. PMID 12533125.
  101. ^ a b Bhandari M, Busse JW, Jackowski D, Montori VM, Schünemann H, Sprague S, Mears D, Schemitsch EH, Heels-Ansdell D, Devereaux PJ (2004). "Association between industry funding and statistically significant pro-industry findings in medical and surgical randomized trials". Can Med Assoc J. 170 (4): 477–80. PMC 332713. PMID 14970094.
  102. ^ Chapman SJ, Shelton B, Mahmood H, Fitzgerald JE, Harrison EM, Bhangu A (2014). "Discontinuation and non-publication of surgical randomised controlled trials: observational study". BMJ. 349: g6870. doi:10.1136/bmj.g6870. PMC 4260649. PMID 25491195.
  103. ^ Ridker PM, Torres J (2006). "Reported outcomes in major cardiovascular clinical trials funded by for-profit and not-for-profit organizations: 2000-2005". JAMA. 295 (19): 2270–4. doi:10.1001/jama.295.19.2270. PMID 16705108.
  104. ^ Song Zhang; Jing Cao; Ahn, C. (23 June 2010). "Calculating sample size in trials using historical controls". Clinical Trials: Journal of the Society for Clinical Trials. 7 (4): 343–353. doi:10.1177/1740774510373629. PMC 3085081. PMID 20573638.
  105. ^ Rowland, D., DiGuiseppi, C., Gross, M., Afolabi, E. and Roberts, I. (2003). "Randomised controlled trial of site specific advice on school travel patterns". Archives of Disease in Childhood. 88 (1): 8–11. doi:10.1136/adc.88.1.8. PMC 1719287. PMID 12495948.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  106. ^ Graham-Rowe, E., Skippon, S., Gardner, B. and Abraham, C. (2011). "Can we reduce car use and, if so, how? A review of available evidence". Transportation Research Part A: Policy and Practice. 44 (5): 401–418. doi:10.1016/j.tra.2011.02.001.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  107. ^ Melia(2011) Do Randomised Control Trials Offer a Solution to 'low Quality' Transport Research? Bristol: University of the West of England]
  108. ^ a b Farrington DP, Welsh BC (2005). "Randomized experiments in criminology: What have we learned in the last two decades?". Journal of Experimental Criminology. 1 (1): 9–38. doi:10.1007/s11292-004-6460-0. S2CID 145758503.
  109. ^ Hollin CR (2008). "Evaluating offending behaviour programmes: does only randomization glister?". Criminology and Criminal Justice. 8 (1): 89–106. doi:10.1177/1748895807085871. S2CID 141222135.
  110. ^ Connolly, Paul; Keenan, Ciara; Urbanska, Karolina (2018-07-09). "The trials of evidence-based practice in education: a systematic review of randomised controlled trials in education research 1980–2016". Educational Research. 60 (3): 276–291. doi:10.1080/00131881.2018.1493353. ISSN 0013-1881.
  111. ^ Walker HM, Seeley JR, Small J, Severson HH, Graham BA, Feil EG, Serna L, Golly AM, Forness SR (2009). "A randomized controlled trial of the First Step to Success early intervention. Demonstration of program efficacy outcomes in a diverse, urban school district". Journal of Emotional and Behavioral Disorders. 17 (4): 197–212. doi:10.1177/1063426609341645. S2CID 144571336.
  112. ^ Bradshaw CP, Zmuda JH, Kellam SG, Ialongo NS (2009). "Longitudinal impact of two universal preventive interventions in first grade on educational outcomes in high school". Journal of Educational Psychology. 101 (4): 926–937. doi:10.1037/a0016586. PMC 3678772. PMID 23766545.
  113. ^ Krauss, Alexander (2018). "Why all randomised controlled trials produce biased results". Annals of Medicine. 50 (4): 312–322. doi:10.1080/07853890.2018.1453233. ISSN 0785-3890. PMID 29616838.

External links

  • Bland M. Directory of randomisation software and services. University of York, 2008 March 19.
  • Evans I, Thornton H, Chalmers I. London: Pinter & Martin, 2010. ISBN 978-1-905177-35-6.
  • Gelband H. The impact of randomized clinical trials on health policy and medical practice: background paper. 2016-03-03 at the Wayback Machine Washington, DC: U.S. Congress, Office of Technology Assessment, 1983. (Report OTA-BP-H-22.)
  • REFLECT (Reporting guidElines For randomized controLled trials for livEstoCk and food safeTy) Statement
  • Wathen JK, Cook JD. Power and bias in adaptively randomized clinical trials. M. D. Anderson Cancer Center, University of Texas, 2006 July 12.

April 17, 2023
randomized, controlled, trial, randomized, controlled, trial, randomized, control, trial, form, scientific, experiment, used, control, factors, under, direct, experimental, control, examples, rcts, clinical, trials, that, compare, effects, drugs, surgical, tec. A randomized controlled trial or randomized control trial 2 RCT is a form of scientific experiment used to control factors not under direct experimental control Examples of RCTs are clinical trials that compare the effects of drugs surgical techniques medical devices diagnostic procedures or other medical treatments Flowchart of four phases enrollment allocation intervention follow up and data analysis of a parallel randomized trial of two groups in a controlled trial one of the interventions serves as the control modified from the CONSORT Consolidated Standards of Reporting Trials 2010 Statement 1 Participants who enroll in RCTs differ from one another in known and unknown ways that can influence study outcomes and yet cannot be directly controlled By randomly allocating participants among compared treatments an RCT enables statistical control over these influences Provided it is designed well conducted properly and enrolls enough participants an RCT may achieve sufficient control over these confounding factors to deliver a useful comparison of the treatments studied Contents 1 Definition and examples 2 History 3 Ethics 3 1 Trial registration 4 Classifications 4 1 By study design 4 2 By outcome of interest efficacy vs effectiveness 4 3 By hypothesis superiority vs noninferiority vs equivalence 5 Randomization 5 1 Procedures 5 1 1 Simple 5 1 2 Restricted 5 1 3 Adaptive 5 2 Allocation concealment 5 3 Sample size 6 Blinding 7 Analysis of data 8 Reporting of results 8 1 Relative importance and observational studies 8 2 Interpretation of statistical results 8 3 Peer review 9 Advantages 10 Disadvantages 10 1 Time and costs 10 2 Conflict of interest dangers 10 3 Ethics 11 In social science 11 1 Transport science 11 2 Criminology 11 3 Education 12 Criticism 13 See also 14 References 15 External linksDefinition and examples EditAn RCT in clinical research typically compares a proposed new treatment against an existing standard of care these are then termed the experimental and control treatments respectively When no such generally accepted treatment is available a placebo may be used in the control group so that participants are blinded to their treatment allocations This blinding principle is ideally also extended as much as possible to other parties including researchers technicians data analysts and evaluators Effective blinding experimentally isolates the physiological effects of treatments from various psychological sources of bias The randomness in the assignment of participants to treatments reduces selection bias and allocation bias balancing both known and unknown prognostic factors in the assignment of treatments 3 Blinding reduces other forms of experimenter and subject biases A well blinded RCT is considered the gold standard for clinical trials Blinded RCTs are commonly used to test the efficacy of medical interventions and may additionally provide information about adverse effects such as drug reactions A randomized controlled trial can provide compelling evidence that the study treatment causes an effect on human health 4 The terms RCT and randomized trial are sometimes used synonymously but the latter term omits mention of controls and can therefore describe studies that compare multiple treatment groups with each other in the absence of a control group 5 Similarly the initialism is sometimes expanded as randomized clinical trial or randomized comparative trial leading to ambiguity in the scientific literature 6 7 Not all RCTs are randomized controlled trials and some of them could never be as in cases where controls would be impractical or unethical to use The term randomized controlled clinical trial is an alternative term used in clinical research 8 however RCTs are also employed in other research areas including many of the social sciences History EditThe first reported clinical trial was conducted by James Lind in 1747 to identify treatment for scurvy 9 The first blind experiment was conducted by the French Royal Commission on Animal Magnetism in 1784 to investigate the claims of mesmerism An early essay advocating the blinding of researchers came from Claude Bernard in the latter half of the 19th century vague Bernard recommended that the observer of an experiment should not have