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Acute radiation syndrome

May 04, 2024

"Radiation poisoning" redirects here. For other uses, see Radiation poisoning (disambiguation).

Acute radiation syndrome (ARS), also known as radiation sickness or radiation poisoning, is a collection of health effects that are caused by being exposed to high amounts of ionizing radiation in a short period of time.[1] Symptoms can start within an hour of exposure, and can last for several months.[1][3][5] Early symptoms are usually nausea, vomiting and loss of appetite.[1] In the following hours or weeks, initial symptoms may appear to improve, before the development of additional symptoms, after which either recovery or death follow.[1]

Acute radiation syndrome
Other namesRadiation poisoning, radiation sickness, radiation toxicity
Radiation causes cellular degradation by autophagy.
SpecialtyCritical care medicine
SymptomsEarly: Nausea, vomiting, skin burns, loss of appetite[1]
Later: Infections, bleeding, dehydration, confusion[1]
ComplicationsCancer[2]
Usual onsetWithin days[1]
TypesBone marrow syndrome, gastrointestinal syndrome, neurovascular syndrome[1][3]
CausesLarge amounts of ionizing radiation over a short period of time[1]
Diagnostic methodBased on history of exposure and symptoms[4]
TreatmentSupportive care (blood transfusions, antibiotics, colony stimulating factors, stem cell transplant)[3]
PrognosisDepends on the exposure dose[4]
FrequencyRare[3]

ARS involves a total dose of greater than 0.7 Gy (70 rad), that generally occurs from a source outside the body, delivered within a few minutes.[1] Sources of such radiation can occur accidentally or intentionally.[6] They may involve nuclear reactors, cyclotrons, certain devices used in cancer therapy, nuclear weapons, or radiological weapons.[4] It is generally divided into three types: bone marrow, gastrointestinal, and neurovascular syndrome, with bone marrow syndrome occurring at 0.7 to 10 Gy, and neurovascular syndrome occurring at doses that exceed 50 Gy.[1][3] The cells that are most affected are generally those that are rapidly dividing.[3] At high doses, this causes DNA damage that may be irreparable.[4] Diagnosis is based on a history of exposure and symptoms.[4] Repeated complete blood counts (CBCs) can indicate the severity of exposure.[1]

Treatment of ARS is generally supportive care. This may include blood transfusions, antibiotics, colony-stimulating factors, or stem cell transplant.[3] Radioactive material remaining on the skin or in the stomach should be removed. If radioiodine was inhaled or ingested, potassium iodide is recommended. Complications such as leukemia and other cancers among those who survive are managed as usual. Short term outcomes depend on the dose exposure.[4]

ARS is generally rare.[3] A single event can affect a large number of people,[7] as happened in the atomic bombings of Hiroshima and Nagasaki and the Chernobyl nuclear power plant disaster.[1] ARS differs from chronic radiation syndrome, which occurs following prolonged exposures to relatively low doses of radiation.[8][9]

Signs and symptoms edit

See also: Effects of nuclear explosions on human health
 
Radiation sickness

Classically, ARS is divided into three main presentations: hematopoietic, gastrointestinal, and neurovascular. These syndromes may be preceded by a prodrome.[3] The speed of symptom onset is related to radiation exposure, with greater doses resulting in a shorter delay in symptom onset.[3] These presentations presume whole-body exposure, and many of them are markers that are invalid if the entire body has not been exposed. Each syndrome requires that the tissue showing the syndrome itself be exposed (e.g., gastrointestinal syndrome is not seen if the stomach and intestines are not exposed to radiation). Some areas affected are:

  1. Hematopoietic. This syndrome is marked by a drop in the number of blood cells, called aplastic anemia. This may result in infections, due to a low number of white blood cells, bleeding, due to a lack of platelets, and anemia, due to too few red blood cells in circulation.[3] These changes can be detected by blood tests after receiving a whole-body acute dose as low as 0.25 grays (25 rad), though they might never be felt by the patient if the dose is below 1 gray (100 rad). Conventional trauma and burns resulting from a bomb blast are complicated by the poor wound healing caused by hematopoietic syndrome, increasing mortality.
  2. Gastrointestinal. This syndrome often follows absorbed doses of 6–30 grays (600–3,000 rad).[3] The signs and symptoms of this form of radiation injury include nausea, vomiting, loss of appetite, and abdominal pain.[10] Vomiting in this time-frame is a marker for whole body exposures that are in the fatal range above 4 grays (400 rad). Without exotic treatment such as bone marrow transplant, death with this dose is common,[3] due generally more to infection than gastrointestinal dysfunction.
  3. Neurovascular. This syndrome typically occurs at absorbed doses greater than 30 grays (3,000 rad), though it may occur at doses as low as 10 grays (1,000 rad).[3] It presents with neurological symptoms such as dizziness, headache, or decreased level of consciousness, occurring within minutes to a few hours, with an absence of vomiting, and is almost always fatal, even with aggressive intensive care.[3]

Early symptoms of ARS typically include nausea, vomiting, headaches, fatigue, fever, and a short period of skin reddening.[3] These symptoms may occur at radiation doses as low as 0.35 grays (35 rad). These symptoms are common to many illnesses, and may not, by themselves, indicate acute radiation sickness.[3]

Dose effects edit

Phase Symptom Whole-body absorbed dose (Gy)
1–2 Gy 2–6 Gy 6–8 Gy 8–30 Gy > 30 Gy
Immediate Nausea and vomiting 5–50% 50–100% 75–100% 90–100% 100%
Time of onset 2–6 h 1–2 h 10–60 min < 10 min Minutes
Duration < 24 h 24–48 h < 48 h < 48 h — (patients die in < 48 h)
Diarrhea None None to mild (< 10%) Heavy (> 10%) Heavy (> 95%) Heavy (100%)
Time of onset 3–8 h 1–3 h < 1 h < 1 h
Headache Slight Mild to moderate (50%) Moderate (80%) Severe (80–90%) Severe (100%)
Time of onset 4–24 h 3–4 h 1–2 h < 1 h
Fever None Moderate increase (10–100%) Moderate to severe (100%) Severe (100%) Severe (100%)
Time of onset 1–3 h < 1 h < 1 h < 1 h
CNS function No impairment Cognitive impairment 6–20 h Cognitive impairment > 24 h Rapid incapacitation Seizures, tremor, ataxia, lethargy
Latent period 28–31 days 7–28 days < 7 days None None
Illness Mild to moderate Leukopenia
Fatigue
Weakness 		Moderate to severe Leukopenia
Purpura
Hemorrhage
Infections
Alopecia after 3 Gy 		Severe leukopenia
High fever
Diarrhea
Vomiting
Dizziness and disorientation
Hypotension
Electrolyte disturbance 		Nausea
Vomiting
Severe diarrhea
High fever
Electrolyte disturbance
Shock 		— (patients die in < 48h)
Mortality Without care 0–5% 5–95% 95–100% 100% 100%
With care 0–5% 5–50% 50–100% 99–100% 100%
Death 6–8 weeks 4–6 weeks 2–4 weeks 2 days – 2 weeks 1–2 days
Table source[11]

A similar table and description of symptoms (given in rems, where 100 rem = 1 Sv), derived from data from the effects on humans subjected to the atomic bombings of Hiroshima and Nagasaki, the indigenous peoples of the Marshall Islands subjected to the Castle Bravo thermonuclear bomb, animal studies and lab experiment accidents, have been compiled by the U.S. Department of Defense.[12]

A person who was less than 1 mile (1.6 km) from the atomic bomb Little Boy's hypocenter at Hiroshima, Japan, was found to have absorbed about 9.46 grays (Gy) of ionizing radiation.[13][14][15][16] The doses at the hypocenters of the Hiroshima and Nagasaki atomic bombings were 240 and 290 Gy, respectively.[17]

Skin changes edit

Main article: Radiation burn
 
Harry K. Daghlian's hand 9 days after he had manually stopped a prompt critical fission reaction during an accident with what later obtained the nickname the demon core. He received a dose of 5.1 Sv,[18] or 3.1 Gy.[19] He died 16 days after this photo was taken.

