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Risk factors for breast cancer

October 28, 2023

Risk factors for breast cancer may be divided into preventable and non-preventable. Their study belongs in the field of epidemiology. Breast cancer, like other forms of cancer, can result from multiple environmental and hereditary risk factors. The term "environmental", as used by cancer researchers, means any risk factor that is not genetically inherited.

For breast cancer, the list of environmental risk factors includes the individual person's development, exposure to microbes, "medical interventions, dietary exposures to nutrients, energy and toxicants, ionizing radiation, and chemicals from industrial and agricultural processes and from consumer products...reproductive choices, energy balance, adult weight gain, body fatness, voluntary and involuntary physical activity, medical care, exposure to tobacco smoke and alcohol, and occupational exposures, including shift work" as well as "metabolic and physiologic processes that modify the body's internal environment."[1] Some of these environmental factors are part of the physical environment, while others (such as diet and number of pregnancies) are primarily part of the social, cultural, or economic environment.[1]

Although many epidemiological risk factors have been identified, the cause of any individual breast cancer is most often unknowable. Epidemiological research informs the patterns of breast cancer incidence across certain populations, but not in a given individual. Approximately 5% of new breast cancers are attributable to hereditary syndromes, and well-established risk factors accounts for approximately 30% of cases.[2]

Age edit

 
Breast cancer incidence by age among women in the UK 2006–2008.[3]

The risk of getting breast cancer increases with age. A woman is more than 100 times more likely to develop breast cancer in her 60s than in her 20s.[4] If all women lived to age 95, about one in eight would be diagnosed with breast cancer at some point during their lives.[5] However, the actual lifetime risk is lower than that, because 90% of women die before age 95, most commonly from heart attacks, strokes, or other forms of cancer.[citation needed]

Though the probability of breast cancer increases with age, breast cancer tends to be more aggressive in younger people.[6]

Sex edit

Male individuals have a much lower risk of developing breast cancer than females. In developed countries, about 99% of breast cancer cases are diagnosed in female patients; in a few African countries, which represent the highest incidence of male breast cancer, males account for 5–15% of cases.[4] The rate of male breast cancer appears to be rising somewhat.[7]

Male breast cancer patients tend to be older than female ones.[4] They are more likely to be diagnosed with hormone-receptor positive tumors, with about six out of seven cases being estrogen-receptor positive.[4] The overall prognosis is worse for male than for female patients.[4]

Heredity edit

Further information: Cancer syndrome and Hereditary breast–ovarian cancer syndrome

United Kingdom being a member of the International Cancer Genome Consortium is leading efforts to map breast cancer's complete genome.

BRCA1 and BRCA2 edit

In 5% of breast cancer cases, there is a strong inherited familial risk.[8]

Two autosomal dominant genes, BRCA1 and BRCA2, account for most of the cases of familial breast cancer. Women who carry a harmful BRCA mutation have a 60% to 80% risk of developing breast cancer in their lifetimes.[8] Other associated malignancies include ovarian cancer and pancreatic cancer. If a mother or a sister was diagnosed breast cancer, the risk of a hereditary BRCA1 or BRCA2 gene mutation is about 2-fold higher than those women without a familial history. Commercial testing for BRCA1 and BRCA2 gene mutations has been available in most developed countries since at least 2004.

In addition to the BRCA genes associated with breast cancer, the presence of NBR2, near breast cancer gene 1, has been discovered, and research into its contribution to breast cancer pathogenesis is ongoing.[9]

Other genes edit

Hereditary non-BRCA1 and non-BRCA2 breast tumors (and even some sporadic carcinomas) are believed to result from the expression of weakly penetrant but highly prevalent mutations in various genes. For instance, polymorphism has been identified in genes associated to the metabolism of estrogens and/or carcinogens (Cytochrome P450, family 1, member A1, CYP1B1, CYP17A1, CYP19, Catechol-O-methyltransferase, N-acetyltransferase 2, Glutathione S-transferase Mu 1, GSTP1, GSTT, . . . ), to estrogen, androgen and vitamin D action (ESR1, AR, VDR), to co-activation of gene transcription (AIB1), to DNA damage response pathways (CHEK2, HRAS1, XRCC1, XRCC3, XRCC5).[10] Sequence variants of these genes that are relatively common in the population may be associated with a small to moderate increased relative risk for breast cancer. Combinations of such variants could lead to multiplicative effects. Sporadic cancers likely result from the complex interplay between the expression of low penetrance genes (risk variants) and environmental factors. However, the suspected impact of most of these variants on breast cancer risk should, in most cases, be confirmed in large populations studies. Indeed, low penetrance genes cannot be easily tracked through families, as is true for dominant high-risk genes.[10]

Part of the hereditary non-BRCA1 and non-BRCA2 breast tumors may be associated to rare syndromes, of which breast cancer is only one component. Such syndromes result notably from mutations in TP53 (Li–Fraumeni syndrome), ATM (ataxia–telangiectasia), STK11/LKB1(Peutz–Jeghers syndrome), PTEN (Cowden syndrome).

RAB11FIP1,[11] TP53, PTEN and rs4973768 are also associated with increased risk of breast cancer. rs6504950 is associated with lower risk of breast cancer.[12]

Mutations in RAD51C confer an increased risk for breast and ovarian cancer.[13]

Prior cancers edit

People who have previously been diagnosed with breast, ovarian, uterine, or bowel cancer have a higher risk of developing breast cancer in the future.[4] Mothers of children with soft-tissue sarcoma may have an increased risk of breast cancer.[4]

Dietary factors edit

The Western dietary pattern is associated with an increased risk of breast cancer.[14][15]

Alcohol edit

Main article: Alcohol and breast cancer

There is strong evidence that alcohol consumption increases risk of breast cancer.[16][17][18][19][20]

Calcium edit

Several reviews have found a weak inverse association between dietary calcium intake and breast cancer risk.[21][22] The World Cancer Research Fund International and American Institute for Cancer Research have stated that there is limited evidence that diets high in calcium might decrease the risk of breast cancer.[17][23]

Fruits and vegetables edit

High total dietary fiber consumption and total fruit and vegetable consumption is associated with a reduced risk of breast cancer.[24][25]

Meat edit

High total processed meat and red meat consumption are associated with increased breast cancer risk.[14][26][27]

Saturated fat edit

Several reviews of case–control studies have found that saturated fat intake is associated with increased breast cancer risk.[14][28][29]

Polycyclic Aromatic Hydrocarbons edit

Main article: Polycyclic aromatic hydrocarbon §  Human health

Polycyclic aromatic hydrocarbons (PAHs) are a known human carcinogens due to their mutagenic ability to damage DNA which causes cancer. A 2016 study found that sources of PAHs such as grilled and smoked meats (along with other sources such as cigarette smoking and indoor air pollution) were associated with 30–50% increase in breast cancer incidence.[30] High risk individuals were those who were active smokers, consumed greater than 55 servings of grilled/smoked meats a year, frequently used indoor fire places, and were exposed to large amounts of traffic pollution.[30] The study was a population-based case-control study conducted on Long island, New York (N=1,508 breast cancer cases/1,556 controls). The authors concluded that while PAHs are ubiquitous, breast cancer risk factors could be modified by dietary and lifestyle changes.