knowledge of the hypothesis being tested This suggestion contrasted starkly with the prevalent Enlightenment era attitude that scientific observation can only be objectively valid when undertaken by a well educated informed scientist 10 The first study recorded to have a blinded researcher was conducted in 1907 by W H R Rivers and H N Webber to investigate the effects of caffeine 11 Randomized experiments first appeared in psychology where they were introduced by Charles Sanders Peirce and Joseph Jastrow in the 1880s 12 and in education 13 14 15 In the early 20th century randomized experiments appeared in agriculture due to Jerzy Neyman 16 and Ronald A Fisher Fisher s experimental research and his writings popularized randomized experiments 17 The first published Randomized Controlled Trial in medicine appeared in the 1948 paper entitled Streptomycin treatment of pulmonary tuberculosis which described a Medical Research Council investigation 18 19 20 One of the authors of that paper was Austin Bradford Hill who is credited as having conceived the modern RCT 21 Trial design was further influenced by the large scale ISIS trials on heart attack treatments that were conducted in the 1980s 22 By the late 20th century RCTs were recognized as the standard method for rational therapeutics in medicine 23 As of 2004 more than 150 000 RCTs were in the Cochrane Library 21 To improve the reporting of RCTs in the medical literature an international group of scientists and editors published Consolidated Standards of Reporting Trials CONSORT Statements in 1996 2001 and 2010 and these have become widely accepted 1 3 Randomization is the process of assigning trial subjects to treatment or control groups using an element of chance to determine the assignments in order to reduce the bias Ethics EditAlthough the principle of clinical equipoise genuine uncertainty within the expert medical community about the preferred treatment common to clinical trials 24 has been applied to RCTs the ethics of RCTs have special considerations For one it has been argued that equipoise itself is insufficient to justify RCTs 25 For another collective equipoise can conflict with a lack of personal equipoise e g a personal belief that an intervention is effective 26 Finally Zelen s design which has been used for some RCTs randomizes subjects before they provide informed consent which may be ethical for RCTs of screening and selected therapies but is likely unethical for most therapeutic trials 27 28 Although subjects almost always provide informed consent for their participation in an RCT studies since 1982 have documented that RCT subjects may believe that they are certain to receive treatment that is best for them personally that is they do not understand the difference between research and treatment 29 30 Further research is necessary to determine the prevalence of and ways to address this therapeutic misconception 30 The RCT method variations may also create cultural effects that have not been well understood 31 For example patients with terminal illness may join trials in the hope of being cured even when treatments are unlikely to be successful Trial registration Edit In 2004 the International Committee of Medical Journal Editors ICMJE announced that all trials starting enrolment after July 1 2005 must be registered prior to consideration for publication in one of the 12 member journals of the committee 32 However trial registration may still occur late or not at all 33 34 Medical journals have been slow in adapting policies requiring mandatory clinical trial registration as a prerequisite for publication 35 Classifications EditBy study design Edit One way to classify RCTs is by study design From most to least common in the healthcare literature the major categories of RCT study designs are 36 Parallel group each participant is randomly assigned to a group and all the participants in the group receive or do not receive an intervention 37 38 Crossover over time each participant receives or does not receive an intervention in a random sequence 39 40 Cluster pre existing groups of participants e g villages schools are randomly selected to receive or not receive an intervention 41 42 Factorial each participant is randomly assigned to a group that receives a particular combination of interventions or non interventions e g group 1 receives vitamin X and vitamin Y group 2 receives vitamin X and placebo Y group 3 receives placebo X and vitamin Y and group 4 receives placebo X and placebo Y An analysis of the 616 RCTs indexed in PubMed during December 2006 found that 78 were parallel group trials 16 were crossover 2 were split body 2 were cluster and 2 were factorial 36 By outcome of interest efficacy vs effectiveness Edit Main article Pragmatic clinical trial RCTs can be classified as explanatory or pragmatic 43 Explanatory RCTs test efficacy in a research setting with highly selected participants and under highly controlled conditions 43 In contrast pragmatic RCTs pRCTs test effectiveness in everyday practice with relatively unselected participants and under flexible conditions in this way pragmatic RCTs can inform decisions about practice 43 By hypothesis superiority vs noninferiority vs equivalence Edit Another classification of RCTs categorizes them as superiority trials noninferiority trials and equivalence trials which differ in methodology and reporting 44 Most RCTs are superiority trials in which one intervention is hypothesized to be superior to another in a statistically significant way 44 Some RCTs are noninferiority trials to determine whether a new treatment is no worse than a reference treatment 44 Other RCTs are equivalence trials in which the hypothesis is that two interventions are indistinguishable from each other 44 Randomization EditThe advantages of proper randomization in RCTs include 45 It eliminates bias in treatment assignment specifically selection bias and confounding It facilitates blinding masking of the identity of treatments from investigators participants and assessors It permits the use of probability theory to express the likelihood that any difference in outcome between treatment groups merely indicates chance There are two processes involved in randomizing patients to different interventions First is choosing a randomization procedure to generate an unpredictable sequence of allocations this may be a simple random assignment of patients to any of the groups at equal probabilities may be restricted or may be adaptive A second and more practical issue is allocation concealment which refers to the stringent precautions taken to ensure that the group assignment of patients are not revealed prior to definitively allocating them to their respective groups Non random systematic methods of group assignment such as alternating subjects between one group and the other can cause limitless contamination possibilities and can cause a breach of allocation concealment 46 However empirical evidence that adequate randomization changes outcomes relative to inadequate randomization has been difficult to detect 47 Procedures Edit The treatment allocation is the desired proportion of patients in each treatment arm An ideal randomization procedure would achieve the following goals 48 Maximize statistical power especially in subgroup analyses Generally equal group sizes maximize statistical power however unequal groups sizes may be more powerful for some analyses e g multiple comparisons of placebo versus several doses using Dunnett s procedure 49 and are sometimes desired for non analytic reasons e g patients may be more motivated to enroll if there is a higher chance of getting the test treatment or regulatory agencies may require a minimum number of patients exposed to treatment 50 Minimize selection bias This may occur if investigators can consciously or unconsciously preferentially enroll patients between treatment arms A good randomization procedure will be unpredictable so that investigators cannot guess the next subject s group assignment based on prior treatment assignments The risk of selection bias is highest when previous treatment assignments are known as in unblinded studies or can be guessed perhaps if a drug has distinctive side effects Minimize allocation bias or confounding This may occur when covariates that affect the outcome are not equally distributed between treatment groups and the treatment effect is confounded with the effect of the covariates i e an accidental bias 45 51 If the randomization procedure causes an imbalance in covariates related to the outcome across groups estimates of effect may be biased if not adjusted for the covariates which may be unmeasured