Cutaneous radiation syndrome (CRS) refers to the skin symptoms of radiation exposure.[1] Within a few hours after irradiation, a transient and inconsistent redness (associated with itching) can occur. Then, a latent phase may occur and last from a few days up to several weeks, when intense reddening, blistering, and ulceration of the irradiated site is visible. In most cases, healing occurs by regenerative means; however, very large skin doses can cause permanent hair loss, damaged sebaceous and sweat glands, atrophy, fibrosis (mostly keloids), decreased or increased skin pigmentation, and ulceration or necrosis of the exposed tissue.[1] As seen at Chernobyl, when skin is irradiated with high energy beta particles, moist desquamation (peeling of skin) and similar early effects can heal, only to be followed by the collapse of the dermal vascular system after two months, resulting in the loss of the full thickness of the exposed skin.[20] Another example of skin loss caused by high-level exposure of radiation is during the 1999 Tokaimura nuclear accident, where technician Hisashi Ouchi had lost a majority of his skin due to the high amounts of radiation he absorbed during the irradiation. This effect had been demonstrated previously with pig skin using high energy beta sources at the Churchill Hospital Research Institute, in Oxford.[21]

Cause edit

 
Both dose and dose rate contribute to the severity of acute radiation syndrome. The effects of dose fractionation or rest periods before repeated exposure also shift the LD50 dose upwards.
 
Comparison of Radiation Doses – includes the amount detected on the trip from Earth to Mars by the RAD on the MSL (2011–2013).[22][23][24][25]

ARS is caused by exposure to a large dose of ionizing radiation (> ~0.1 Gy) over a short period of time (> ~0.1 Gy/h). Alpha and beta radiation have low penetrating power and are unlikely to affect vital internal organs from outside the body. Any type of ionizing radiation can cause burns, but alpha and beta radiation can only do so if radioactive contamination or nuclear fallout is deposited on the individual's skin or clothing. Gamma and neutron radiation can travel much greater distances and penetrate the body easily, so whole-body irradiation generally causes ARS before skin effects are evident. Local gamma irradiation can cause skin effects without any sickness. In the early twentieth century, radiographers would commonly calibrate their machines by irradiating their own hands and measuring the time to onset of erythema.[26]

Accidental edit

Main article: Nuclear and radiation accidents and incidents

Accidental exposure may be the result of a criticality or radiotherapy accident. There have been numerous criticality accidents dating back to atomic testing during World War II, while computer-controlled radiation therapy machines such as Therac-25 played a major part in radiotherapy accidents. The latter of the two is caused by the failure of equipment software used to monitor the radiational dose given. Human error has played a large part in accidental exposure incidents, including some of the criticality accidents, and larger scale events such as the Chernobyl disaster. Other events have to do with orphan sources, in which radioactive material is unknowingly kept, sold, or stolen. The Goiânia accident is an example, where a forgotten radioactive source was taken from a hospital, resulting in the deaths of 4 people from ARS.[27] Theft and attempted theft of radioactive material by clueless thieves has also led to lethal exposure in at least one incident.[28]

Exposure may also come from routine spaceflight and solar flares that result in radiation effects on earth in the form of solar storms. During spaceflight, astronauts are exposed to both galactic cosmic radiation (GCR) and solar particle event (SPE) radiation. The exposure particularly occurs during flights beyond low Earth orbit (LEO). Evidence indicates past SPE radiation levels that would have been lethal for unprotected astronauts.[29] GCR levels that might lead to acute radiation poisoning are less well understood.[30] The latter cause is rarer, with an event possibly occurring during the solar storm of 1859.

Intentional edit

Main articles: Atomic bombings of Hiroshima and Nagasaki and Crimes involving radioactive substances

Intentional exposure is controversial as it involves the use of nuclear weapons, human experiments, or is given to a victim in an act of murder. The intentional atomic bombings of Hiroshima and Nagasaki resulted in tens of thousands of casualties; the survivors of these bombings are known today as Hibakusha. Nuclear weapons emit large amounts of thermal radiation as visible, infrared, and ultraviolet light, to which the atmosphere is largely transparent. This event is also known as "Flash", where radiant heat and light are bombarded into any given victim's exposed skin, causing radiation burns.[31] Death is highly likely, and radiation poisoning is almost certain if one is caught in the open with no terrain or building masking-effects within a radius of 0–3 km from a 1 megaton airburst. The 50% chance of death from the blast extends out to ~8 km from a 1 megaton atmospheric explosion.[32]

Scientific testing on humans within the United States occurred extensively throughout the atomic age. Experiments took place on a range of subjects including, but not limited to; the disabled, children, soldiers, and incarcerated persons, with the level of understanding and consent given by subjects varying from complete to none. Since 1997 there have been requirements for patients to give informed consent, and to be notified if experiments were classified.[33] Across the world, the Soviet nuclear program involved human experiments on a large scale, which is still kept secret by the Russian government and the Rosatom agency.[34][35] The human experiments that fall under intentional ARS exclude those that involved long term exposure. Criminal activity has involved murder and attempted murder carried out through abrupt victim contact with a radioactive substance such as polonium or plutonium.

Pathophysiology edit

The most commonly used predictor of ARS is the whole-body absorbed dose. Several related quantities, such as the equivalent dose, effective dose, and committed dose, are used to gauge long-term stochastic biological effects such as cancer incidence, but they are not designed to evaluate ARS.[36] To help avoid confusion between these quantities, absorbed dose is measured in units of grays (in SI, unit symbol Gy) or rad (in CGS), while the others are measured in sieverts (in SI, unit symbol Sv) or rem (in CGS). 1 rad = 0.01 Gy and 1 rem = 0.01 Sv.[37]

In most of the acute exposure scenarios that lead to radiation sickness, the bulk of the radiation is external whole-body gamma, in which case the absorbed, equivalent, and effective doses are all equal. There are exceptions, such as the Therac-25 accidents and the 1958 Cecil Kelley criticality accident, where the absorbed doses in Gy or rad are the only useful quantities, because of the targeted nature of the exposure to the body.