Obesity and Lack of Exercise edit

Gaining weight after menopause can increase a woman's risk. A 2006 study found that putting on 9.9 kg (22 lbs) after menopause increased the risk of developing breast cancer by 18%.[31] Lack of exercise has been linked to breast cancer by the American Institute for Cancer Research.[32]

Obesity has been linked to an increased risk of developing breast cancer by many scientific studies.[33] There is evidence to suggest that excess body fat at the time of breast cancer diagnosis is associated with higher rates of cancer recurrence and death.[33] Furthermore, studies have shown that obese women are more likely to have large tumors, greater lymph node involvement, and poorer breast cancer prognosis with 30% higher risk of mortality.[34]

Weight gain after diagnosis has also been linked to higher rates of breast cancer recurrence or mortality although this finding is not consistent.[33] Weight gain is often less severe with newer chemotherapy treatments but one study found a significant risk of breast cancer mortality in women who gained weight compared to those who maintained their weight.[35] However, other cohort studies and recent clinical trials have not shown a significant relationship between weight gain after diagnosis and breast cancer mortality.[33][36]

Weight loss after diagnosis has not been shown to decrease the risk of breast cancer recurrence or mortality.[33] However, physical activity after breast cancer diagnosis has shown some associations with reducing breast cancer recurrence and mortality independent of weight loss.[37] Data for both weight loss and physical activity and the effect on breast cancer prognosis is still lacking.[33]

There is debate as to whether the higher rate of breast cancer associated with obesity is due to a biological difference in the cancer itself, or differences in other factors such as health screen practices.[38] It has been suggested that obesity may be a determinant for breast cancer screening by mammography. Seventeen scientific studies in the United States have found that as obesity increases in women over 40 years of age the rate of mammography reported decreases significantly.[39] When stratified by race (white vs. black) there was a stronger relationship between obesity and lack of mammography screening among white women.[39] Another study also found lower rates of mammography among those who were overweight and obese compared to those women who were of normal body mass index—this effect was only seen in white women.[40] Obese women are more likely to list pain associated with mammograms as a reason for not getting screened; however, leaner women also list this as a reason for avoiding mammograms.[41] Other reasons obese women may avoid mammography are due to lack of insurance, low income, or embarrassment at the procedure, although when these factors are accounted for, the effect of lower rates of screening are still significant.[41] In contrast, other studies have shown that mammography patterns did not differ among women who were obese compared to those at a healthy weight indicating that there may be biological differences in cancer presentation between these groups.[42]

Hormones edit

Persistently increased blood levels of estrogen are associated with an increased risk of breast cancer, as are increased levels of the androgens androstenedione and testosterone (which can be directly converted by aromatase to the estrogens estrone and estradiol, respectively). Increased blood levels of progesterone are associated with a decreased risk of breast cancer in premenopausal women.[43] A number of circumstances which increase exposure to endogenous estrogens including not having children, delaying first childbirth, not breastfeeding, early menarche (the first menstrual period) and late menopause are suspected of increasing lifetime risk for developing breast cancer.[44]

However, not only sex hormones, but also insulin levels are positively associated with the risk of breast cancer.[45]

Pregnancy, childbearing and breastfeeding edit

Lower age of first childbirth, compared to the average age of 24,[46] having more children (about 7% lowered risk per child), and breastfeeding (4.3% per breastfeeding year, with an average relative risk around 0.7[47][48]) have all been correlated to lowered breast cancer risk in premenopausal women, but not postmenopausal women, in large studies.[49] Women who give birth and breast-feed by the age of 20 may have even greater protection.[50] In contrast, for instance, having the first live birth after age 30 doubles the risk compared to having first live birth at age less than 25.[51] Never having children triples the risk.[51] The studies have found that these risk factors become less material as a woman reaches menopause, i.e. that they affect risk of breast cancer prior to menopause but not after it. In balancing premenopausal reductions in risk from childbirth and lactation, it is important also to consider the risks involved in having a child.

Hormonal contraception edit

Hormonal contraceptives may produce a slight increase in the risk of breast cancer diagnosis among current and recent users, but this appears to be a short-term effect. In 1996 the largest collaborative reanalysis of individual data on over 150,000 women in 54 studies of breast cancer found a relative risk (RR) of 1.24 of breast cancer diagnosis among current combined oral contraceptive pill users; 10 or more years after stopping, no difference was seen. Further, the cancers diagnosed in women who had ever used hormonal contraceptives were less advanced than those in nonusers, raising the possibility that the small excess among users was due to increased detection.[52][53] The relative risk of breast cancer diagnosis associated with current and recent use of hormonal contraceptives did not appear to vary with family history of breast cancer.[54] Some studies have suggested that women who began using hormonal contraceptives before the age of 20 or before their first full-term pregnancy are at increased risk for breast cancer, but it is not clear how much of the risk stems from early age at first use, and how much stems from use before the first full-term pregnancy.[55]

Hormone replacement therapy edit

Data exist from both observational and randomized clinical trials regarding the association between menopausal hormone replacement therapy (menopausal HRT) and breast cancer. The largest meta-analysis (1997) of data from 51 observational studies, indicated a relative risk of breast cancer of 1.35 for women who had used HRT for 5 or more years after menopause.[56] The estrogen-plus-progestin arm of the Women's Health Initiative (WHI), a randomized controlled trial, which randomized more than 16,000 postmenopausal women to receive combined hormone therapy or placebo, was halted early (2002) because health risks exceeded benefits. One of the adverse outcomes prompting closure was a significant increase in both total and invasive breast cancers (hazard ratio = 1.24) in women randomized to receive estrogen and progestin for an average of 5 years.[57] HRT-related breast cancers had adverse prognostic characteristics (more advanced stages and larger tumors) compared with cancers occurring in the placebo group, and HRT was also associated with a substantial increase in abnormal mammograms. Short-term use of hormones for treatment of menopausal symptoms appears to confer little or no breast cancer risk.[54] A correlation was found between the use of hormonal contraceptives and subsequent reliance on hormone replacement therapy.[55]

Oophorectomy and mastectomy edit

Main article: BRCA mutation

Prophylactic oophorectomy (removal of ovaries) and mastectomy in individuals with high-risk mutations of BRCA1 or BRCA2 genes reduces the risk of developing breast cancer as well as reducing the risk of developing ovarian cancer. Because of a complex balance of benefits and risks of a prophylactic surgery it is recommended only in very specific cases.

Hormonal therapy edit

Main article: Hormonal therapy (oncology)

Hormonal therapy has been used for chemoprevention in individuals at high risk for breast cancer. Overall it is recommended only in very special circumstances. In 2002, a clinical practice guideline by the US Preventive Services Task Force (USPSTF) recommended that "clinicians discuss chemoprevention with women at high risk for breast cancer and at low risk for adverse effects of chemoprevention" with a grade B recommendation.[58][verification needed][59][60]

Selective estrogen receptor modulators (SERMs) edit

The guidelines[clarification needed] were based on studies of SERMs from the MORE, BCPT P-1, and Italian trials. In the MORE trial, the relative risk reduction for raloxifene was 76%.[61] The P-1 preventative study demonstrated that tamoxifen can prevent breast cancer in high-risk individuals. The relative risk reduction was up to 50% of new breast cancers, though the cancers prevented were more likely estrogen-receptor positive (this is analogous to the effect of finasteride on the prevention of prostate cancer, in which only low-grade prostate cancers were prevented).[62][63] The Italian trial showed benefit from tamoxifen.[64]

Additional randomized controlled trials have been published since the guidelines. The IBIS trial found benefit from tamoxifen.[65] In 2006, the NSABP STAR trial demonstrated that raloxifene had equal efficacy in preventing breast cancer compared with tamoxifen, but that there were fewer side effects with raloxifene.[66] The RUTH Trial concluded that "benefits of raloxifene in reducing the risks of invasive breast cancer and vertebral fracture should be weighed against the increased risks of venous thromboembolism and fatal stroke".[67] On September 14, 2007, the US Food and Drug Administration approved raloxifene (Evista) to prevent invasive breast cancer in postmenopausal women.[68]

Endocrine disruptors edit

Many xenoestrogens (industrially made estrogenic compounds) and other endocrine disruptors are potential risk factors of breast cancer.