and therefore impossible to adjust for However no single randomization procedure meets those goals in every circumstance so researchers must select a procedure for a given study based on its advantages and disadvantages Simple Edit This is a commonly used and intuitive procedure similar to repeated fair coin tossing 45 Also known as complete or unrestricted randomization it is robust against both selection and accidental biases However its main drawback is the possibility of imbalanced group sizes in small RCTs It is therefore recommended only for RCTs with over 200 subjects 52 Restricted Edit To balance group sizes in smaller RCTs some form of restricted randomization is recommended 52 The major types of restricted randomization used in RCTs are Permuted block randomization or blocked randomization a block size and allocation ratio number of subjects in one group versus the other group are specified and subjects are allocated randomly within each block 46 For example a block size of 6 and an allocation ratio of 2 1 would lead to random assignment of 4 subjects to one group and 2 to the other This type of randomization can be combined with stratified randomization for example by center in a multicenter trial to ensure good balance of participant characteristics in each group 3 A special case of permuted block randomization is random allocation in which the entire sample is treated as one block 46 The major disadvantage of permuted block randomization is that even if the block sizes are large and randomly varied the procedure can lead to selection bias 48 Another disadvantage is that proper analysis of data from permuted block randomized RCTs requires stratification by blocks 52 Adaptive biased coin randomization methods of which urn randomization is the most widely known type In these relatively uncommon methods the probability of being assigned to a group decreases if the group is overrepresented and increases if the group is underrepresented 46 The methods are thought to be less affected by selection bias than permuted block randomization 52 Adaptive Edit At least two types of adaptive randomization procedures have been used in RCTs but much less frequently than simple or restricted randomization Covariate adaptive randomization of which one type is minimization The probability of being assigned to a group varies in order to minimize covariate imbalance 52 Minimization is reported to have supporters and detractors 46 because only the first subject s group assignment is truly chosen at random the method does not necessarily eliminate bias on unknown factors 3 Response adaptive randomization also known as outcome adaptive randomization The probability of being assigned to a group increases if the responses of the prior patients in the group were favorable 52 Although arguments have been made that this approach is more ethical than other types of randomization when the probability that a treatment is effective or ineffective increases during the course of an RCT ethicists have not yet studied the approach in detail 53 Allocation concealment Edit Main article Allocation concealment Allocation concealment defined as the procedure for protecting the randomization process so that the treatment to be allocated is not known before the patient is entered into the study is important in RCTs 54 In practice clinical investigators in RCTs often find it difficult to maintain impartiality Stories abound of investigators holding up sealed envelopes to lights or ransacking offices to determine group assignments in order to dictate the assignment of their next patient 46 Such practices introduce selection bias and confounders both of which should be minimized by randomization possibly distorting the results of the study 46 Adequate allocation concealment should defeat patients and investigators from discovering treatment allocation once a study is underway and after the study has concluded Treatment related side effects or adverse events may be specific enough to reveal allocation to investigators or patients thereby introducing bias or influencing any subjective parameters collected by investigators or requested from subjects Some standard methods of ensuring allocation concealment include sequentially numbered opaque sealed envelopes SNOSE sequentially numbered containers pharmacy controlled randomization and central randomization 46 It is recommended that allocation concealment methods be included in an RCT s protocol and that the allocation concealment methods should be reported in detail in a publication of an RCT s results however a 2005 study determined that most RCTs have unclear allocation concealment in their protocols in their publications or both 55 On the other hand a 2008 study of 146 meta analyses concluded that the results of RCTs with inadequate or unclear allocation concealment tended to be biased toward beneficial effects only if the RCTs outcomes were subjective as opposed to objective 56 Sample size Edit Main article Sample size determination The number of treatment units subjects or groups of subjects assigned to control and treatment groups affects an RCT s reliability If the effect of the treatment is small the number of treatment units in either group may be insufficient for rejecting the null hypothesis in the respective statistical test The failure to reject the null hypothesis would imply that the treatment shows no statistically significant effect on the treated in a given test But as the sample size increases the same RCT may be able to demonstrate a significant effect of the treatment even if this effect is small 57 Blinding EditMain article Blinded experiment An RCT may be blinded also called masked by procedures that prevent study participants caregivers or outcome assessors from knowing which intervention was received 56 Unlike allocation concealment blinding is sometimes inappropriate or impossible to perform in an RCT for example if an RCT involves a treatment in which active participation of the patient is necessary e g physical therapy participants cannot be blinded to the intervention Traditionally blinded RCTs have been classified as single blind double blind or triple blind however in 2001 and 2006 two studies showed that these terms have different meanings for different people 58 59 The 2010 CONSORT Statement specifies that authors and editors should not use the terms single blind double blind and triple blind instead reports of blinded RCT should discuss If done who was blinded after assignment to interventions for example participants care providers those assessing outcomes and how 3 RCTs without blinding are referred to as unblinded 60 open 61 or if the intervention is a medication open label 62 In 2008 a study concluded that the results of unblinded RCTs tended to be biased toward beneficial effects only if the RCTs outcomes were subjective as opposed to objective 56 for example in an RCT of treatments for multiple sclerosis unblinded neurologists but not the blinded neurologists felt that the treatments were beneficial 63 In pragmatic RCTs although the participants and providers are often unblinded it is still desirable and often possible to blind the assessor or obtain an objective source of data for evaluation of outcomes 43 Analysis of data EditThe types of statistical methods used in RCTs depend on the characteristics of the data and include For dichotomous binary outcome data logistic regression e g to predict sustained virological response after receipt of peginterferon alfa 2a for hepatitis C 64 and other methods can be used For continuous outcome data analysis of covariance e g for changes in blood lipid levels after receipt of atorvastatin after acute coronary syndrome 65 tests the effects of predictor variables For time to event outcome data that may be censored survival analysis e g Kaplan Meier estimators and Cox proportional hazards models for time to coronary heart disease after receipt of hormone replacement therapy in menopause 66 is appropriate Regardless of the statistical methods used important considerations in the analysis of RCT data include Whether an RCT should be stopped early due to interim results For example RCTs may be stopped early if an intervention produces larger than expected benefit or harm or if investigators find evidence of no important difference between experimental and control interventions 3 The extent to which the groups can be analyzed exactly as they existed upon randomization i e whether a so called intention to treat analysis is used A pure intention to treat analysis is possible only when complete outcome data are available for all randomized subjects 67 when some outcome