Radiotherapy treatments are typically prescribed in terms of the local absorbed dose, which might be 60 Gy or higher. The dose is fractionated to about 2 Gy per day for curative treatment, which allows normal tissues to undergo repair, allowing them to tolerate a higher dose than would otherwise be expected. The dose to the targeted tissue mass must be averaged over the entire body mass, most of which receives negligible radiation, to arrive at a whole-body absorbed dose that can be compared to the table above.[citation needed]

DNA damage edit

Exposure to high doses of radiation causes DNA damage, later creating serious and even lethal chromosomal aberrations if left unrepaired. Ionizing radiation can produce reactive oxygen species, and does directly damage cells by causing localized ionization events. The former is very damaging to DNA, while the latter events create clusters of DNA damage.[38][39] This damage includes loss of nucleobases and breakage of the sugar-phosphate backbone that binds to the nucleobases. The DNA organization at the level of histones, nucleosomes, and chromatin also affects its susceptibility to radiation damage.[40] Clustered damage, defined as at least two lesions within a helical turn, is especially harmful.[39] While DNA damage happens frequently and naturally in the cell from endogenous sources, clustered damage is a unique effect of radiation exposure.[41] Clustered damage takes longer to repair than isolated breakages, and is less likely to be repaired at all.[42] Larger radiation doses are more prone to cause tighter clustering of damage, and closely localized damage is increasingly less likely to be repaired.[39]

Somatic mutations cannot be passed down from parent to offspring, but these mutations can propagate in cell lines within an organism. Radiation damage can also cause chromosome and chromatid aberrations, and their effects depend on in which stage of the mitotic cycle the cell is when the irradiation occurs. If the cell is in interphase, while it is still a single strand of chromatin, the damage will be replicated during the S1 phase of the cell cycle, and there will be a break on both chromosome arms; the damage then will be apparent in both daughter cells. If the irradiation occurs after replication, only one arm will bear the damage; this damage will be apparent in only one daughter cell. A damaged chromosome may cyclize, binding to another chromosome, or to itself.[43]

Diagnosis edit

Diagnosis is typically made based on a history of significant radiation exposure and suitable clinical findings.[3] An absolute lymphocyte count can give a rough estimate of radiation exposure.[3] Time from exposure to vomiting can also give estimates of exposure levels if they are less than 10 Gy (1000 rad).[3]

Prevention edit

A guiding principle of radiation safety is as low as reasonably achievable (ALARA).[44] This means try to avoid exposure as much as possible and includes the three components of time, distance, and shielding.[44]

Time edit

The longer that humans are subjected to radiation the larger the dose will be. The advice in the nuclear war manual entitled Nuclear War Survival Skills published by Cresson Kearny in the U.S. was that if one needed to leave the shelter then this should be done as rapidly as possible to minimize exposure.[45]

In chapter 12, he states that "[q]uickly putting or dumping wastes outside is not hazardous once fallout is no longer being deposited. For example, assume the shelter is in an area of heavy fallout and the dose rate outside is 400 roentgen (R) per hour, enough to give a potentially fatal dose in about an hour to a person exposed in the open. If a person needs to be exposed for only 10 seconds to dump a bucket, in this 1/360 of an hour he will receive a dose of only about 1 R. Under war conditions, an additional 1-R dose is of little concern." In peacetime, radiation workers are taught to work as quickly as possible when performing a task that exposes them to radiation. For instance, the recovery of a radioactive source should be done as quickly as possible.[citation needed]

Shielding edit

See also: Radiation protection

Matter attenuates radiation in most cases, so placing any mass (e.g., lead, dirt, sandbags, vehicles, water, even air) between humans and the source will reduce the radiation dose. This is not always the case, however; care should be taken when constructing shielding for a specific purpose. For example, although high atomic number materials are very effective in shielding photons, using them to shield beta particles may cause higher radiation exposure due to the production of bremsstrahlung x-rays, and hence low atomic number materials are recommended. Also, using material with a high neutron activation cross section to shield neutrons will result in the shielding material itself becoming radioactive and hence more dangerous than if it were not present.[citation needed]

There are many types of shielding strategies that can be used to reduce the effects of radiation exposure. Internal contamination protective equipment such as respirators are used to prevent internal deposition as a result of inhalation and ingestion of radioactive material. Dermal protective equipment, which protects against external contamination, provides shielding to prevent radioactive material from being deposited on external structures.[46] While these protective measures do provide a barrier from radioactive material deposition, they do not shield from externally penetrating gamma radiation. This leaves anyone exposed to penetrating gamma rays at high risk of ARS.

Naturally, shielding the entire body from high energy gamma radiation is optimal, but the required mass to provide adequate attenuation makes functional movement nearly impossible. In the event of a radiation catastrophe, medical and security personnel need mobile protection equipment in order to safely assist in containment, evacuation, and many other necessary public safety objectives.

Research has been done exploring the feasibility of partial body shielding, a radiation protection strategy that provides adequate attenuation to only the most radio-sensitive organs and tissues inside the body. Irreversible stem cell damage in the bone marrow is the first life-threatening effect of intense radiation exposure and therefore one of the most important bodily elements to protect. Due to the regenerative property of hematopoietic stem cells, it is only necessary to protect enough bone marrow to repopulate the exposed areas of the body with the shielded supply.[47] This concept allows for the development of lightweight mobile radiation protection equipment, which provides adequate protection, deferring the onset of ARS to much higher exposure doses. One example of such equipment is the 360 gamma, a radiation protection belt that applies selective shielding to protect the bone marrow stored in the pelvic area as well as other radio sensitive organs in the abdominal region without hindering functional mobility.

Reduction of incorporation edit

Where radioactive contamination is present, an elastomeric respirator, dust mask, or good hygiene practices may offer protection, depending on the nature of the contaminant. Potassium iodide (KI) tablets can reduce the risk of cancer in some situations due to slower uptake of ambient radioiodine. Although this does not protect any organ other than the thyroid gland, their effectiveness is still highly dependent on the time of ingestion, which would protect the gland for the duration of a twenty-four-hour period. They do not prevent ARS as they provide no shielding from other environmental radionuclides.[48]

Fractionation of dose edit

Main article: Dose fractionation

If an intentional dose is broken up into a number of smaller doses, with time allowed for recovery between irradiations, the same total dose causes less cell death. Even without interruptions, a reduction in dose rate below 0.1 Gy/h also tends to reduce cell death.[36] This technique is routinely used in radiotherapy.[citation needed]

The human body contains many types of cells and a human can be killed by the loss of a single type of cells in a vital organ. For many short term radiation deaths (3–30 days), the loss of two important types of cells that are constantly being regenerated causes death. The loss of cells forming blood cells (bone marrow) and the cells in the digestive system (microvilli, which form part of the wall of the intestines) is fatal.[citation needed]

Management edit

 
Effect of medical care on acute radiation syndrome

Treatment usually involves supportive care with possible symptomatic measures employed. The former involves the possible use of antibiotics, blood products, colony stimulating factors, and stem cell transplant.[3]

Antimicrobials edit

Main article: Treatment of infections after exposure to ionizing radiation

There is a direct relationship between the degree of the neutropenia that emerges after exposure to radiation and the increased risk of developing infection. Since there are no controlled studies of therapeutic intervention in humans, most of the current recommendations are based on animal research.[citation needed]

The treatment of established or suspected infection following exposure to radiation (characterized by neutropenia and fever) is similar to the one used for other febrile neutropenic patients. However, important differences between the two conditions exist. Individuals that develop neutropenia after exposure to radiation are also susceptible to irradiation damage in other tissues, such as the gastrointestinal tract, lungs and central nervous system. These patients may require therapeutic interventions not needed in other types of neutropenic patients. The response of irradiated animals to antimicrobial therapy can be unpredictable, as was evident in experimental studies where metronidazole[49] and pefloxacin[50] therapies were detrimental.