Diethylstilbestrol (DES) is a synthetic form of estrogen. It has been used between the early 1940s and 1971. Pregnant women took DES to prevent certain pregnancy complications. However, it also increased their risk of breast cancer. It also increased the risk of breast cancer in the prenatally exposed daughters after they have reached an age 40 years.[69]

Factors in the physical environment edit

According to a review, the main mechanisms by which environmental compounds increase breast cancer risk are acting like hormones, especially estrogen, or affecting susceptibility to carcinogenesis.[70] The evidence to date generally supports an association between breast cancer and polycyclic aromatic hydrocarbons (PAHs) and polychlorinated biphenyls (PCBs). Dioxins and organic solvents, on the other hand, have only shown an association in sparse and methodologically limited studies, but are suggestive of an association.[70] Overall, however, evidence is still based on a relatively small number of studies.[70]

Xenoestrogens edit

Main article: Xenoestrogens

Many xenoestrogens (industrially made estrogenic compounds) are endocrine disruptors, and potential risk factors of breast cancer. Endocrine disruption is the hypothesis that some chemicals in the body, such as Bisphenol A, are capable of interfering with the production, processing, and transmission of hormones.[71]

A substantial and growing body of evidence indicates that exposures to certain toxic chemicals and hormone-mimicking compounds including chemicals used in pesticides, cosmetics and cleaning products contribute to the development of breast cancer.

The increasing prevalence of these substances in the environment may explain the increasing incidence of breast cancer, though direct evidence is sparse.

Bisphenol A edit

Main article: Bisphenol A
 
Exposure to bisphenol A causes breast cancer.[72]

Bisphenol A (BPA) is a chemical compound used in the production of plastics found in numerous commercial products, including laptops, baby bottles, food containers, water main pipes, and laboratory and hospital equipment. BPA was first produced in 1891, but its estrogenic properties went undiscovered until the mid-1930s. Today it is considered a xenoestrogen, and it functions as an endocrine disruptor that interferes with hormones in the body and disrupts the normal functioning of the endocrine system. At very low levels the FDA has long considered BPA in food to be safe, but this has been challenged over the years as more information is discovered regarding the effects of the chemical.[73]

Rats exposed prenatally to environmentally relevant doses of BPA show an increased number of intraductal hyperplasias (precancerous lesions) in mammary glands that appear during adulthood, while high doses induce the development of carcinomas in breast tissue. Animals exposed to BPA during fetal life develop palpable tumors, and all studies show an increased susceptibility to mammary gland neoplasia that manifests during adulthood. Exposure of mouse dams to environmentally relevant levels of BPA during organogenesis results in considerable alterations in the mammary gland. It was concluded that perinatal exposure to low doses of BPA results in altered mammary gland morphogenesis, induction of precancerous lesions, and carcinoma in situ.[72]

A study sought to determine whether early exposure to BPA could accelerate mammary carcinogenesis in a dimethylbenzanthracene (DMBA) model of rodent mammary cancer. In the study, scientists exposed neonatal/prebubertal rats to BPA via lactation from nursing dams treated orally with 0, 25, and 250 µg BPA/kg body weight/day. For tumorigenesis studies, female offspring were exposed to 30 mg DMBA/kg body weight at 50 days of age. DMBA induces mammary tumors and allows chemicals that predispose for mammary cancer to increase the number of mammary adenocarcinomas. The results of the study showed that female rats in the control, BPA 25, and BPA 250 groups administered DMBA exhibited a BPA dose-dependent increase in mammary tumors. The groups had 2.84, 3.82, and 5.00 mammary tumors per rat respectively. Treatment with BPA also reduced tumor latency, with the median tumor latency of 65, 53, and 56.5 days for 0, BPA 25, and BPA 250 groups respectively. Maternal exposure to BPA during lactation decreased time to first tumor latency and increased the number of DMBA-induced mammary tumors in female offspring. If these effects found in rodents carry over to humans, even minimal exposure to BPA could cause an increased risk for breast cancer.[74]

The elevated incidence of breast cancer in women has been associated with prolonged exposure to high levels of estrogens. Xenoestrogens, such as BPA have the capacity to perturb normal hormonal actions. This study provides evidence of the estrogenic effects of BPA. In this study the human breast epithelial cells MCF-10F were treated with 10-3 M, 10-4 M, 10-5 M and 10-6 M BPA continuously for two weeks. The cells treated with 10-3 M BPA died on the second day of treatment. The concentration of 10-4 M BPA was also toxic for the breast epithelial cells, and they died on the fourth day of treatment. This data indicated that these concentrations of BPA are toxic for MCF-10F cells. After the two-week observation period it was seen that the cells formed a high percentage of duct like structures in collagen. MCF-10F cells treated with 10-5 M and 10-6 M BPA formed a high percentage of solid masses, 27% and 20% respectively. This data indicates that BPA is able to induce neoplastic transformation of human breast epithelial cells. Epigenetic changes are involved in the early stages of cancer initiation by altering ductulogenesis. BPA was able to induce transformation of human breast MCF-10F epithelial cells. After treatment with BPA, the cells produced fewer collagen tubules and more solid masses.[75]

Consumer groups recommend that people wishing to lower their exposure to bisphenol A avoid canned food and polycarbonate plastic containers (which shares resin identification code 7 with many other plastics) unless the packaging indicates the plastic is bisphenol A-free.[76] The National Toxicology Panel recommends avoiding microwaving food in plastic containers, putting plastics in the dishwasher, or using harsh detergents on plastics, to avoid leaching.[77]

Aromatic Amines edit

Aromatic amines are chemicals that are produced when products such as dyes, polyurethane products, and certain pesticides are made. They are also found in cigarette smoke, fuel exhaust, and in over cooked, burned meat. The three types of aromatic amines monocyclic, polycyclic, and heterocyclic have all been found in recent studies of breast health. Monocyclic amines have been found to cause mammary cancer in rats. Studies have shown that women who eat higher amounts of overcooked meat, meaning more exposure to heterocyclic amines, have also been diagnosed with more post-menopausal breast cancer. Heterocyclic amines also have the ability to copy estrogen and in laboratory studies have been found to encourage the growth of cancerous tumors on human tissue.[78]

Benzene edit

 
Multiple studies point to a correlation between benzene exposure and breast cancer risk.[78]

Benzene is a petrochemical solvent. Benzene exposure mostly originates from air pollution resulting from industrial burning, exhaust and gas fumes, as well as cigarette smoke. Petroleum, its distillates such as gasoline, auto and truck exhausts also contain benzene. The International Agency for Research on Cancer and the National Toxicology Program have labeled benzene as a definite human carcinogen. Multiple studies point to a correlation between benzene exposure and breast cancer risk. Laboratory studies on mice have shown that a high level of benzene exposure can lead to mammary cancer.[78]

DDT edit

Main article: DDT § Breast cancer

Although the pesticide DDT was banned over 20 years ago, studies have shown that there are still trace amounts found in certain agricultural products, as well as in human and animal milk.[79] While individual studies have come to conflicting conclusions, the most recent reviews of all the evidence conclude that exposure to DDT before puberty increases the risk of breast cancer later in life.[80][81]