data are missing options include analyzing only cases with known outcomes and using imputed data 3 Nevertheless the more that analyses can include all participants in the groups to which they were randomized the less bias that an RCT will be subject to 3 Whether subgroup analysis should be performed These are often discouraged because multiple comparisons may produce false positive findings that cannot be confirmed by other studies 3 Reporting of results EditThe CONSORT 2010 Statement is an evidence based minimum set of recommendations for reporting RCTs 68 The CONSORT 2010 checklist contains 25 items many with sub items focusing on individually randomised two group parallel trials which are the most common type of RCT 1 For other RCT study designs CONSORT extensions have been published some examples are Consort 2010 Statement Extension to Cluster Randomised Trials 69 Consort 2010 Statement Non Pharmacologic Treatment Interventions 70 71 Relative importance and observational studies Edit Two studies published in The New England Journal of Medicine in 2000 found that observational studies and RCTs overall produced similar results 72 73 The authors of the 2000 findings questioned the belief that observational studies should not be used for defining evidence based medical care and that RCTs results are evidence of the highest grade 72 73 However a 2001 study published in Journal of the American Medical Association concluded that discrepancies beyond chance do occur and differences in estimated magnitude of treatment effect are very common between observational studies and RCTs 74 According to a 2014 Cochrane review there is little evidence for significant effect differences between observational studies and randomized controlled trials regardless of design heterogeneity or inclusion of studies of interventions that assessed drug effects 75 Two other lines of reasoning question RCTs contribution to scientific knowledge beyond other types of studies If study designs are ranked by their potential for new discoveries then anecdotal evidence would be at the top of the list followed by observational studies followed by RCTs 76 RCTs may be unnecessary for treatments that have dramatic and rapid effects relative to the expected stable or progressively worse natural course of the condition treated 77 78 One example is combination chemotherapy including cisplatin for metastatic testicular cancer which increased the cure rate from 5 to 60 in a 1977 non randomized study 78 79 Interpretation of statistical results Edit Like all statistical methods RCTs are subject to both type I false positive and type II false negative statistical errors Regarding Type I errors a typical RCT will use 0 05 i e 1 in 20 as the probability that the RCT will falsely find two equally effective treatments significantly different 80 Regarding Type II errors despite the publication of a 1978 paper noting that the sample sizes of many negative RCTs were too small to make definitive conclusions about the negative results 81 by 2005 2006 a sizeable proportion of RCTs still had inaccurate or incompletely reported sample size calculations 82 Peer review Edit Peer review of results is an important part of the scientific method Reviewers examine the study results for potential problems with design that could lead to unreliable results for example by creating a systematic bias evaluate the study in the context of related studies and other evidence and evaluate whether the study can be reasonably considered to have proven its conclusions To underscore the need for peer review and the danger of overgeneralizing conclusions two Boston area medical researchers performed a randomized controlled trial in which they randomly assigned either a parachute or an empty backpack to 23 volunteers who jumped from either a biplane or a helicopter The study was able to accurately report that parachutes fail to reduce injury compared to empty backpacks The key context that limited the general applicability of this conclusion was that the aircraft were parked on the ground and participants had only jumped about two feet 83 Advantages EditRCTs are considered to be the most reliable form of scientific evidence in the hierarchy of evidence that influences healthcare policy and practice because RCTs reduce spurious causality and bias Results of RCTs may be combined in systematic reviews which are increasingly being used in the conduct of evidence based practice Some examples of scientific organizations considering RCTs or systematic reviews of RCTs to be the highest quality evidence available are As of 1998 the National Health and Medical Research Council of Australia designated Level I evidence as that obtained from a systematic review of all relevant randomised controlled trials and Level II evidence as that obtained from at least one properly designed randomised controlled trial 84 Since at least 2001 in making clinical practice guideline recommendations the United States Preventive Services Task Force has considered both a study s design and its internal validity as indicators of its quality 85 It has recognized evidence obtained from at least one properly randomized controlled trial with good internal validity i e a rating of I good as the highest quality evidence available to it 85 The GRADE Working Group concluded in 2008 that randomised trials without important limitations constitute high quality evidence 86 For issues involving Therapy Prevention Aetiology Harm the Oxford Centre for Evidence based Medicine as of 2011 defined Level 1a evidence as a systematic review of RCTs that are consistent with each other and Level 1b evidence as an individual RCT with narrow Confidence Interval 87 Notable RCTs with unexpected results that contributed to changes in clinical practice include After Food and Drug Administration approval the antiarrhythmic agents flecainide and encainide came to market in 1986 and 1987 respectively 88 The non randomized studies concerning the drugs were characterized as glowing 89 and their sales increased to a combined total of approximately 165 000 prescriptions per month in early 1989 88 In that year however a preliminary report of an RCT concluded that the two drugs increased mortality 90 Sales of the drugs then decreased 88 Prior to 2002 based on observational studies it was routine for physicians to prescribe hormone replacement therapy for post menopausal women to prevent myocardial infarction 89 In 2002 and 2004 however published RCTs from the Women s Health Initiative claimed that women taking hormone replacement therapy with estrogen plus progestin had a higher rate of myocardial infarctions than women on a placebo and that estrogen only hormone replacement therapy caused no reduction in the incidence of coronary heart disease 66 91 Possible explanations for the discrepancy between the observational studies and the RCTs involved differences in methodology in the hormone regimens used and in the populations studied 92 93 The use of hormone replacement therapy decreased after publication of the RCTs 94 Disadvantages EditMany papers discuss the disadvantages of RCTs 77 95 96 Among the most frequently cited drawbacks are Time and costs Edit RCTs can be expensive 96 one study found 28 Phase III RCTs funded by the National Institute of Neurological Disorders and Stroke prior to 2000 with a total cost of US 335 million 97 for a mean cost of US 12 million per RCT Nevertheless the return on investment of RCTs may be high in that the same study projected that the 28 RCTs produced a net benefit to society at 10 years of 46 times the cost of the trials program based on evaluating a quality adjusted life year as equal to the prevailing mean per capita gross domestic product 97 The conduct of an RCT takes several years until being published thus data is restricted from the medical community for long years and may be of less relevance at time of publication 98 It is costly to maintain RCTs for the years or decades that would be ideal for evaluating some interventions 77 96 Interventions to prevent events that occur only infrequently e g sudden infant death syndrome and uncommon adverse outcomes e g a rare side effect of a drug would require RCTs with extremely large sample sizes and may therefore best be assessed by observational studies 77 Due to the costs of running RCTs these usually only inspect one variable or very few variables rarely reflecting the full picture of a complicated medical situation whereas the case report for example can detail many aspects of the patient s medical situation e g patient history physical examination diagnosis psychosocial aspects follow up 98 Conflict of interest dangers