Antimicrobials that reduce the number of the strict anaerobic component of the gut flora (i.e., metronidazole) generally should not be given because they may enhance systemic infection by aerobic or facultative bacteria, thus facilitating mortality after irradiation.[51]

An empirical regimen of antimicrobials should be chosen based on the pattern of bacterial susceptibility and nosocomial infections in the affected area and medical center and the degree of neutropenia. Broad-spectrum empirical therapy (see below for choices) with high doses of one or more antibiotics should be initiated at the onset of fever. These antimicrobials should be directed at the eradication of Gram-negative aerobic bacilli (i.e., Enterobacteriaceae, Pseudomonas) that account for more than three quarters of the isolates causing sepsis. Because aerobic and facultative Gram-positive bacteria (mostly alpha-hemolytic streptococci) cause sepsis in about a quarter of the victims, coverage for these organisms may also be needed.[52]

A standardized management plan for people with neutropenia and fever should be devised. Empirical regimens contain antibiotics broadly active against Gram-negative aerobic bacteria (quinolones: i.e., ciprofloxacin, levofloxacin, a third- or fourth-generation cephalosporin with pseudomonal coverage: e.g., cefepime, ceftazidime, or an aminoglycoside: i.e. gentamicin, amikacin).[53]

Prognosis edit

See also: Radiation-induced cancer

The prognosis for ARS is dependent on the exposure dose, with anything above 8 Gy being almost always lethal, even with medical care.[4][54] Radiation burns from lower-level exposures usually manifest after 2 months, while reactions from the burns occur months to years after radiation treatment.[55][56] Complications from ARS include an increased risk of developing radiation-induced cancer later in life. According to the controversial but commonly applied linear no-threshold model, any exposure to ionizing radiation, even at doses too low to produce any symptoms of radiation sickness, can induce cancer due to cellular and genetic damage. The probability of developing cancer is a linear function with respect to the effective radiation dose. Radiation cancer may occur after ionizing radiation exposure following a latent period averaging 20 to 40 years.[57][55]

History edit

Acute effects of ionizing radiation were first observed when Wilhelm Röntgen intentionally subjected his fingers to X-rays in 1895. He published his observations concerning the burns that developed that eventually healed, and misattributed them to ozone. Röntgen believed the free radical produced in air by X-rays from the ozone was the cause, but other free radicals produced within the body are now understood to be more important. David Walsh first established the symptoms of radiation sickness in 1897.[58]

Ingestion of radioactive materials caused many radiation-induced cancers in the 1930s, but no one was exposed to high enough doses at high enough rates to bring on ARS.

The atomic bombings of Hiroshima and Nagasaki resulted in high acute doses of radiation to a large number of Japanese people, allowing for greater insight into its symptoms and dangers. Red Cross Hospital Surgeon Terufumi Sasaki led intensive research into the syndrome in the weeks and months following the Hiroshima and Nagasaki bombings. Sasaki and his team were able to monitor the effects of radiation in patients of varying proximities to the blast itself, leading to the establishment of three recorded stages of the syndrome. Within 25–30 days of the explosion, Sasaki noticed a sharp drop in white blood cell count and established this drop, along with symptoms of fever, as prognostic standards for ARS.[59] Actress Midori Naka, who was present during the atomic bombing of Hiroshima, was the first incident of radiation poisoning to be extensively studied. Her death on 24 August 1945 was the first death ever to be officially certified as a result of ARS (or "Atomic bomb disease").

There are two major databases that track radiation accidents: The American ORISE REAC/TS and the European IRSN ACCIRAD. REAC/TS shows 417 accidents occurring between 1944 and 2000, causing about 3000 cases of ARS, of which 127 were fatal.[60] ACCIRAD lists 580 accidents with 180 ARS fatalities for an almost identical period.[61] The two deliberate bombings are not included in either database, nor are any possible radiation-induced cancers from low doses. The detailed accounting is difficult because of confounding factors. ARS may be accompanied by conventional injuries such as steam burns, or may occur in someone with a pre-existing condition undergoing radiotherapy. There may be multiple causes for death, and the contribution from radiation may be unclear. Some documents may incorrectly refer to radiation-induced cancers as radiation poisoning, or may count all overexposed individuals as survivors without mentioning if they had any symptoms of ARS.

Notable cases edit

The following table includes only those known for their attempted survival with ARS. These cases exclude chronic radiation syndrome such as Albert Stevens, in which radiation is exposed to a given subject over a long duration. The table also necessarily excludes cases where the individual was exposed to so much radiation that death occurred before medical assistance or dose estimations could be made, such as an attempted cobalt-60 thief who reportedly died 30 minutes after exposure.[62] The result column represents the time of exposure to the time of death attributed to the short and long term effects attributed to initial exposure. As ARS is measured by a whole-body absorbed dose, the exposure column only includes units of gray (Gy).

Date Name Exposure (Gy or Sv) Incident/accident Result
August 21, 1945 Harry Daghlian 3.1 Gy[19] Harry Daghlian criticality accident Death in 25 days
May 21, 1946 Louis Slotin 11 Gy[63] Slotin criticality accident Death in 9 days
Alvin C. Graves 1.9 Gy[19] Death in 19 years
December 30, 1958 Cecil Kelley 36 Gy[64] Cecil Kelley criticality accident Death in 38 hours
July 24, 1964 Robert Peabody ~100 Gy[65][66] Robert Peabody criticality accident Death in 49 hours
April 26, 1986 Aleksandr Akimov 15 Gy[67] Chernobyl disaster Death in 14 days
September 30, 1999 Hisashi Ouchi 17 Sv[68] Tokaimura nuclear accident Death in 83 days
December 2, 2001 Patient "1-DN" 3.6 Gy[69] Lia radiological accident Death in 893 days

Other animals edit

Thousands of scientific experiments have been performed to study ARS in animals.[citation needed] There is a simple guide for predicting survival and death in mammals, including humans, following the acute effects of inhaling radioactive particles.[70]

See also edit

References edit

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This article incorporates public domain material from websites or documents of the U.S. Armed Forces Radiobiology Research Institute and the U.S. Centers for Disease Control and Prevention

External links edit

 
Wikimedia Commons has media related to Acute radiation syndrome.
  • "Emergency preparedness and subject matter expertise on the medical management of radiation incidents". U.S. Radiation Emergency Assistance Center Training Site REACts. from the original on 2023-05-05.
  • . U.S. Centers for Disease Control and Prevention. Archived from the original on 16 July 2006. Retrieved 22 July 2006.
  • "The criticality accident in Sarov" (PDF). International Atomic Energy Agency. 2001. – A well documented account of the biological effects of a criticality accident.
  • . Archived from the original on 2015-03-03. Retrieved 2011-07-01.
  • More information on bone marrow shielding can be found in the Health Physics Radiation Safety Journal article: Waterman, Gideon; Kase, Kenneth; Orion, Itzhak; Broisman, Andrey; Milstein, Oren (September 2017). "Selective Shielding of Bone Marrow: An Approach to Protecting Humans from External Gamma Radiation". Health Physics. 113 (3): 195–208. doi:10.1097/HP.0000000000000688. PMID 28749810. S2CID 3300412., or in the Organisation for Economic Co-operation and Development (OECD) and the Nuclear Energy Agency (NEA)'s 2015 report: "Occupational Radiation Protection in Severe Accident Management"