Ethylene oxide edit

Ethylene oxide is a chemical that can be found in some personal care products, mainly in the form of fragrance. It is also used for the sterilization of various medical objects. The National Toxicology Program has labeled ethylene oxide as a definite human and animal carcinogen. A study done by the National Institute for Occupational Safety and Health including 7,576 women found a direct correlation between breast cancer rates and exposure to ethylene oxide during medical sterilization processes. Also, human breast cells put into contact with small amounts of ethylene oxide in a laboratory can lead to DNA damage of the breast tissue.[78]

Polycyclic aromatic hydrocarbons edit

Polycyclic aromatic hydrocarbons are chemical products of combustion from coal burners, fuel, cigarette smoke, and various other sources. PAH's are often found in the air and are breathed into the body. PAH's bioaccumulate easily and can copy the estrogen hormone. PAH's can also be genotoxic, meaning they have the ability to harm DNA.[78]

Vinyl chloride edit

Vinyl chloride is produced when PVC or polyvinyl chloride is made. PVC is found in plastic packaging, outerwear, plastic toys and other plastic products. Vinyl chloride can be found in cigarette smoke and the air around garbage and land fills. It can also be found in the wastewater when PVC is made. The National Toxicology Program and the International Agency for Research on Cancer have both labeled vinyl chloride as a definite human carcinogen.[78]

Tobacco edit

See also: Women and smoking § Unique gender differences and health effects for Females

Until recently, most studies had not found an increased risk of breast cancer from active tobacco smoking. Beginning in the mid-1990s, a number of studies suggested an increased risk of breast cancer in both active smokers and those exposed to secondhand smoke compared to women who reported no exposure to secondhand smoke.[82] By 2005 enough evidence had accumulated for the [California Environmental Protection Agency] to conclude that breathing secondhand smoke causes breast cancer in younger, primarily premenopausal women.[83] The Agency concluded that the risk was increased by 70%, based on epidemiological studies and the fact that there are many mammary carcinogens in secondhand smoke. The following year (2006) the US Surgeon General[84] identified the same risk increase and concluded that the evidence is "suggestive," one step below causal. There is some evidence that exposure to tobacco smoke is most problematic between puberty and first childbirth. The reason is that breast tissue appears most sensitive to chemical carcinogens breast cells not fully differentiated until lactation.[85] The likely reason that the older studies of active smoking did not detect risks associated with smoking was that they compared active smokers to all nonsmokers (which includes many passive smokers). The newer studies, which exclude passive smokers from the control group, generally show elevated risks associated with active as well as passive smoking.

Passive smoking edit

Breathing secondhand smoke increases breast cancer risk by 70% in younger, primarily pre-menopausal women. The California Environmental Protection Agency has concluded that passive smoking causes breast cancer[83] and the US Surgeon General[84] has concluded that the evidence is suggestive, one step below causal. There is some evidence that exposure to tobacco smoke is most problematic between puberty and first childbirth. The reason that breast tissue appears most sensitive to chemical carcinogens in this phase is that breast cells are not fully differentiated until lactation.[85]

Radiation edit

Women who have received high-dose ionizing radiation to the chest (for example, as treatments for other cancers) have a relative risk of breast cancer between 2.1 and 4.0.[82] The risk increases with increased dose. In addition, the risk is higher in women irradiated before age 30, when there is still breast development.[51]

Dioxins edit

Dioxins (most notably the polychlorinated dibenzodioxins) are chemicals that are produced when chlorinated products are burned, such as polyvinyl chloride (PVC). This occurs when chlorinated products are used in certain manufacturing industries. Dioxins are also added to the air when gasoline and diesel fuels break down. Dioxins are able to bioaccumulate, meaning that they settle and stay in human and animal fat for long periods of time. There are many different types of dioxins and only a few of them have been labeled by the Environmental Protection Agency as definite human carcinogens and endocrine hormone disruptors. Although dioxins are floating in the air, they eventually settle on plants and other vegetation surfaces. These plants and vegetation are them eaten by cows and other animals. Humans end up eating the produce, milk, eggs, and meat produced by these animals that have consumed dioxin covered vegetation. Dioxins are more harmful when ingested this way. Multiple studies have led to the idea that increased dioxin levels can increase one's risk for breast cancer. A study done in 1976 after a chemical plant explosion in Seveso, Italy concluded that high dioxin level exposure in a woman's body correlated with a more than double chance of developing breast cancer.[78]

Light at night and disturbance of circadian rhythm edit

In 1978 Cohen et al. proposed that reduced production of the hormone melatonin might increase the risk of breast cancer and citing "environmental lighting" as a possible causal factor.[86] Researchers at the National Cancer Institute (NCI) and National Institute of Environmental Health Sciences conducted a study in 2005 that suggests that artificial light during the night can be a factor for breast cancer by disrupting melatonin levels.[87] According to a research in 2008, a reduced melatonin level in postmenopausal women is linked to a higher risk of breast cancer.[88]

In 2007, "shiftwork that involves circadian disruption" was listed as a probable carcinogen by the World Health Organization's International Agency for Research on Cancer. (IARC Press release No. 180).[89] Multiple studies have documented a link between night shift work and the increased incidence of breast cancer.[90][91][92][93] A review of current knowledge of the health consequences of exposure to artificial light at night including the increased incidence of breast cancer and an explanation of the causal mechanisms has been published in the Journal of Pineal Research in 2007.[94]

Tonsillectomy edit

A systematic review and meta-analysis of eight studies revealed an association of prior tonsillectomy and risk of breast cancer in females.[95]

Ethnicity-related and socioeconomic factors edit

Incidence and mortality vary with ethnic background and social status. Incidence rises with improving economic situation, while mortality is tied to low economic status. In the US incidence is significantly lower and mortality higher among black women and this difference appears to persist even after adjustment for economic status. It is currently unclear if significant ethnic differences in incidence and mortality persist after adjustment for economic status between women of white, Hispanic and Asian origin in the US.[96]

Several studies have found that black women in the U.S. are more likely to die from breast cancer even though white women are more likely to be diagnosed with the disease. Even after diagnosis, black women are less likely to get treatment compared to white women.[97][98][99] Scholars have advanced several theories for the disparities, including inadequate access to screening, reduced availability of the most advanced surgical and medical techniques, or some biological characteristic of the disease in the African American population.[100] Some studies suggest that the racial disparity in breast cancer outcomes may reflect cultural biases more than biological disease differences.[101] However, the lack of diversity in clinical trials for breast cancer treatment may contribute to these disparities, with recent research indicating that black women are more likely to have estrogen receptor negative breast cancers, which are not responsive to hormone treatments that are effective for most white women.[102] Research is currently ongoing to define the contribution of both biological and cultural factors.[98][103]

Part of the differences in incidence that is attributable to race and economic status may be explained by past use of hormone replacement therapy[104]

Factors with inconclusive research edit

1,3-Butadiene edit

1,3-Butadiene is an environmental factor that can be found in air pollution and can be produced by combustion engines, as well as petroleum refineries. It is found in cigarette smoke and is also used in the making and processing of certain synthetic rubber products and fungicides. The National Toxicology Program has labeled 1,3-Butadiene as definite human carcinogen. The EPA has stated that people are mainly put in contact with this chemical through the means of simple inhalation.[78]

Mammographic density edit

Mammographic density refers to the relative proportions of radiodense area compared to the radiolucent area on a mammogram, which is basically an x-ray of the breast. The radiodense area on a mammogram is white and is associated with ductal and lobular epithelium, connective tissue and fluid in the breast. The radiolucent area is dark gray or black and is associated with fat in the breast. High mammographic density is associated with a higher risk of developing breast cancer, but the reasons for this link are not certain and are being studied.[105][106] Conversely, patients with very low mammographic breast density were found to hold a poorer prognosis irrespective of age, BMI and menopausal status.[107]