Edit A 2011 study done to disclose possible conflicts of interests in underlying research studies used for medical meta analyses reviewed 29 meta analyses and found that conflicts of interests in the studies underlying the meta analyses were rarely disclosed The 29 meta analyses included 11 from general medicine journals 15 from specialty medicine journals and 3 from the Cochrane Database of Systematic Reviews The 29 meta analyses reviewed an aggregate of 509 randomized controlled trials RCTs Of these 318 RCTs reported funding sources with 219 69 industry funded 132 of the 509 RCTs reported author conflict of interest disclosures with 91 studies 69 disclosing industry financial ties with one or more authors The information was however seldom reflected in the meta analyses Only two 7 reported RCT funding sources and none reported RCT author industry ties The authors concluded without acknowledgment of COI due to industry funding or author industry financial ties from RCTs included in meta analyses readers understanding and appraisal of the evidence from the meta analysis may be compromised 99 Some RCTs are fully or partly funded by the health care industry e g the pharmaceutical industry as opposed to government nonprofit or other sources A systematic review published in 2003 found four 1986 2002 articles comparing industry sponsored and nonindustry sponsored RCTs and in all the articles there was a correlation of industry sponsorship and positive study outcome 100 A 2004 study of 1999 2001 RCTs published in leading medical and surgical journals determined that industry funded RCTs are more likely to be associated with statistically significant pro industry findings 101 These results have been mirrored in trials in surgery where although industry funding did not affect the rate of trial discontinuation it was however associated with a lower odds of publication for completed trials 102 One possible reason for the pro industry results in industry funded published RCTs is publication bias 101 Other authors have cited the differing goals of academic and industry sponsored research as contributing to the difference Commercial sponsors may be more focused on performing trials of drugs that have already shown promise in early stage trials and on replicating previous positive results to fulfill regulatory requirements for drug approval 103 Ethics Edit If a disruptive innovation in medical technology is developed it may be difficult to test this ethically in an RCT if it becomes obvious that the control subjects have poorer outcomes either due to other foregoing testing or within the initial phase of the RCT itself Ethically it may be necessary to abort the RCT prematurely and getting ethics approval and patient agreement to withhold the innovation from the control group in future RCT s may not be feasible Historical control trials HCT exploit the data of previous RCTs to reduce the sample size however these approaches are controversial in the scientific community and must be handled with care 104 In social science EditDue to the recent emergence of RCTs in social science the use of RCTs in social sciences is a contested issue Some writers from a medical or health background have argued that existing research in a range of social science disciplines lacks rigour and should be improved by greater use of randomized control trials Transport science Edit Researchers in transport science argue that public spending on programmes such as school travel plans could not be justified unless their efficacy is demonstrated by randomized controlled trials 105 Graham Rowe and colleagues 106 reviewed 77 evaluations of transport interventions found in the literature categorising them into 5 quality levels They concluded that most of the studies were of low quality and advocated the use of randomized controlled trials wherever possible in future transport research Dr Steve Melia 107 took issue with these conclusions arguing that claims about the advantages of RCTs in establishing causality and avoiding bias have been exaggerated He proposed the following eight criteria for the use of RCTs in contexts where interventions must change human behaviour to be effective The intervention Has not been applied to all members of a unique group of people e g the population of a whole country all employees of a unique organisation etc Is applied in a context or setting similar to that which applies to the control group Can be isolated from other activities and the purpose of the study is to assess this isolated effect Has a short timescale between its implementation and maturity of its effectsAnd the causal mechanisms Are either known to the researchers or else all possible alternatives can be tested Do not involve significant feedback mechanisms between the intervention group and external environments Have a stable and predictable relationship to exogenous factors Would act in the same way if the control group and intervention group were reversedCriminology Edit A 2005 review found 83 randomized experiments in criminology published in 1982 2004 compared with only 35 published in 1957 1981 108 The authors classified the studies they found into five categories policing prevention corrections court and community 108 Focusing only on offending behavior programs Hollin 2008 argued that RCTs may be difficult to implement e g if an RCT required passing sentences that would randomly assign offenders to programmes and therefore that experiments with quasi experimental design are still necessary 109 Education Edit RCTs have been used in evaluating a number of educational interventions Between 1980 and 2016 over 1 000 reports of RCTs have been published 110 For example a 2009 study randomized 260 elementary school teachers classrooms to receive or not receive a program of behavioral screening classroom intervention and parent training and then measured the behavioral and academic performance of their students 111 Another 2009 study randomized classrooms for 678 first grade children to receive a classroom centered intervention a parent centered intervention or no intervention and then followed their academic outcomes through age 19 112 Criticism EditA 2018 review of the 10 most cited randomised controlled trials noted poor distribution of background traits difficulties with blinding and discussed other assumptions and biases inherent in randomised controlled trials These include the unique time period assessment bias the background traits remain constant assumption the average treatment effects limitation the simple treatment at the individual level limitation the all preconditions are fully met assumption the quantitative variable limitation and the placebo only or conventional treatment only limitation 113 See also EditDrug development Hypothesis testing Impact evaluation Jadad scale Pipeline planning Royal Commission on Animal Magnetism Statistical inferenceReferences Edit a b c Schulz KF Altman DG Moher D for the CONSORT Group 2010 CONSORT 2010 Statement updated guidelines for reporting parallel group randomised trials Br Med J 340 c332 doi 10 1136 bmj c332 PMC 2844940 PMID 20332509 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Chalmers TC Smith H Jr Blackburn B Silverman B Schroeder B Reitman D Ambroz A 1981 A method for assessing the quality of a randomized control trial Controlled Clinical Trials 2 1 31 49 doi 10 1016 0197 2456 81 90056 8 PMID 7261638 a b c d e f g h i Moher D Hopewell S Schulz KF Montori V Gotzsche PC Devereaux PJ Elbourne D Egger M Altman DG 2010 CONSORT 2010 explanation and elaboration updated guidelines for reporting parallel group randomised trials Br Med J 340 c869 doi 10 1136 bmj c869 PMC 2844943 PMID 20332511 Hannan EL June 2008 Randomized clinical trials and observational studies guidelines for assessing respective strengths and limitations JACC Cardiovascular Interventions 1 3 211 7 doi 10 1016 j jcin 2008 01 008 PMID 19463302 Ranjith G 2005 Interferon a induced depression when a randomized trial is not a randomized controlled trial Psychother Psychosom 74 6 387 author reply 387 8 doi 10 1159 000087787 PMID 16244516 S2CID 143644933 Peto R Pike MC Armitage P Breslow NE Cox DR Howard SV Mantel N McPherson K Peto J Smith PG 1976 Design and analysis of randomized clinical trials requiring prolonged observation of each patient I Introduction and design Br J Cancer 34 6 585 612 doi 10 1038 bjc 1976 220 PMC 2025229 PMID 795448 Peto R Pike MC Armitage P Breslow NE Cox DR Howard SV Mantel N McPherson K Peto J Smith PG 1977 Design and analysis of randomized clinical trials requiring prolonged observation of each patient II Analysis and examples Br J Cancer 35 1 1 39 doi 10 