May 04, 2024
acute, radiation, syndrome, radiation, poisoning, redirects, here, other, uses, radiation, poisoning, disambiguation, also, known, radiation, sickness, radiation, poisoning, collection, health, effects, that, caused, being, exposed, high, amounts, ionizing, ra. Radiation poisoning redirects here For other uses see Radiation poisoning disambiguation Acute radiation syndrome ARS also known as radiation sickness or radiation poisoning is a collection of health effects that are caused by being exposed to high amounts of ionizing radiation in a short period of time 1 Symptoms can start within an hour of exposure and can last for several months 1 3 5 Early symptoms are usually nausea vomiting and loss of appetite 1 In the following hours or weeks initial symptoms may appear to improve before the development of additional symptoms after which either recovery or death follow 1 Acute radiation syndromeOther namesRadiation poisoning radiation sickness radiation toxicityRadiation causes cellular degradation by autophagy SpecialtyCritical care medicineSymptomsEarly Nausea vomiting skin burns loss of appetite 1 Later Infections bleeding dehydration confusion 1 ComplicationsCancer 2 Usual onsetWithin days 1 TypesBone marrow syndrome gastrointestinal syndrome neurovascular syndrome 1 3 CausesLarge amounts of ionizing radiation over a short period of time 1 Diagnostic methodBased on history of exposure and symptoms 4 TreatmentSupportive care blood transfusions antibiotics colony stimulating factors stem cell transplant 3 PrognosisDepends on the exposure dose 4 FrequencyRare 3 ARS involves a total dose of greater than 0 7 Gy 70 rad that generally occurs from a source outside the body delivered within a few minutes 1 Sources of such radiation can occur accidentally or intentionally 6 They may involve nuclear reactors cyclotrons certain devices used in cancer therapy nuclear weapons or radiological weapons 4 It is generally divided into three types bone marrow gastrointestinal and neurovascular syndrome with bone marrow syndrome occurring at 0 7 to 10 Gy and neurovascular syndrome occurring at doses that exceed 50 Gy 1 3 The cells that are most affected are generally those that are rapidly dividing 3 At high doses this causes DNA damage that may be irreparable 4 Diagnosis is based on a history of exposure and symptoms 4 Repeated complete blood counts CBCs can indicate the severity of exposure 1 Treatment of ARS is generally supportive care This may include blood transfusions antibiotics colony stimulating factors or stem cell transplant 3 Radioactive material remaining on the skin or in the stomach should be removed If radioiodine was inhaled or ingested potassium iodide is recommended Complications such as leukemia and other cancers among those who survive are managed as usual Short term outcomes depend on the dose exposure 4 ARS is generally rare 3 A single event can affect a large number of people 7 as happened in the atomic bombings of Hiroshima and Nagasaki and the Chernobyl nuclear power plant disaster 1 ARS differs from chronic radiation syndrome which occurs following prolonged exposures to relatively low doses of radiation 8 9 Contents 1 Signs and symptoms 1 1 Dose effects 1 2 Skin changes 2 Cause 2 1 Accidental 2 2 Intentional 3 Pathophysiology 3 1 DNA damage 4 Diagnosis 5 Prevention 5 1 Time 5 2 Shielding 5 3 Reduction of incorporation 5 4 Fractionation of dose 6 Management 6 1 Antimicrobials 7 Prognosis 8 History 8 1 Notable cases 9 Other animals 10 See also 11 References 12 External linksSigns and symptoms editSee also Effects of nuclear explosions on human health nbsp Radiation sickness Classically ARS is divided into three main presentations hematopoietic gastrointestinal and neurovascular These syndromes may be preceded by a prodrome 3 The speed of symptom onset is related to radiation exposure with greater doses resulting in a shorter delay in symptom onset 3 These presentations presume whole body exposure and many of them are markers that are invalid if the entire body has not been exposed Each syndrome requires that the tissue showing the syndrome itself be exposed e g gastrointestinal syndrome is not seen if the stomach and intestines are not exposed to radiation Some areas affected are Hematopoietic This syndrome is marked by a drop in the number of blood cells called aplastic anemia This may result in infections due to a low number of white blood cells bleeding due to a lack of platelets and anemia due to too few red blood cells in circulation 3 These changes can be detected by blood tests after receiving a whole body acute dose as low as 0 25 grays 25 rad though they might never be felt by the patient if the dose is below 1 gray 100 rad Conventional trauma and burns resulting from a bomb blast are complicated by the poor wound healing caused by hematopoietic syndrome increasing mortality Gastrointestinal This syndrome often follows absorbed doses of 6 30 grays 600 3 000 rad 3 The signs and symptoms of this form of radiation injury include nausea vomiting loss of appetite and abdominal pain 10 Vomiting in this time frame is a marker for whole body exposures that are in the fatal range above 4 grays 400 rad Without exotic treatment such as bone marrow transplant death with this dose is common 3 due generally more to infection than gastrointestinal dysfunction Neurovascular This syndrome typically occurs at absorbed doses greater than 30 grays 3 000 rad though it may occur at doses as low as 10 grays 1 000 rad 3 It presents with neurological symptoms such as dizziness headache or decreased level of consciousness occurring within minutes to a few hours with an absence of vomiting and is almost always fatal even with aggressive intensive care 3 Early symptoms of ARS typically include nausea vomiting headaches fatigue fever and a short period of skin reddening 3 These symptoms may occur at radiation doses as low as 0 35 grays 35 rad These symptoms are common to many illnesses and may not by themselves indicate acute radiation sickness 3 Dose effects edit Phase Symptom Whole body absorbed dose Gy 1 2 Gy 2 6 Gy 6 8 Gy 8 30 Gy gt 30 Gy Immediate Nausea and vomiting 5 50 50 100 75 100 90 100 100 Time of onset 2 6 h 1 2 h 10 60 min lt 10 min Minutes Duration lt 24 h 24 48 h lt 48 h lt 48 h patients die in lt 48 h Diarrhea None None to mild lt 10 Heavy gt 10 Heavy gt 95 Heavy 100 Time of onset 3 8 h 1 3 h lt 1 h lt 1 h Headache Slight Mild to moderate 50 Moderate 80 Severe 80 90 Severe 100 Time of onset 4 24 h 3 4 h 1 2 h lt 1 h Fever None Moderate increase 10 100 Moderate to severe 100 Severe 100 Severe 100 Time of onset 1 3 h lt 1 h lt 1 h lt 1 h CNS function No impairment Cognitive impairment 6 20 h Cognitive impairment gt 24 h Rapid incapacitation Seizures tremor ataxia lethargy Latent period 28 31 days 7 28 days lt 7 days None None Illness Mild to moderate LeukopeniaFatigueWeakness Moderate to severe LeukopeniaPurpuraHemorrhageInfectionsAlopecia after 3 Gy Severe leukopeniaHigh feverDiarrheaVomitingDizziness and disorientationHypotensionElectrolyte disturbance NauseaVomitingSevere diarrheaHigh feverElectrolyte disturbanceShock patients die in lt 48h Mortality Without care 0 5 5 95 95 100 100 100 With care 0 5 5 50 50 100 99 100 100 Death 6 8 weeks 4 6 weeks 2 4 weeks 2 days 2 weeks 1 2 days Table source 11 A similar table and description of symptoms given in rems where 100 rem 1 Sv derived from data from the effects on humans subjected to the atomic bombings of Hiroshima and Nagasaki the indigenous peoples of the Marshall Islands subjected to the Castle Bravo thermonuclear bomb animal studies and lab experiment accidents have been compiled by the U S Department of Defense 12 A person who was less than 1 mile 1 6 km from the atomic bomb Little Boy s hypocenter at Hiroshima Japan was found to have absorbed about 9 46 grays Gy of ionizing radiation 13 14 15 16 The doses at the hypocenters of the Hiroshima and Nagasaki atomic bombings were 240 and 290 Gy respectively 17 Skin changes edit Main article Radiation burn nbsp Harry K Daghlian s hand 9 days after he had manually stopped a prompt critical fission reaction during an accident with what later obtained the nickname the demon core He received a dose of 5 1 Sv 18 or 3 1 Gy 19 He died 16 days after this photo was taken Cutaneous radiation syndrome CRS refers to the skin symptoms of radiation exposure 1 Within a few hours after irradiation a transient and inconsistent redness associated with itching can occur Then a latent phase may occur and last from a few days up to several weeks when intense reddening blistering and ulceration of the irradiated site is visible In most cases healing occurs by regenerative means however very large skin doses can cause permanent hair loss damaged sebaceous