Red No. 3 edit

Red No. 3 is a coloring agent used in some foods. In laboratory tests human breast cell DNA was found positive for damage when put into contact with Red No. 3, which means that it is genotoxic.[108]

Viruses edit

Several kinds of viruses with oncogenic potential are suspected to play a role or cause breast cancer. Among the three most commonly studied are the human papilloma virus (HPV),[109] mouse mammary tumour virus[110](MMTV) and the Epstein-Barr virus (EBV).[110] A study published in 2011, reviewing 85 original molecular research investigations on the presence of one or more of these three viruses found that only seven of the studies convincingly demonstrated the presence of an oncogenic virus biomarker, while twenty-five of the studies were able to show the absence of the virus studied, and the remaining studies were excluded due to shortcomings. Thus, the data from these investigations do not justify a conclusion as to whether HPV, MMTV, or EBV play a causal role in human breast cancer development.[111]

Humans are not the only mammals susceptible to breast cancer. Some strains of mice, namely the house mouse (Mus domesticus) are prone to breast cancer which is caused by infection with the mouse mammary tumour virus (MMTV or "Bittner virus" for its discoverer John Joseph Bittner), by random insertional mutagenesis. It is the only animal breast cancer with a known etiology.[111] These findings are taken to mean that a viral origin of human breast cancer is at least possible, though there is no definitive evidence to support the claim that MMTV causes human breast cancer. For example, there may be critical differences between cancer pathogenesis in mice and people. A human homologue of the mammary virus has been described in 1971 and linked to human breast cancer in several small epidemiologic studies.[112][113]

Factors with minimal or no impact edit

There is no significant association between first-trimester abortion and breast cancer risk.[114] There is no scientific evidence to prove that any kind of brassiere can cause cancer.[115][116] The myth that breast cancer is linked with deodorant use has been widely circulated, and appears to originate from a spam email sent in 1999.[117] There is however no evidence to support the existence of such a link.[118] There is no persuasive connection between fertility medications and breast cancer.[119]

History edit

In past centuries, the development of breast cancer was most commonly seen as divine punishment or a trial. From ancient Greek medicine until the end of the 17th century, the dominant medical explanation was an imbalance of the four humors.[120] By the start of the 18th century, humoralism had generally been rejected. Many other theories were put forward, often related to sexual activity: In 1713, Bernardino Ramazzini said that nuns developed breast cancer at a higher rate than married women because they did not engage in sexual intercourse, and the "unnatural" lack of sexual activity caused instability of the breasts; others countered that the cause was frequently too much sexual activity.[121] Other theories from the 18th century included various sorts of problems with the movement of body fluids, such as lymphatic blockages, curdled breast milk or the transformation of pus left after an infection.[121]

In modern times, women are more likely to blame themselves, perhaps deciding that their diet, childbearing history, decision not to breastfeed, or level of exercise is the cause.[120]

See also edit

References edit

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External links edit

  • Breast Cancer Myths and Facts
  • Breast cancer at Curlie
  • GeneReviews/NCBI/NIH/UW entry on BRCA1 and BRCA2 Hereditary Breast/Ovarian Cancer
  • Breast cancer database at Silent Spring Institute
  • Risk factors for breast cancer at Curlie