1038 bjc 1977 1 PMC 2025310 PMID 831755 Wollert KC Meyer GP Lotz J Ringes Lichtenberg S Lippolt P Breidenbach C Fichtner S Korte T Hornig B Messinger D Arseniev L Hertenstein B Ganser A Drexler H 2004 Intracoronary autologous bone marrow cell transfer after myocardial infarction the BOOST randomised controlled clinical trial Lancet 364 9429 141 8 doi 10 1016 S0140 6736 04 16626 9 PMID 15246726 S2CID 24361586 Dunn PM January 1997 James Lind 1716 94 of Edinburgh and the treatment of scurvy Arch Dis Child Fetal Neonatal Ed 76 1 F64 5 doi 10 1136 fn 76 1 f64 PMC 1720613 PMID 9059193 Daston L 2005 Scientific Error and the Ethos of Belief Social Research 72 1 18 doi 10 1353 sor 2005 0016 Rivers WH Webber HN August 1907 The action of caffeine on the capacity for muscular work The Journal of Physiology 36 1 33 47 doi 10 1113 jphysiol 1907 sp001215 PMC 1533733 PMID 16992882 Charles Sanders Peirce and Joseph Jastrow 1885 On Small Differences in Sensation Memoirs of the National Academy of Sciences 3 73 83 http psychclassics yorku ca Peirce small diffs htm Hacking Ian September 1988 Telepathy Origins of Randomization in Experimental Design Isis A Special Issue on Artifact and Experiment 79 3 427 451 doi 10 1086 354775 JSTOR 234674 MR 1013489 S2CID 52201011 Stephen M Stigler November 1992 A Historical View of Statistical Concepts in Psychology and Educational Research American Journal of Education 101 1 60 70 doi 10 1086 444032 S2CID 143685203 Trudy Dehue December 1997 Deception Efficiency and Random Groups Psychology and the Gradual Origination of the Random Group Design PDF Isis 88 4 653 673 doi 10 1086 383850 PMID 9519574 S2CID 23526321 Neyman Jerzy 1923 1990 On the Application of Probability Theory to AgriculturalExperiments Essay on Principles Section 9 Statistical Science 5 4 465 472 Trans Dorota M Dabrowska and Terence P Speed According to Denis Conniffe Ronald A Fisher was interested in application and in the popularization of statistical methods and his early book Statistical Methods for Research Workers published in 1925 went through many editions and motivated and influenced the practical use of statistics in many fields of study His Design of Experiments 1935 promoted statistical technique and application In that book he emphasized examples and how to design experiments systematically from a statistical point of view The mathematical justification of the methods described was not stressed and indeed proofs were often barely sketched or omitted altogether a fact which led H B Mann to fill the gaps with a rigorous mathematical treatment in his well known treatise Mann 1949 Conniffe Denis 1990 1991 R A Fisher and the development of statistics a view in his centenary year Journal of the Statistical and Social Inquiry Society of Ireland Vol XXVI no 3 Dublin Statistical and Social Inquiry Society of Ireland p 87 hdl 2262 2764 ISSN 0081 4776 Mann H B 1949 Analysis and design of experiments Analysis of variance and analysis of variance designs New York N Y Dover Publications Inc pp x 195 MR 0032177 Streptomycin in Tuberculosis Trials Committee 1948 Streptomycin treatment of pulmonary tuberculosis A Medical Research Council investigation Br Med J 2 4582 769 82 doi 10 1136 bmj 2 4582 769 PMC 2091872 PMID 18890300 Brown D 1998 11 02 Landmark study made research resistant to bias Washington Post Shikata S Nakayama T Noguchi Y Taji Y Yamagishi H 2006 Comparison of effects in randomized controlled trials with observational studies in digestive surgery Ann Surg 244 5 668 76 doi 10 1097 01 sla 0000225356 04304 bc PMC 1856609 PMID 17060757 a b Stolberg HO Norman G Trop I 2004 Randomized controlled trials Am J Roentgenol 183 6 1539 44 doi 10 2214 ajr 183 6 01831539 PMID 15547188 S2CID 5376391 Georgina Ferry 2 November 2020 Peter Sleight Obituary The Guardian Retrieved 3 November 2020 Meldrum ML 2000 A brief history of the randomized controlled trial From oranges and lemons to the gold standard Hematol Oncol Clin North Am 14 4 745 60 vii doi 10 1016 S0889 8588 05 70309 9 PMID 10949771 Freedman B 1987 Equipoise and the ethics of clinical research N Engl J Med 317 3 141 5 doi 10 1056 NEJM198707163170304 PMID 3600702 Gifford F 1995 Community equipoise and the ethics of randomized clinical trials Bioethics 9 2 127 48 doi 10 1111 j 1467 8519 1995 tb00306 x PMID 11653056 Edwards SJ Lilford RJ Hewison J 1998 The ethics of randomised controlled trials from the perspectives of patients the public and healthcare professionals Br Med J 317 7167 1209 12 doi 10 1136 bmj 317 7167 1209 PMC 1114158 PMID 9794861 Zelen M 1979 A new design for randomized clinical trials N Engl J Med 300 22 1242 5 doi 10 1056 NEJM197905313002203 PMID 431682 Torgerson DJ Roland M 1998 What is Zelen s design Br Med J 316 7131 606 doi 10 1136 bmj 316 7131 606 PMC 1112637 PMID 9518917 Appelbaum PS Roth LH Lidz C 1982 The therapeutic misconception informed consent in psychiatric research Int J Law Psychiatry 5 3 4 319 29 doi 10 1016 0160 2527 82 90026 7 PMID 6135666 a b Henderson GE Churchill LR Davis AM Easter MM Grady C Joffe S Kass N King NM Lidz CW Miller FG Nelson DK Peppercorn J Rothschild BB Sankar P Wilfond BS Zimmer CR 2007 Clinical trials and medical care defining the therapeutic misconception PLoS Med 4 11 e324 doi 10 1371 journal pmed 0040324 PMC 2082641 PMID 18044980 Jain SL 2010 The mortality effect counting the dead in the cancer trial PDF Public Culture 21 1 89 117 doi 10 1215 08992363 2009 017 S2CID 143641293 Archived from the original PDF on 2020 02 20 De Angelis C Drazen JM Frizelle FA et al September 2004 Clinical trial registration a statement from the International Committee of Medical Journal Editors The New England Journal of Medicine 351 12 1250 1 doi 10 1056 NEJMe048225 PMID 15356289 Law MR Kawasumi Y Morgan SG 2011 Despite law fewer than one in eight completed studies of drugs and biologics are reported on time on ClinicalTrials gov Health Aff Millwood 30 12 2338 45 doi 10 1377 hlthaff 2011 0172 PMID 22147862 Mathieu S Boutron I Moher D Altman DG Ravaud P 2009 Comparison of registered and published primary outcomes in randomized controlled trials JAMA 302 9 977 84 doi 10 1001 jama 2009 1242 PMID 19724045 Bhaumik S Mar 2013 Editorial policies of MEDLINE indexed Indian journals on clinical trial registration Indian Pediatr 50 3 339 40 doi 10 1007 s13312 013 0092 2 PMID 23680610 S2CID 40317464 a b Hopewell S Dutton S Yu LM Chan AW Altman DG 2010 The quality of reports of randomised trials in 2000 and 2006 comparative study of articles indexed in PubMed BMJ 340 c723 doi 10 1136 bmj c723 PMC 2844941 PMID 20332510 Kaiser Joerg Niesen Willem Probst Pascal Bruckner Thomas Doerr Harim Colette Strobel Oliver Knebel Phillip Diener Markus K Mihaljevic Andre L Buchler Markus W Hackert Thilo 7 June 2019 Abdominal drainage versus no drainage after distal pancreatectomy study protocol for a randomized controlled trial Trials 20 1 332 doi 10 1186 s13063 019 3442 0 PMC 6555976 PMID 31174583 Farag Sara M Mohammed Manal O EL Sobky Tamer A ElKadery Nadia A ElZohiery Abeer K March 2020 Botulinum Toxin A Injection in Treatment of Upper Limb Spasticity in Children with Cerebral Palsy A Systematic Review of Randomized Controlled Trials JBJS Reviews 8 3 e0119 doi 10 2106 JBJS RVW 19 00119 PMC 7161716 PMID 32224633 Jones Byron Kenward Michael G 2003 Design and Analysis of Cross Over Trials Second ed London Chapman and Hall Vonesh Edward F Chinchilli Vernon G 1997 Crossover Experiments Linear and Nonlinear Models for the Analysis of Repeated Measurements London Chapman and Hall pp 111 202 Gall Stefanie Adams Larissa Joubert Nandi Ludyga Sebastian Muller Ivan Nqweniso Siphesihle Puhse Uwe du Randt Rosa Seelig Harald Smith Danielle Steinmann Peter Utzinger Jurg Walter Cheryl Gerber Markus van Wouwe Jacobus P 8 November 2018 Effect of a 20 week physical activity intervention on selective attention and academic performance in children living in disadvantaged neighborhoods A cluster randomized control trial PLOS ONE 13 11 e0206908 Bibcode 2018PLoSO 1306908G doi 10 1371 journal pone 0206908 PMC 6224098 PMID 30408073 Gladstone Melissa J Chandna Jaya Kandawasvika Gwendoline Ntozini Robert Majo Florence D Tavengwa Naume V Mbuya Mduduzi N N Mangwadu Goldberg T Chigumira Ancikaria Chasokela Cynthia M Moulton Lawrence H Stoltzfus Rebecca J Humphrey Jean H Prendergast Andrew J Tumwine James K 21 March 2019 Independent and combined effects of improved water sanitation and hygiene WASH and improved complementary feeding on early neurodevelopment among children born to HIV negative mothers in rural Zimbabwe Substudy of a cluster randomized trial PLOS Medicine 16 3 e1002766 doi 10 1371 journal pmed 1002766 PMC 6428259 PMID 30897095 a