and sweat glands atrophy fibrosis mostly keloids decreased or increased skin pigmentation and ulceration or necrosis of the exposed tissue 1 As seen at Chernobyl when skin is irradiated with high energy beta particles moist desquamation peeling of skin and similar early effects can heal only to be followed by the collapse of the dermal vascular system after two months resulting in the loss of the full thickness of the exposed skin 20 Another example of skin loss caused by high level exposure of radiation is during the 1999 Tokaimura nuclear accident where technician Hisashi Ouchi had lost a majority of his skin due to the high amounts of radiation he absorbed during the irradiation This effect had been demonstrated previously with pig skin using high energy beta sources at the Churchill Hospital Research Institute in Oxford 21 Cause edit nbsp Both dose and dose rate contribute to the severity of acute radiation syndrome The effects of dose fractionation or rest periods before repeated exposure also shift the LD50 dose upwards nbsp Comparison of Radiation Doses includes the amount detected on the trip from Earth to Mars by the RAD on the MSL 2011 2013 22 23 24 25 ARS is caused by exposure to a large dose of ionizing radiation gt 0 1 Gy over a short period of time gt 0 1 Gy h Alpha and beta radiation have low penetrating power and are unlikely to affect vital internal organs from outside the body Any type of ionizing radiation can cause burns but alpha and beta radiation can only do so if radioactive contamination or nuclear fallout is deposited on the individual s skin or clothing Gamma and neutron radiation can travel much greater distances and penetrate the body easily so whole body irradiation generally causes ARS before skin effects are evident Local gamma irradiation can cause skin effects without any sickness In the early twentieth century radiographers would commonly calibrate their machines by irradiating their own hands and measuring the time to onset of erythema 26 Accidental edit Main article Nuclear and radiation accidents and incidents Accidental exposure may be the result of a criticality or radiotherapy accident There have been numerous criticality accidents dating back to atomic testing during World War II while computer controlled radiation therapy machines such as Therac 25 played a major part in radiotherapy accidents The latter of the two is caused by the failure of equipment software used to monitor the radiational dose given Human error has played a large part in accidental exposure incidents including some of the criticality accidents and larger scale events such as the Chernobyl disaster Other events have to do with orphan sources in which radioactive material is unknowingly kept sold or stolen The Goiania accident is an example where a forgotten radioactive source was taken from a hospital resulting in the deaths of 4 people from ARS 27 Theft and attempted theft of radioactive material by clueless thieves has also led to lethal exposure in at least one incident 28 Exposure may also come from routine spaceflight and solar flares that result in radiation effects on earth in the form of solar storms During spaceflight astronauts are exposed to both galactic cosmic radiation GCR and solar particle event SPE radiation The exposure particularly occurs during flights beyond low Earth orbit LEO Evidence indicates past SPE radiation levels that would have been lethal for unprotected astronauts 29 GCR levels that might lead to acute radiation poisoning are less well understood 30 The latter cause is rarer with an event possibly occurring during the solar storm of 1859 Intentional edit Main articles Atomic bombings of Hiroshima and Nagasaki and Crimes involving radioactive substances Intentional exposure is controversial as it involves the use of nuclear weapons human experiments or is given to a victim in an act of murder The intentional atomic bombings of Hiroshima and Nagasaki resulted in tens of thousands of casualties the survivors of these bombings are known today as Hibakusha Nuclear weapons emit large amounts of thermal radiation as visible infrared and ultraviolet light to which the atmosphere is largely transparent This event is also known as Flash where radiant heat and light are bombarded into any given victim s exposed skin causing radiation burns 31 Death is highly likely and radiation poisoning is almost certain if one is caught in the open with no terrain or building masking effects within a radius of 0 3 km from a 1 megaton airburst The 50 chance of death from the blast extends out to 8 km from a 1 megaton atmospheric explosion 32 Scientific testing on humans within the United States occurred extensively throughout the atomic age Experiments took place on a range of subjects including but not limited to the disabled children soldiers and incarcerated persons with the level of understanding and consent given by subjects varying from complete to none Since 1997 there have been requirements for patients to give informed consent and to be notified if experiments were classified 33 Across the world the Soviet nuclear program involved human experiments on a large scale which is still kept secret by the Russian government and the Rosatom agency 34 35 The human experiments that fall under intentional ARS exclude those that involved long term exposure Criminal activity has involved murder and attempted murder carried out through abrupt victim contact with a radioactive substance such as polonium or plutonium Pathophysiology editThe most commonly used predictor of ARS is the whole body absorbed dose Several related quantities such as the equivalent dose effective dose and committed dose are used to gauge long term stochastic biological effects such as cancer incidence but they are not designed to evaluate ARS 36 To help avoid confusion between these quantities absorbed dose is measured in units of grays in SI unit symbol Gy or rad in CGS while the others are measured in sieverts in SI unit symbol Sv or rem in CGS 1 rad 0 01 Gy and 1 rem 0 01 Sv 37 In most of the acute exposure scenarios that lead to radiation sickness the bulk of the radiation is external whole body gamma in which case the absorbed equivalent and effective doses are all equal There are exceptions such as the Therac 25 accidents and the 1958 Cecil Kelley criticality accident where the absorbed doses in Gy or rad are the only useful quantities because of the targeted nature of the exposure to the body Radiotherapy treatments are typically prescribed in terms of the local absorbed dose which might be 60 Gy or higher The dose is fractionated to about 2 Gy per day for curative treatment which allows normal tissues to undergo repair allowing them to tolerate a higher dose than would otherwise be expected The dose to the targeted tissue mass must be averaged over the entire body mass most of which receives negligible radiation to arrive at a whole body absorbed dose that can be compared to the table above citation needed DNA damage edit Exposure to high doses of radiation causes DNA damage later creating serious and even lethal chromosomal aberrations if left unrepaired Ionizing radiation can produce reactive oxygen species and does directly damage cells by causing localized ionization events The former is very damaging to DNA while the latter events create clusters of DNA damage 38 39 This damage includes loss of nucleobases and breakage of the sugar phosphate backbone that binds to the nucleobases The DNA organization at the level of histones nucleosomes and chromatin also affects its susceptibility to radiation damage 40 Clustered damage defined as at least two lesions within a helical turn is especially harmful 39 While DNA damage happens frequently and naturally in the cell from endogenous sources clustered damage is a unique effect of radiation exposure 41 Clustered damage takes longer to repair than isolated breakages and is less likely to be repaired at all 42 Larger radiation doses are more prone to cause tighter clustering of damage and closely localized damage is increasingly less likely to be repaired 39 Somatic mutations cannot be passed down from parent to offspring but these mutations can propagate in cell lines within an organism Radiation damage can also cause chromosome and chromatid aberrations and their effects depend on in which stage of the mitotic cycle the cell is when the irradiation occurs If the cell is in interphase while it is still a single strand of chromatin the damage will be replicated during the S1 phase of the cell cycle and there will be a break on both chromosome arms the damage then will be apparent in both daughter cells If the irradiation occurs after replication only one arm will bear the damage this damage will be apparent in