October 28, 2023
risk, factors, breast, cancer, this, article, needs, more, reliable, medical, references, verification, relies, heavily, primary, sources, please, review, contents, article, appropriate, references, unsourced, poorly, sourced, material, challenged, removed, fi. This article needs more reliable medical references for verification or relies too heavily on primary sources Please review the contents of the article and add the appropriate references if you can Unsourced or poorly sourced material may be challenged and removed Find sources Risk factors for breast cancer news newspapers books scholar JSTOR November 2016 Risk factors for breast cancer may be divided into preventable and non preventable Their study belongs in the field of epidemiology Breast cancer like other forms of cancer can result from multiple environmental and hereditary risk factors The term environmental as used by cancer researchers means any risk factor that is not genetically inherited For breast cancer the list of environmental risk factors includes the individual person s development exposure to microbes medical interventions dietary exposures to nutrients energy and toxicants ionizing radiation and chemicals from industrial and agricultural processes and from consumer products reproductive choices energy balance adult weight gain body fatness voluntary and involuntary physical activity medical care exposure to tobacco smoke and alcohol and occupational exposures including shift work as well as metabolic and physiologic processes that modify the body s internal environment 1 Some of these environmental factors are part of the physical environment while others such as diet and number of pregnancies are primarily part of the social cultural or economic environment 1 Although many epidemiological risk factors have been identified the cause of any individual breast cancer is most often unknowable Epidemiological research informs the patterns of breast cancer incidence across certain populations but not in a given individual Approximately 5 of new breast cancers are attributable to hereditary syndromes and well established risk factors accounts for approximately 30 of cases 2 Contents 1 Age 2 Sex 3 Heredity 3 1 BRCA1 and BRCA2 3 2 Other genes 4 Prior cancers 5 Dietary factors 5 1 Alcohol 5 2 Calcium 5 3 Fruits and vegetables 5 4 Meat 5 5 Saturated fat 5 6 Polycyclic Aromatic Hydrocarbons 6 Obesity and Lack of Exercise 7 Hormones 7 1 Pregnancy childbearing and breastfeeding 7 2 Hormonal contraception 7 3 Hormone replacement therapy 7 4 Oophorectomy and mastectomy 7 5 Hormonal therapy 7 5 1 Selective estrogen receptor modulators SERMs 7 6 Endocrine disruptors 8 Factors in the physical environment 8 1 Xenoestrogens 8 1 1 Bisphenol A 8 2 Aromatic Amines 8 3 Benzene 8 4 DDT 8 5 Ethylene oxide 8 6 Polycyclic aromatic hydrocarbons 8 7 Vinyl chloride 8 8 Tobacco 8 8 1 Passive smoking 8 9 Radiation 8 10 Dioxins 8 11 Light at night and disturbance of circadian rhythm 9 Tonsillectomy 10 Ethnicity related and socioeconomic factors 11 Factors with inconclusive research 11 1 1 3 Butadiene 11 2 Mammographic density 11 3 Red No 3 11 4 Viruses 12 Factors with minimal or no impact 13 History 14 See also 15 References 16 External linksAge edit nbsp Breast cancer incidence by age among women in the UK 2006 2008 3 The risk of getting breast cancer increases with age A woman is more than 100 times more likely to develop breast cancer in her 60s than in her 20s 4 If all women lived to age 95 about one in eight would be diagnosed with breast cancer at some point during their lives 5 However the actual lifetime risk is lower than that because 90 of women die before age 95 most commonly from heart attacks strokes or other forms of cancer citation needed Though the probability of breast cancer increases with age breast cancer tends to be more aggressive in younger people 6 Sex editMale individuals have a much lower risk of developing breast cancer than females In developed countries about 99 of breast cancer cases are diagnosed in female patients in a few African countries which represent the highest incidence of male breast cancer males account for 5 15 of cases 4 The rate of male breast cancer appears to be rising somewhat 7 Male breast cancer patients tend to be older than female ones 4 They are more likely to be diagnosed with hormone receptor positive tumors with about six out of seven cases being estrogen receptor positive 4 The overall prognosis is worse for male than for female patients 4 Heredity editFurther information Cancer syndrome and Hereditary breast ovarian cancer syndrome United Kingdom being a member of the International Cancer Genome Consortium is leading efforts to map breast cancer s complete genome BRCA1 and BRCA2 edit In 5 of breast cancer cases there is a strong inherited familial risk 8 Two autosomal dominant genes BRCA1 and BRCA2 account for most of the cases of familial breast cancer Women who carry a harmful BRCA mutation have a 60 to 80 risk of developing breast cancer in their lifetimes 8 Other associated malignancies include ovarian cancer and pancreatic cancer If a mother or a sister was diagnosed breast cancer the risk of a hereditary BRCA1 or BRCA2 gene mutation is about 2 fold higher than those women without a familial history Commercial testing for BRCA1 and BRCA2 gene mutations has been available in most developed countries since at least 2004 In addition to the BRCA genes associated with breast cancer the presence of NBR2 near breast cancer gene 1 has been discovered and research into its contribution to breast cancer pathogenesis is ongoing 9 Other genes edit Hereditary non BRCA1 and non BRCA2 breast tumors and even some sporadic carcinomas are believed to result from the expression of weakly penetrant but highly prevalent mutations in various genes For instance polymorphism has been identified in genes associated to the metabolism of estrogens and or carcinogens Cytochrome P450 family 1 member A1 CYP1B1 CYP17A1 CYP19 Catechol O methyltransferase N acetyltransferase 2 Glutathione S transferase Mu 1 GSTP1 GSTT to estrogen androgen and vitamin D action ESR1 AR VDR to co activation of gene transcription AIB1 to DNA damage response pathways CHEK2 HRAS1 XRCC1 XRCC3 XRCC5 10 Sequence variants of these genes that are relatively common in the population may be associated with a small to moderate increased relative risk for breast cancer Combinations of such variants could lead to multiplicative effects Sporadic cancers likely result from the complex interplay between the expression of low penetrance genes risk variants and environmental factors However the suspected impact of most of these variants on breast cancer risk should in most cases be confirmed in large populations studies Indeed low penetrance genes cannot be easily tracked through families as is true for dominant high risk genes 10 Part of the hereditary non BRCA1 and non BRCA2 breast tumors may be associated to rare syndromes of which breast cancer is only one component Such syndromes result notably from mutations in TP53 Li Fraumeni syndrome ATM ataxia telangiectasia STK11 LKB1 Peutz Jeghers syndrome PTEN Cowden syndrome RAB11FIP1 11 TP53 PTEN and rs4973768 are also associated with increased risk of breast cancer rs6504950 is associated with lower risk of breast cancer 12 Mutations in RAD51C confer an increased risk for breast and ovarian cancer 13 Prior cancers editPeople who have previously been diagnosed with breast ovarian uterine or bowel cancer have a higher risk of developing breast cancer in the future 4 Mothers of children with soft tissue sarcoma may have an increased risk of breast cancer 4 Dietary factors editThe Western dietary pattern is associated with an increased risk of breast cancer 14 15 Alcohol edit Main article Alcohol and breast cancer There is strong evidence that alcohol consumption increases risk of breast cancer 16 17 18 19 20 Calcium edit Several reviews have found a weak inverse association between dietary calcium intake and breast cancer risk 21 22 The World Cancer Research Fund International and American Institute for Cancer Research have stated that there is limited evidence that diets high in calcium might decrease the risk of breast cancer 17 23 Fruits and vegetables edit High total dietary fiber consumption and total fruit and vegetable consumption is associated with a reduced risk of breast cancer 24 25 Meat edit High total processed meat and red meat consumption are associated with increased breast cancer risk 14 26 27 Saturated fat edit Several reviews of case control studies have found that saturated fat intake is associated with increased breast cancer risk 14 28 29 Polycyclic Aromatic Hydrocarbons edit Main article Polycyclic aromatic hydrocarbon Human health Polycyclic aromatic hydrocarbons PAHs are a known human carcinogens due to their mutagenic ability to damage DNA which causes cancer A 2016 study found that sources of PAHs such as grilled and smoked meats along with other sources such as cigarette smoking and indoor air pollution were associated with 30 50 increase in breast cancer incidence 30 High risk individuals were those who were active smokers consumed greater than 55 servings of grilled smoked meats a year frequently used indoor fire places and were exposed to large amounts of traffic pollution 30 The study was a population based case control study conducted on Long island New York N 1 508 breast cancer cases 1 556 controls The authors concluded that while PAHs are ubiquitous breast cancer risk factors could be modified by dietary and lifestyle changes Obesity and Lack of Exercise editGaining weight after menopause can increase a woman s risk A 2006 study found that putting on 9 9 kg 22 lbs after menopause increased the risk of developing breast cancer by 18 31 Lack of exercise has been linked to breast cancer by the American Institute for Cancer Research 32 Obesity has been linked to an increased risk of developing breast cancer by many scientific studies 33 There is evidence to suggest that excess body fat at the time of breast cancer diagnosis is associated with higher rates of cancer recurrence and death 33 Furthermore studies have shown that obese women are more likely to have large tumors greater lymph node involvement and poorer breast cancer prognosis with 30 higher risk of mortality 34 Weight gain after diagnosis has also been linked to higher rates of breast cancer recurrence or mortality although this finding is not consistent 33 Weight gain is often less severe with newer chemotherapy treatments but one study found a significant risk of breast cancer mortality in women who gained weight compared to those who maintained their weight 35 However other