b c d Zwarenstein M Treweek S Gagnier JJ Altman DG Tunis S Haynes B Oxman AD Moher D CONSORT group Pragmatic Trials in Healthcare Practihc group 2008 Improving the reporting of pragmatic trials an extension of the CONSORT statement BMJ 337 a2390 doi 10 1136 bmj a2390 PMC 3266844 PMID 19001484 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link a b c d Piaggio G Elbourne DR Altman DG Pocock SJ Evans SJ CONSORT Group 2006 Reporting of noninferiority and equivalence randomized trials an extension of the CONSORT statement PDF JAMA 295 10 1152 60 doi 10 1001 jama 295 10 1152 PMID 16522836 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link a b c Schulz KF Grimes DA 2002 Generation of allocation sequences in randomised trials chance not choice PDF Lancet 359 9305 515 9 doi 10 1016 S0140 6736 02 07683 3 PMID 11853818 S2CID 291300 dead link a b c d e f g h Schulz KF Grimes DA 2002 Allocation concealment in randomised trials defending against deciphering PDF Lancet 359 9306 614 8 doi 10 1016 S0140 6736 02 07750 4 PMID 11867132 S2CID 12902486 Archived from the original PDF on September 11 2012 Howick J Mebius A 2014 In search of justification for the unpredictability paradox Trials 15 480 doi 10 1186 1745 6215 15 480 PMC 4295227 PMID 25490908 a b Lachin JM 1988 Statistical properties of randomization in clinical trials Controlled Clinical Trials 9 4 289 311 doi 10 1016 0197 2456 88 90045 1 PMID 3060315 Rosenberger James STAT 503 Design of Experiments Pennsylvania State University Retrieved 24 September 2012 Avins A L 1998 Can unequal be more fair Ethics subject allocation and randomized clinical trials J Med Ethics 24 6 401 408 doi 10 1136 jme 24 6 401 PMC 479141 PMID 9873981 Buyse ME 1989 Analysis of clinical trial outcomes some comments on subgroup analyses Controlled Clinical Trials 10 4 Suppl 187S 194S doi 10 1016 0197 2456 89 90057 3 PMID 2605967 a b c d e f Lachin JM Matts JP Wei LJ 1988 Randomization in clinical trials conclusions and recommendations PDF Controlled Clinical Trials 9 4 365 74 doi 10 1016 0197 2456 88 90049 9 hdl 2027 42 27041 PMID 3203526 Rosenberger WF Lachin JM 1993 The use of response adaptive designs in clinical trials Controlled Clinical Trials 14 6 471 84 doi 10 1016 0197 2456 93 90028 C PMID 8119063 Forder PM Gebski VJ Keech AC 2005 Allocation concealment and blinding when ignorance is bliss Med J Aust 182 2 87 9 doi 10 5694 j 1326 5377 2005 tb06584 x PMID 15651970 S2CID 202149 Pildal J Chan AW Hrobjartsson A Forfang E Altman DG Gotzsche PC 2005 Comparison of descriptions of allocation concealment in trial protocols and the published reports cohort study BMJ 330 7499 1049 doi 10 1136 bmj 38414 422650 8F PMC 557221 PMID 15817527 a b c Wood L Egger M Gluud LL Schulz KF Juni P Altman DG Gluud C Martin RM Wood AJ Sterne JA 2008 Empirical evidence of bias in treatment effect estimates in controlled trials with different interventions and outcomes meta epidemiological study BMJ 336 7644 601 5 doi 10 1136 bmj 39465 451748 AD PMC 2267990 PMID 18316340 Glennerster Rachel Kudzai Takavarasha 2013 Chapter 6 Running randomized evaluations a practical guide Princeton Princeton University Press ISBN 9780691159249 JSTOR j ctt4cgd52 Devereaux PJ Manns BJ Ghali WA Quan H Lacchetti C Montori VM Bhandari M Guyatt GH 2001 Physician interpretations and textbook definitions of blinding terminology in randomized controlled trials J Am Med Assoc 285 15 2000 3 doi 10 1001 jama 285 15 2000 PMID 11308438 Haahr MT Hrobjartsson A 2006 Who is blinded in randomized clinical trials A study of 200 trials and a survey of authors Clin Trials 3 4 360 5 doi 10 1177 1740774506069153 PMID 17060210 S2CID 23818514 Marson AG Al Kharusi AM Alwaidh M Appleton R Baker GA Chadwick DW et al 2007 The SANAD study of effectiveness of valproate lamotrigine or topiramate for generalised and unclassifiable epilepsy an unblinded randomised controlled trial Lancet 369 9566 1016 26 doi 10 1016 S0140 6736 07 60461 9 PMC 2039891 PMID 17382828 Chan R Hemeryck L O Regan M Clancy L Feely J 1995 Oral versus intravenous antibiotics for community acquired lower respiratory tract infection in a general hospital open randomised controlled trial BMJ 310 6991 1360 2 doi 10 1136 bmj 310 6991 1360 PMC 2549744 PMID 7787537 Fukase K Kato M Kikuchi S Inoue K Uemura N Okamoto S Terao S Amagai K Hayashi S Asaka M Japan Gast Study Group 2008 Effect of eradication of Helicobacter pylori on incidence of metachronous gastric carcinoma after endoscopic resection of early gastric cancer an open label randomised controlled trial PDF Lancet 372 9636 392 7 doi 10 1016 S0140 6736 08 61159 9 hdl 2115 34681 PMID 18675689 S2CID 13741892 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Noseworthy JH Ebers GC Vandervoort MK Farquhar RE Yetisir E Roberts R 1994 The impact of blinding on the results of a randomized placebo controlled multiple sclerosis clinical trial Neurology 44 1 16 20 doi 10 1212 wnl 44 1 16 PMID 8290055 S2CID 2663997 Manns MP McHutchison JG Gordon SC Rustgi VK Shiffman M Reindollar R Goodman ZD Koury K Ling M Albrecht JK 2001 Peginterferon alfa 2b plus ribavirin compared with interferon alfa 2b plus ribavirin for initial treatment of chronic hepatitis C a randomised trial Lancet 358 9286 958 65 doi 10 1016 S0140 6736 01 06102 5 PMID 11583749 S2CID 14583372 Schwartz GG Olsson AG Ezekowitz MD Ganz P Oliver MF Waters D Zeiher A Chaitman BR Leslie S Stern T Myocardial Ischemia Reduction with Aggressive Cholesterol Lowering MIRACL Study Investigators 2001 Effects of atorvastatin on early recurrent ischemic events in acute coronary syndromes the MIRACL study a randomized controlled trial J Am Med Assoc 285 13 1711 8 doi 10 1001 jama 285 13 1711 PMID 11277825 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link a b Rossouw JE Anderson GL Prentice RL LaCroix AZ Kooperberg C Stefanick ML Jackson RD Beresford SA Howard BV Johnson KC Kotchen JM Ockene J Writing Group for the Women s Health Initiative Investigators 2002 Risks and benefits of estrogen plus progestin in healthy postmenopausal women principal results from the Women s Health Initiative randomized controlled trial PDF J Am Med Assoc 288 3 321 33 doi 10 1001 jama 288 3 321 PMID 12117397 S2CID 20149703 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Hollis S Campbell F 1999 What is meant by intention to treat analysis Survey of published randomised controlled trials Br Med J 319 7211 670 4 doi 10 1136 bmj 319 7211 670 PMC 28218 PMID 10480822 CONSORT Group Welcome to the CONSORT statement Website Retrieved 2010 03 29 Campbell MK Piaggio G Elbourne DR Altman DG 2012 Consort 2010 statement extension to cluster randomised trials BMJ 345 e5661 doi 10 1136 bmj e5661 PMID 22951546 Boutron I Moher D Altman DG Schulz K Ravaud P 2008 Extending the CONSORT Statement to randomized trials of nonpharmacologic treatment explanation and elaboration Annals of Internal Medicine 148 4 295 309 doi 10 7326 0003 4819 148 4 200802190 00008 PMID 18283207 Boutron I Moher D Altman DG Schulz K Ravaud P 2008 Methods and Processes of the CONSORT Group Example of an Extension for Trials Assessing Nonpharmacologic Treatments Annals of Internal Medicine 148 4 W60 6 doi 10 7326 0003 4819 148 4 200802190 00008 w1 PMID 18283201 a b Benson K Hartz AJ 2000 A comparison of observational studies and randomized controlled trials N Engl J Med 342 25 1878 86 doi 10 1056 NEJM200006223422506 PMID 10861324 a b Concato J Shah N Horwitz RI 2000 Randomized controlled trials observational studies and the hierarchy of research designs N Engl J Med 342 25 1887 92 doi 10 1056 NEJM200006223422507 PMC 1557642 PMID 10861325 Ioannidis JP Haidich AB Pappa M Pantazis N Kokori SI Tektonidou MG Contopoulos Ioannidis DG Lau J 2001 Comparison of evidence of treatment effects in randomized and nonrandomized studies J Am Med Assoc 286 7 821 30 CiteSeerX 10 1 1 590 2854 doi 10 1001 jama 286 7 821 PMID 11497536 Anglemyer A Horvath HT Bero L April 2014 Healthcare outcomes assessed with observational study designs compared with those assessed in randomized trials The Cochrane Database of Systematic Reviews 2014 4 MR000034 doi 10 1002 14651858 MR000034 pub2 PMC 8191367 PMID 24782322 Vandenbroucke JP 2008 Observational research randomised trials and two views of medical science PLoS Med 5 3 e67 doi 10 1371 journal pmed 0050067 PMC 2265762 PMID 18336067 a b c d Black N 1996 Why we need observational studies to evaluate the effectiveness of health care BMJ 312 7040 1215 8 doi 10 1136 bmj 312 7040 1215 PMC 2350940 PMID 8634569 a b Glasziou P Chalmers I Rawlins M McCulloch P 2007 When are randomised trials unnecessary Picking signal from noise Br Med J 334 7589 349 51 doi 10 1136 bmj 39070 527986 68 PMC 