only one daughter cell A damaged chromosome may cyclize binding to another chromosome or to itself 43 Diagnosis editDiagnosis is typically made based on a history of significant radiation exposure and suitable clinical findings 3 An absolute lymphocyte count can give a rough estimate of radiation exposure 3 Time from exposure to vomiting can also give estimates of exposure levels if they are less than 10 Gy 1000 rad 3 Prevention editA guiding principle of radiation safety is as low as reasonably achievable ALARA 44 This means try to avoid exposure as much as possible and includes the three components of time distance and shielding 44 Time edit The longer that humans are subjected to radiation the larger the dose will be The advice in the nuclear war manual entitled Nuclear War Survival Skills published by Cresson Kearny in the U S was that if one needed to leave the shelter then this should be done as rapidly as possible to minimize exposure 45 In chapter 12 he states that q uickly putting or dumping wastes outside is not hazardous once fallout is no longer being deposited For example assume the shelter is in an area of heavy fallout and the dose rate outside is 400 roentgen R per hour enough to give a potentially fatal dose in about an hour to a person exposed in the open If a person needs to be exposed for only 10 seconds to dump a bucket in this 1 360 of an hour he will receive a dose of only about 1 R Under war conditions an additional 1 R dose is of little concern In peacetime radiation workers are taught to work as quickly as possible when performing a task that exposes them to radiation For instance the recovery of a radioactive source should be done as quickly as possible citation needed Shielding edit See also Radiation protection Matter attenuates radiation in most cases so placing any mass e g lead dirt sandbags vehicles water even air between humans and the source will reduce the radiation dose This is not always the case however care should be taken when constructing shielding for a specific purpose For example although high atomic number materials are very effective in shielding photons using them to shield beta particles may cause higher radiation exposure due to the production of bremsstrahlung x rays and hence low atomic number materials are recommended Also using material with a high neutron activation cross section to shield neutrons will result in the shielding material itself becoming radioactive and hence more dangerous than if it were not present citation needed There are many types of shielding strategies that can be used to reduce the effects of radiation exposure Internal contamination protective equipment such as respirators are used to prevent internal deposition as a result of inhalation and ingestion of radioactive material Dermal protective equipment which protects against external contamination provides shielding to prevent radioactive material from being deposited on external structures 46 While these protective measures do provide a barrier from radioactive material deposition they do not shield from externally penetrating gamma radiation This leaves anyone exposed to penetrating gamma rays at high risk of ARS Naturally shielding the entire body from high energy gamma radiation is optimal but the required mass to provide adequate attenuation makes functional movement nearly impossible In the event of a radiation catastrophe medical and security personnel need mobile protection equipment in order to safely assist in containment evacuation and many other necessary public safety objectives Research has been done exploring the feasibility of partial body shielding a radiation protection strategy that provides adequate attenuation to only the most radio sensitive organs and tissues inside the body Irreversible stem cell damage in the bone marrow is the first life threatening effect of intense radiation exposure and therefore one of the most important bodily elements to protect Due to the regenerative property of hematopoietic stem cells it is only necessary to protect enough bone marrow to repopulate the exposed areas of the body with the shielded supply 47 This concept allows for the development of lightweight mobile radiation protection equipment which provides adequate protection deferring the onset of ARS to much higher exposure doses One example of such equipment is the 360 gamma a radiation protection belt that applies selective shielding to protect the bone marrow stored in the pelvic area as well as other radio sensitive organs in the abdominal region without hindering functional mobility Reduction of incorporation edit Where radioactive contamination is present an elastomeric respirator dust mask or good hygiene practices may offer protection depending on the nature of the contaminant Potassium iodide KI tablets can reduce the risk of cancer in some situations due to slower uptake of ambient radioiodine Although this does not protect any organ other than the thyroid gland their effectiveness is still highly dependent on the time of ingestion which would protect the gland for the duration of a twenty four hour period They do not prevent ARS as they provide no shielding from other environmental radionuclides 48 Fractionation of dose edit Main article Dose fractionation If an intentional dose is broken up into a number of smaller doses with time allowed for recovery between irradiations the same total dose causes less cell death Even without interruptions a reduction in dose rate below 0 1 Gy h also tends to reduce cell death 36 This technique is routinely used in radiotherapy citation needed The human body contains many types of cells and a human can be killed by the loss of a single type of cells in a vital organ For many short term radiation deaths 3 30 days the loss of two important types of cells that are constantly being regenerated causes death The loss of cells forming blood cells bone marrow and the cells in the digestive system microvilli which form part of the wall of the intestines is fatal citation needed Management edit nbsp Effect of medical care on acute radiation syndrome Treatment usually involves supportive care with possible symptomatic measures employed The former involves the possible use of antibiotics blood products colony stimulating factors and stem cell transplant 3 Antimicrobials edit Main article Treatment of infections after exposure to ionizing radiation There is a direct relationship between the degree of the neutropenia that emerges after exposure to radiation and the increased risk of developing infection Since there are no controlled studies of therapeutic intervention in humans most of the current recommendations are based on animal research citation needed The treatment of established or suspected infection following exposure to radiation characterized by neutropenia and fever is similar to the one used for other febrile neutropenic patients However important differences between the two conditions exist Individuals that develop neutropenia after exposure to radiation are also susceptible to irradiation damage in other tissues such as the gastrointestinal tract lungs and central nervous system These patients may require therapeutic interventions not needed in other types of neutropenic patients The response of irradiated animals to antimicrobial therapy can be unpredictable as was evident in experimental studies where metronidazole 49 and pefloxacin 50 therapies were detrimental Antimicrobials that reduce the number of the strict anaerobic component of the gut flora i e metronidazole generally should not be given because they may enhance systemic infection by aerobic or facultative bacteria thus facilitating mortality after irradiation 51 An empirical regimen of antimicrobials should be chosen based on the pattern of bacterial susceptibility and nosocomial infections in the affected area and medical center and the degree of neutropenia Broad spectrum empirical therapy see below for choices with high doses of one or more antibiotics should be initiated at the onset of fever These antimicrobials should be directed at the eradication of Gram negative aerobic bacilli i e Enterobacteriaceae Pseudomonas that account for more than three quarters of the isolates causing sepsis Because aerobic and facultative Gram positive bacteria mostly alpha hemolytic streptococci cause sepsis in about a quarter of the victims coverage for these organisms may also be needed 52 A standardized management plan for people with neutropenia and fever should be devised Empirical regimens contain antibiotics broadly active against Gram negative aerobic bacteria quinolones i e ciprofloxacin levofloxacin a third or fourth generation cephalosporin with pseudomonal coverage e g cefepime ceftazidime or an aminoglycoside