cohort studies and recent clinical trials have not shown a significant relationship between weight gain after diagnosis and breast cancer mortality 33 36 Weight loss after diagnosis has not been shown to decrease the risk of breast cancer recurrence or mortality 33 However physical activity after breast cancer diagnosis has shown some associations with reducing breast cancer recurrence and mortality independent of weight loss 37 Data for both weight loss and physical activity and the effect on breast cancer prognosis is still lacking 33 There is debate as to whether the higher rate of breast cancer associated with obesity is due to a biological difference in the cancer itself or differences in other factors such as health screen practices 38 It has been suggested that obesity may be a determinant for breast cancer screening by mammography Seventeen scientific studies in the United States have found that as obesity increases in women over 40 years of age the rate of mammography reported decreases significantly 39 When stratified by race white vs black there was a stronger relationship between obesity and lack of mammography screening among white women 39 Another study also found lower rates of mammography among those who were overweight and obese compared to those women who were of normal body mass index this effect was only seen in white women 40 Obese women are more likely to list pain associated with mammograms as a reason for not getting screened however leaner women also list this as a reason for avoiding mammograms 41 Other reasons obese women may avoid mammography are due to lack of insurance low income or embarrassment at the procedure although when these factors are accounted for the effect of lower rates of screening are still significant 41 In contrast other studies have shown that mammography patterns did not differ among women who were obese compared to those at a healthy weight indicating that there may be biological differences in cancer presentation between these groups 42 Hormones editPersistently increased blood levels of estrogen are associated with an increased risk of breast cancer as are increased levels of the androgens androstenedione and testosterone which can be directly converted by aromatase to the estrogens estrone and estradiol respectively Increased blood levels of progesterone are associated with a decreased risk of breast cancer in premenopausal women 43 A number of circumstances which increase exposure to endogenous estrogens including not having children delaying first childbirth not breastfeeding early menarche the first menstrual period and late menopause are suspected of increasing lifetime risk for developing breast cancer 44 However not only sex hormones but also insulin levels are positively associated with the risk of breast cancer 45 Pregnancy childbearing and breastfeeding edit Lower age of first childbirth compared to the average age of 24 46 having more children about 7 lowered risk per child and breastfeeding 4 3 per breastfeeding year with an average relative risk around 0 7 47 48 have all been correlated to lowered breast cancer risk in premenopausal women but not postmenopausal women in large studies 49 Women who give birth and breast feed by the age of 20 may have even greater protection 50 In contrast for instance having the first live birth after age 30 doubles the risk compared to having first live birth at age less than 25 51 Never having children triples the risk 51 The studies have found that these risk factors become less material as a woman reaches menopause i e that they affect risk of breast cancer prior to menopause but not after it In balancing premenopausal reductions in risk from childbirth and lactation it is important also to consider the risks involved in having a child Hormonal contraception edit Hormonal contraceptives may produce a slight increase in the risk of breast cancer diagnosis among current and recent users but this appears to be a short term effect In 1996 the largest collaborative reanalysis of individual data on over 150 000 women in 54 studies of breast cancer found a relative risk RR of 1 24 of breast cancer diagnosis among current combined oral contraceptive pill users 10 or more years after stopping no difference was seen Further the cancers diagnosed in women who had ever used hormonal contraceptives were less advanced than those in nonusers raising the possibility that the small excess among users was due to increased detection 52 53 The relative risk of breast cancer diagnosis associated with current and recent use of hormonal contraceptives did not appear to vary with family history of breast cancer 54 Some studies have suggested that women who began using hormonal contraceptives before the age of 20 or before their first full term pregnancy are at increased risk for breast cancer but it is not clear how much of the risk stems from early age at first use and how much stems from use before the first full term pregnancy 55 Hormone replacement therapy edit Data exist from both observational and randomized clinical trials regarding the association between menopausal hormone replacement therapy menopausal HRT and breast cancer The largest meta analysis 1997 of data from 51 observational studies indicated a relative risk of breast cancer of 1 35 for women who had used HRT for 5 or more years after menopause 56 The estrogen plus progestin arm of the Women s Health Initiative WHI a randomized controlled trial which randomized more than 16 000 postmenopausal women to receive combined hormone therapy or placebo was halted early 2002 because health risks exceeded benefits One of the adverse outcomes prompting closure was a significant increase in both total and invasive breast cancers hazard ratio 1 24 in women randomized to receive estrogen and progestin for an average of 5 years 57 HRT related breast cancers had adverse prognostic characteristics more advanced stages and larger tumors compared with cancers occurring in the placebo group and HRT was also associated with a substantial increase in abnormal mammograms Short term use of hormones for treatment of menopausal symptoms appears to confer little or no breast cancer risk 54 A correlation was found between the use of hormonal contraceptives and subsequent reliance on hormone replacement therapy 55 Oophorectomy and mastectomy edit Main article BRCA mutation Prophylactic oophorectomy removal of ovaries and mastectomy in individuals with high risk mutations of BRCA1 or BRCA2 genes reduces the risk of developing breast cancer as well as reducing the risk of developing ovarian cancer Because of a complex balance of benefits and risks of a prophylactic surgery it is recommended only in very specific cases Hormonal therapy edit Main article Hormonal therapy oncology Hormonal therapy has been used for chemoprevention in individuals at high risk for breast cancer Overall it is recommended only in very special circumstances In 2002 a clinical practice guideline by the US Preventive Services Task Force USPSTF recommended that clinicians discuss chemoprevention with women at high risk for breast cancer and at low risk for adverse effects of chemoprevention with a grade B recommendation 58 verification needed 59 60 Selective estrogen receptor modulators SERMs edit The guidelines clarification needed were based on studies of SERMs from the MORE BCPT P 1 and Italian trials In the MORE trial the relative risk reduction for raloxifene was 76 61 The P 1 preventative study demonstrated that tamoxifen can prevent breast cancer in high risk individuals The relative risk reduction was up to 50 of new breast cancers though the cancers prevented were more likely estrogen receptor positive this is analogous to the effect of finasteride on the prevention of prostate cancer in which only low grade prostate cancers were prevented 62 63 The Italian trial showed benefit from tamoxifen 64 Additional randomized controlled trials have been published since the guidelines The IBIS trial found benefit from tamoxifen 65 In 2006 the NSABP STAR trial demonstrated that raloxifene had equal efficacy in preventing breast cancer compared with tamoxifen but that there were fewer side effects with raloxifene 66 The RUTH Trial concluded that benefits of raloxifene in reducing the risks of invasive breast cancer and vertebral fracture should be weighed against the increased risks of venous thromboembolism and fatal stroke 67 On September 14 2007 the US Food and Drug Administration approved raloxifene Evista to prevent invasive breast cancer in postmenopausal women 68 Endocrine disruptors edit Many xenoestrogens industrially made estrogenic compounds and other endocrine disruptors are potential risk factors of breast cancer Diethylstilbestrol DES is a synthetic form of estrogen It has been used between the early 1940s and 1971 Pregnant women took DES to prevent certain pregnancy complications However it also increased their risk of breast cancer It also increased the risk of breast cancer in the prenatally exposed daughters after they have reached an age 40 years 69 Factors in the physical environment editAccording to a review the main mechanisms by which environmental compounds increase breast cancer risk are acting like hormones especially estrogen or affecting susceptibility to carcinogenesis 70 The evidence to date generally supports an association between breast cancer and polycyclic aromatic hydrocarbons PAHs and polychlorinated biphenyls PCBs Dioxins and organic solvents on the other hand have only shown an association in sparse and methodologically limited studies but are suggestive of an association 70 Overall however evidence is still based on a relatively small number of studies 70 Xenoestrogens edit Main article Xenoestrogens Many xenoestrogens industrially made estrogenic compounds are endocrine disruptors and potential risk factors of breast cancer Endocrine disruption is the hypothesis that some chemicals in the body such as Bisphenol A are capable of interfering with the production processing and transmission of hormones 71 A substantial and growing body of evidence indicates that exposures to certain toxic chemicals and hormone mimicking compounds including chemicals used in pesticides cosmetics and cleaning products contribute to the development of breast cancer The increasing prevalence of these substances in the environment may explain the increasing incidence of breast cancer though direct evidence is sparse Bisphenol A edit Main article Bisphenol A nbsp Exposure to bisphenol A causes breast cancer 72 Bisphenol A BPA is a chemical compound used in the production of plastics found in numerous commercial products including laptops baby bottles food containers