1800999 PMID 17303884 Einhorn LH 2002 Curing metastatic testicular cancer Proc Natl Acad Sci U S A 99 7 4592 5 doi 10 1073 pnas 072067999 PMC 123692 PMID 11904381 Wittes J 2002 Sample size calculations for randomized controlled trials Epidemiol Rev 24 1 39 53 doi 10 1093 epirev 24 1 39 PMID 12119854 Freiman JA Chalmers TC Smith H Jr Kuebler RR 1978 The importance of beta the type II error and sample size in the design and interpretation of the randomized control trial Survey of 71 negative trials N Engl J Med 299 13 690 4 doi 10 1056 NEJM197809282991304 PMID 355881 Charles P Giraudeau B Dechartres A Baron G Ravaud P 2009 05 12 Reporting of sample size calculation in randomised controlled trials review Br Med J 338 b1732 doi 10 1136 bmj b1732 PMC 2680945 PMID 19435763 Richard Harris 22 Dec 2018 Researchers Show Parachutes Don t Work But There s A Catch National Health and Medical Research Council 1998 11 16 A guide to the development implementation and evaluation of clinical practice guidelines PDF Canberra Commonwealth of Australia p 56 ISBN 978 1 86496 048 8 Retrieved 2010 03 28 a b Harris RP Helfand M Woolf SH Lohr KN Mulrow CD Teutsch SM Atkins D Methods Work Group Third US Preventive Services Task Force 2001 Current methods of the US Preventive Services Task Force a review of the process PDF Am J Prev Med 20 3 Suppl 21 35 doi 10 1016 S0749 3797 01 00261 6 PMID 11306229 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Guyatt GH Oxman AD Kunz R Vist GE Falck Ytter Y Schunemann HJ GRADE Working Group 2008 What is quality of evidence and why is it important to clinicians BMJ 336 7651 995 8 doi 10 1136 bmj 39490 551019 BE PMC 2364804 PMID 18456631 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Oxford Centre for Evidence based Medicine 2011 09 16 Levels of evidence Retrieved 2012 02 15 a b c Anderson JL Pratt CM Waldo AL Karagounis LA 1997 Impact of the Food and Drug Administration approval of flecainide and encainide on coronary artery disease mortality putting Deadly Medicine to the test Am J Cardiol 79 1 43 7 doi 10 1016 S0002 9149 96 00673 X PMID 9024734 a b Rubin R 2006 10 16 In medicine evidence can be confusing deluged with studies doctors try to sort out what works what doesn t USA Today Retrieved 2010 03 22 Cardiac Arrhythmia Suppression Trial CAST Investigators 1989 Preliminary report effect of encainide and flecainide on mortality in a randomized trial of arrhythmia suppression after myocardial infarction The Cardiac Arrhythmia Suppression Trial CAST Investigators N Engl J Med 321 6 406 12 doi 10 1056 NEJM198908103210629 PMID 2473403 Anderson GL Limacher M Assaf AR Bassford T Beresford SA Black H et al 2004 Effects of conjugated equine estrogen in postmenopausal women with hysterectomy the Women s Health Initiative randomized controlled trial JAMA 291 14 1701 12 doi 10 1001 jama 291 14 1701 PMID 15082697 Grodstein F Clarkson TB Manson JE 2003 Understanding the divergent data on postmenopausal hormone therapy N Engl J Med 348 7 645 50 doi 10 1056 NEJMsb022365 PMID 12584376 Vandenbroucke JP 2009 The HRT controversy observational studies and RCTs fall in line Lancet 373 9671 1233 5 doi 10 1016 S0140 6736 09 60708 X PMID 19362661 S2CID 44991220 Hsu A Card A Lin SX Mota S Carrasquillo O Moran A 2009 Changes in postmenopausal hormone replacement therapy use among women with high cardiovascular risk Am J Public Health 99 12 2184 7 doi 10 2105 AJPH 2009 159889 PMC 2775780 PMID 19833984 Bell S H amp Peck L R 2012 Obstacles to and limitations of social experiments 15 false alarms Abt Thought Leadership Paper Series a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link a b c Sanson Fisher RW Bonevski B Green LW D Este C 2007 Limitations of the randomized controlled trial in evaluating population based health interventions Am J Prev Med 33 2 155 61 doi 10 1016 j amepre 2007 04 007 PMID 17673104 a b Johnston SC Rootenberg JD Katrak S Smith WS Elkins JS 2006 Effect of a US National Institutes of Health programme of clinical trials on public health and costs PDF Lancet 367 9519 1319 27 doi 10 1016 S0140 6736 06 68578 4 PMID 16631910 S2CID 41035177 a b Yitschaky O Yitschaky M Zadik Y May 2011 Case report on trial Do you Doctor swear to tell the truth the whole truth and nothing but the truth PDF J Med Case Rep 5 1 179 doi 10 1186 1752 1947 5 179 PMC 3113995 PMID 21569508 How Well Do Meta Analyses Disclose Conflicts of Interests in Underlying Research Studies The Cochrane Collaboration Cochrane org Retrieved 2011 08 19 Bekelman JE Li Y Gross CP 2003 Scope and impact of financial conflicts of interest in biomedical research a systematic review J Am Med Assoc 289 4 454 65 doi 10 1001 jama 289 4 454 PMID 12533125 a b Bhandari M Busse JW Jackowski D Montori VM Schunemann H Sprague S Mears D Schemitsch EH Heels Ansdell D Devereaux PJ 2004 Association between industry funding and statistically significant pro industry findings in medical and surgical randomized trials Can Med Assoc J 170 4 477 80 PMC 332713 PMID 14970094 Chapman SJ Shelton B Mahmood H Fitzgerald JE Harrison EM Bhangu A 2014 Discontinuation and non publication of surgical randomised controlled trials observational study BMJ 349 g6870 doi 10 1136 bmj g6870 PMC 4260649 PMID 25491195 Ridker PM Torres J 2006 Reported outcomes in major cardiovascular clinical trials funded by for profit and not for profit organizations 2000 2005 JAMA 295 19 2270 4 doi 10 1001 jama 295 19 2270 PMID 16705108 Song Zhang Jing Cao Ahn C 23 June 2010 Calculating sample size in trials using historical controls Clinical Trials Journal of the Society for Clinical Trials 7 4 343 353 doi 10 1177 1740774510373629 PMC 3085081 PMID 20573638 Rowland D DiGuiseppi C Gross M Afolabi E and Roberts I 2003 Randomised controlled trial of site specific advice on school travel patterns Archives of Disease in Childhood 88 1 8 11 doi 10 1136 adc 88 1 8 PMC 1719287 PMID 12495948 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Graham Rowe E Skippon S Gardner B and Abraham C 2011 Can we reduce car use and if so how A review of available evidence Transportation Research Part A Policy and Practice 44 5 401 418 doi 10 1016 j tra 2011 02 001 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Melia 2011 Do Randomised Control Trials Offer a Solution to low Quality Transport Research Bristol University of the West of England a b Farrington DP Welsh BC 2005 Randomized experiments in criminology What have we learned in the last two decades Journal of Experimental Criminology 1 1 9 38 doi 10 1007 s11292 004 6460 0 S2CID 145758503 Hollin CR 2008 Evaluating offending behaviour programmes does only randomization glister Criminology and Criminal Justice 8 1 89 106 doi 10 1177 1748895807085871 S2CID 141222135 Connolly Paul Keenan Ciara Urbanska Karolina 2018 07 09 The trials of evidence based practice in education a systematic review of randomised controlled trials in education research 1980 2016 Educational Research 60 3 276 291 doi 10 1080 00131881 2018 1493353 ISSN 0013 1881 Walker HM Seeley JR Small J Severson HH Graham BA Feil EG Serna L Golly AM Forness SR 2009 A randomized controlled trial of the First Step to Success early intervention Demonstration of program efficacy outcomes in a diverse urban school district Journal of Emotional and Behavioral Disorders 17 4 197 212 doi 10 1177 1063426609341645 S2CID 144571336 Bradshaw CP Zmuda JH Kellam SG Ialongo NS 2009 Longitudinal impact of two universal preventive interventions in first grade on educational outcomes in high school Journal of Educational Psychology 101 4 926 937 doi 10 1037 a0016586 PMC 3678772 PMID 23766545 Krauss Alexander 2018 Why all randomised controlled trials produce biased results Annals of Medicine 50 4 312 322 doi 10 1080 07853890 2018 1453233 ISSN 0785 3890 PMID 29616838 External links EditBland M Directory of randomisation software and services University of York 2008 March 19 Evans I Thornton H Chalmers I Testing treatments better research for better health care London Pinter amp Martin 2010 ISBN 978 1 905177 35 6 Gelband H The impact of randomized clinical trials on health policy and medical practice background paper Archived 2016 03 03 at the Wayback Machine Washington DC U S Congress Office of Technology Assessment 1983 Report OTA BP H 22 REFLECT Reporting guidElines For randomized controLled trials for livEstoCk and food safeTy Statement Wathen JK Cook JD Power and bias in adaptively randomized clinical trials M D Anderson Cancer Center University of Texas 2006 July 12 Retrieved from https en wikipedia org w index php title Randomized controlled trial amp oldid 1146786349, wikipedia, wiki, book, books, library,

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