i e gentamicin amikacin 53 Prognosis editSee also Radiation induced cancer The prognosis for ARS is dependent on the exposure dose with anything above 8 Gy being almost always lethal even with medical care 4 54 Radiation burns from lower level exposures usually manifest after 2 months while reactions from the burns occur months to years after radiation treatment 55 56 Complications from ARS include an increased risk of developing radiation induced cancer later in life According to the controversial but commonly applied linear no threshold model any exposure to ionizing radiation even at doses too low to produce any symptoms of radiation sickness can induce cancer due to cellular and genetic damage The probability of developing cancer is a linear function with respect to the effective radiation dose Radiation cancer may occur after ionizing radiation exposure following a latent period averaging 20 to 40 years 57 55 History editAcute effects of ionizing radiation were first observed when Wilhelm Rontgen intentionally subjected his fingers to X rays in 1895 He published his observations concerning the burns that developed that eventually healed and misattributed them to ozone Rontgen believed the free radical produced in air by X rays from the ozone was the cause but other free radicals produced within the body are now understood to be more important David Walsh first established the symptoms of radiation sickness in 1897 58 Ingestion of radioactive materials caused many radiation induced cancers in the 1930s but no one was exposed to high enough doses at high enough rates to bring on ARS The atomic bombings of Hiroshima and Nagasaki resulted in high acute doses of radiation to a large number of Japanese people allowing for greater insight into its symptoms and dangers Red Cross Hospital Surgeon Terufumi Sasaki led intensive research into the syndrome in the weeks and months following the Hiroshima and Nagasaki bombings Sasaki and his team were able to monitor the effects of radiation in patients of varying proximities to the blast itself leading to the establishment of three recorded stages of the syndrome Within 25 30 days of the explosion Sasaki noticed a sharp drop in white blood cell count and established this drop along with symptoms of fever as prognostic standards for ARS 59 Actress Midori Naka who was present during the atomic bombing of Hiroshima was the first incident of radiation poisoning to be extensively studied Her death on 24 August 1945 was the first death ever to be officially certified as a result of ARS or Atomic bomb disease There are two major databases that track radiation accidents The American ORISE REAC TS and the European IRSN ACCIRAD REAC TS shows 417 accidents occurring between 1944 and 2000 causing about 3000 cases of ARS of which 127 were fatal 60 ACCIRAD lists 580 accidents with 180 ARS fatalities for an almost identical period 61 The two deliberate bombings are not included in either database nor are any possible radiation induced cancers from low doses The detailed accounting is difficult because of confounding factors ARS may be accompanied by conventional injuries such as steam burns or may occur in someone with a pre existing condition undergoing radiotherapy There may be multiple causes for death and the contribution from radiation may be unclear Some documents may incorrectly refer to radiation induced cancers as radiation poisoning or may count all overexposed individuals as survivors without mentioning if they had any symptoms of ARS Notable cases edit The following table includes only those known for their attempted survival with ARS These cases exclude chronic radiation syndrome such as Albert Stevens in which radiation is exposed to a given subject over a long duration The table also necessarily excludes cases where the individual was exposed to so much radiation that death occurred before medical assistance or dose estimations could be made such as an attempted cobalt 60 thief who reportedly died 30 minutes after exposure 62 The result column represents the time of exposure to the time of death attributed to the short and long term effects attributed to initial exposure As ARS is measured by a whole body absorbed dose the exposure column only includes units of gray Gy Date Name Exposure Gy or Sv Incident accident Result August 21 1945 Harry Daghlian 3 1 Gy 19 Harry Daghlian criticality accident Death in 25 days May 21 1946 Louis Slotin 11 Gy 63 Slotin criticality accident Death in 9 days Alvin C Graves 1 9 Gy 19 Death in 19 years December 30 1958 Cecil Kelley 36 Gy 64 Cecil Kelley criticality accident Death in 38 hours July 24 1964 Robert Peabody 100 Gy 65 66 Robert Peabody criticality accident Death in 49 hours April 26 1986 Aleksandr Akimov 15 Gy 67 Chernobyl disaster Death in 14 days September 30 1999 Hisashi Ouchi 17 Sv 68 Tokaimura nuclear accident Death in 83 days December 2 2001 Patient 1 DN 3 6 Gy 69 Lia radiological accident Death in 893 daysOther animals editThousands of scientific experiments have been performed to study ARS in animals citation needed There is a simple guide for predicting survival and death in mammals including humans following the acute effects of inhaling radioactive particles 70 See also edit nbsp Nuclear technology portal 5 Androstenediol Biological effects of ionizing radiation Biological effects of radiation on the epigenome CBLB502 Ex Rad List of civilian nuclear accidents List of military nuclear accidents Nuclear terrorism Orders of magnitude radiation Prehydrated electrons Rongelap AtollReferences edit a b c d e f g h i j k l m n o A Fact Sheet for Physicians CDC CDC Radiation Emergencies Acute Radiation Syndrome 22 April 2019 Archived from the original on 18 May 2019 Retrieved 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Scientific Laboratory H l 78 Harold Catherine ed 2009 Professional guide to diseases 9th ed Philadelphia Lippincott Williams amp Wilkins ISBN 978 0 7817 7899 2 OCLC 475981026 McLaughlin Thomas P Monahan Shean P Pruvost Norman L Frolov Vladimir V Ryazanov Boris G Sviridov Victor I 2000 A Review of Criticality Accidents 2000 Revision PDF Los Alamos NM Los Alamos National Laboratory pp 33 34 Archived from the original PDF on 2009 09 11 Retrieved October 30 2023 United States Nuclear Regulatory Commission Division of Compliance Region I September 16 1964 UNC Recovery Sytems sic Compliance Investigation Report PDF Vol 3 Supplemental Report with Exhibits Archived PDF from the original on 2022 01 07 Retrieved October 30 2023 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Serhii Plokhii 2018 Chernobyl the history of a nuclear catastrophe Basic Books ISBN 978 1541617087 World s most radioactive man cried blood as his skin melted in 83 day nightmare TimesNow 29 March 2023 Retrieved 21 May 2023 The radiological accident in Lia Georgia PDF Vienna International Atomic Energy Agency 2014 ISBN 978 92 0 103614 8 OCLC 900016880 Wells J 1976 A guide to the prognosis for survival in mammals following the acute effects of inhaled radioactive particles Journal of the Institute of Nuclear Engineers 17 5 126 131 ISSN 0368 2595 This article incorporates public domain material from websites or documents of the U S Armed Forces Radiobiology Research Institute and the U S Centers for Disease Control and PreventionExternal links edit nbsp Wikimedia Commons has media related to Acute radiation syndrome Emergency preparedness and subject matter expertise on the medical management of radiation incidents U S Radiation Emergency Assistance Center Training Site REACts Archived from the original on 2023 05 05 Fact sheet on Acute Radiation Syndrome U S Centers for Disease Control and Prevention Archived from the original on 16 July 2006 Retrieved 22 July 2006 The criticality accident in Sarov PDF International Atomic Energy Agency 2001 A well documented account of the biological effects of a criticality accident Armed Forces Radiobiology Research Institute Archived from the original on 2015 03 03 Retrieved 2011 07 01 More information on bone marrow shielding can be found in the Health Physics Radiation Safety Journal article Waterman Gideon Kase Kenneth Orion Itzhak Broisman Andrey Milstein Oren September 2017 Selective Shielding of Bone Marrow An Approach to Protecting Humans from External Gamma Radiation Health Physics 113 3 195 208 doi 10 1097 HP 0000000000000688 PMID 28749810 S2CID 3300412 or in the Organisation for Economic Co operation and Development OECD and the Nuclear Energy Agency NEA s 2015 report Occupational Radiation Protection in Severe Accident Management Retrieved from https en wikipedia org w index php title Acute radiation syndrome amp oldid 1221068839, wikipedia, wiki, book, books, library,

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