water main pipes and laboratory and hospital equipment BPA was first produced in 1891 but its estrogenic properties went undiscovered until the mid 1930s Today it is considered a xenoestrogen and it functions as an endocrine disruptor that interferes with hormones in the body and disrupts the normal functioning of the endocrine system At very low levels the FDA has long considered BPA in food to be safe but this has been challenged over the years as more information is discovered regarding the effects of the chemical 73 Rats exposed prenatally to environmentally relevant doses of BPA show an increased number of intraductal hyperplasias precancerous lesions in mammary glands that appear during adulthood while high doses induce the development of carcinomas in breast tissue Animals exposed to BPA during fetal life develop palpable tumors and all studies show an increased susceptibility to mammary gland neoplasia that manifests during adulthood Exposure of mouse dams to environmentally relevant levels of BPA during organogenesis results in considerable alterations in the mammary gland It was concluded that perinatal exposure to low doses of BPA results in altered mammary gland morphogenesis induction of precancerous lesions and carcinoma in situ 72 A study sought to determine whether early exposure to BPA could accelerate mammary carcinogenesis in a dimethylbenzanthracene DMBA model of rodent mammary cancer In the study scientists exposed neonatal prebubertal rats to BPA via lactation from nursing dams treated orally with 0 25 and 250 µg BPA kg body weight day For tumorigenesis studies female offspring were exposed to 30 mg DMBA kg body weight at 50 days of age DMBA induces mammary tumors and allows chemicals that predispose for mammary cancer to increase the number of mammary adenocarcinomas The results of the study showed that female rats in the control BPA 25 and BPA 250 groups administered DMBA exhibited a BPA dose dependent increase in mammary tumors The groups had 2 84 3 82 and 5 00 mammary tumors per rat respectively Treatment with BPA also reduced tumor latency with the median tumor latency of 65 53 and 56 5 days for 0 BPA 25 and BPA 250 groups respectively Maternal exposure to BPA during lactation decreased time to first tumor latency and increased the number of DMBA induced mammary tumors in female offspring If these effects found in rodents carry over to humans even minimal exposure to BPA could cause an increased risk for breast cancer 74 The elevated incidence of breast cancer in women has been associated with prolonged exposure to high levels of estrogens Xenoestrogens such as BPA have the capacity to perturb normal hormonal actions This study provides evidence of the estrogenic effects of BPA In this study the human breast epithelial cells MCF 10F were treated with 10 3 M 10 4 M 10 5 M and 10 6 M BPA continuously for two weeks The cells treated with 10 3 M BPA died on the second day of treatment The concentration of 10 4 M BPA was also toxic for the breast epithelial cells and they died on the fourth day of treatment This data indicated that these concentrations of BPA are toxic for MCF 10F cells After the two week observation period it was seen that the cells formed a high percentage of duct like structures in collagen MCF 10F cells treated with 10 5 M and 10 6 M BPA formed a high percentage of solid masses 27 and 20 respectively This data indicates that BPA is able to induce neoplastic transformation of human breast epithelial cells Epigenetic changes are involved in the early stages of cancer initiation by altering ductulogenesis BPA was able to induce transformation of human breast MCF 10F epithelial cells After treatment with BPA the cells produced fewer collagen tubules and more solid masses 75 Consumer groups recommend that people wishing to lower their exposure to bisphenol A avoid canned food and polycarbonate plastic containers which shares resin identification code 7 with many other plastics unless the packaging indicates the plastic is bisphenol A free 76 The National Toxicology Panel recommends avoiding microwaving food in plastic containers putting plastics in the dishwasher or using harsh detergents on plastics to avoid leaching 77 Aromatic Amines edit Aromatic amines are chemicals that are produced when products such as dyes polyurethane products and certain pesticides are made They are also found in cigarette smoke fuel exhaust and in over cooked burned meat The three types of aromatic amines monocyclic polycyclic and heterocyclic have all been found in recent studies of breast health Monocyclic amines have been found to cause mammary cancer in rats Studies have shown that women who eat higher amounts of overcooked meat meaning more exposure to heterocyclic amines have also been diagnosed with more post menopausal breast cancer Heterocyclic amines also have the ability to copy estrogen and in laboratory studies have been found to encourage the growth of cancerous tumors on human tissue 78 Benzene edit nbsp Multiple studies point to a correlation between benzene exposure and breast cancer risk 78 Benzene is a petrochemical solvent Benzene exposure mostly originates from air pollution resulting from industrial burning exhaust and gas fumes as well as cigarette smoke Petroleum its distillates such as gasoline auto and truck exhausts also contain benzene The International Agency for Research on Cancer and the National Toxicology Program have labeled benzene as a definite human carcinogen Multiple studies point to a correlation between benzene exposure and breast cancer risk Laboratory studies on mice have shown that a high level of benzene exposure can lead to mammary cancer 78 DDT edit Main article DDT Breast cancer Although the pesticide DDT was banned over 20 years ago studies have shown that there are still trace amounts found in certain agricultural products as well as in human and animal milk 79 While individual studies have come to conflicting conclusions the most recent reviews of all the evidence conclude that exposure to DDT before puberty increases the risk of breast cancer later in life 80 81 Ethylene oxide edit Ethylene oxide is a chemical that can be found in some personal care products mainly in the form of fragrance It is also used for the sterilization of various medical objects The National Toxicology Program has labeled ethylene oxide as a definite human and animal carcinogen A study done by the National Institute for Occupational Safety and Health including 7 576 women found a direct correlation between breast cancer rates and exposure to ethylene oxide during medical sterilization processes Also human breast cells put into contact with small amounts of ethylene oxide in a laboratory can lead to DNA damage of the breast tissue 78 Polycyclic aromatic hydrocarbons edit Polycyclic aromatic hydrocarbons are chemical products of combustion from coal burners fuel cigarette smoke and various other sources PAH s are often found in the air and are breathed into the body PAH s bioaccumulate easily and can copy the estrogen hormone PAH s can also be genotoxic meaning they have the ability to harm DNA 78 Vinyl chloride edit Vinyl chloride is produced when PVC or polyvinyl chloride is made PVC is found in plastic packaging outerwear plastic toys and other plastic products Vinyl chloride can be found in cigarette smoke and the air around garbage and land fills It can also be found in the wastewater when PVC is made The National Toxicology Program and the International Agency for Research on Cancer have both labeled vinyl chloride as a definite human carcinogen 78 Tobacco edit See also Women and smoking Unique gender differences and health effects for Females Until recently most studies had not found an increased risk of breast cancer from active tobacco smoking Beginning in the mid 1990s a number of studies suggested an increased risk of breast cancer in both active smokers and those exposed to secondhand smoke compared to women who reported no exposure to secondhand smoke 82 By 2005 enough evidence had accumulated for the California Environmental Protection Agency to conclude that breathing secondhand smoke causes breast cancer in younger primarily premenopausal women 83 The Agency concluded that the risk was increased by 70 based on epidemiological studies and the fact that there are many mammary carcinogens in secondhand smoke The following year 2006 the US Surgeon General 84 identified the same risk increase and concluded that the evidence is suggestive one step below causal There is some evidence that exposure to tobacco smoke is most problematic between puberty and first childbirth The reason is that breast tissue appears most sensitive to chemical carcinogens breast cells not fully differentiated until lactation 85 The likely reason that the older studies of active smoking did not detect risks associated with smoking was that they compared active smokers to all nonsmokers which includes many passive smokers The newer studies which exclude passive smokers from the control group generally show elevated risks associated with active as well as passive smoking Passive smoking edit Breathing secondhand smoke increases breast cancer risk by 70 in younger primarily pre menopausal women The California Environmental Protection Agency has concluded that passive smoking causes breast cancer 83 and the US Surgeon General 84 has concluded that the evidence is suggestive one step below causal There is some evidence that exposure to tobacco smoke is most problematic between puberty and first childbirth The reason that breast tissue appears most sensitive to chemical carcinogens in this phase is that breast cells are not fully differentiated until lactation 85 Radiation edit Women who have received high dose ionizing radiation to the chest for example as treatments for other cancers have a relative risk of breast cancer between 2 1 and 4 0 82 The risk increases with increased dose In addition the risk is higher in women irradiated before age 30 when there is still breast development 51 Dioxins edit Dioxins most notably the polychlorinated dibenzodioxins are chemicals that are produced when chlorinated products are burned such as polyvinyl chloride PVC This occurs when chlorinated products are used in certain manufacturing industries Dioxins are also added to the air when gasoline and diesel fuels break down Dioxins are able to bioaccumulate meaning that they settle and stay in human and animal fat for long periods of time There are many different types of dioxins and only a few of them have been labeled by the Environmental Protection Agency as definite human carcinogens and endocrine hormone disruptors Although dioxins are floating in the air they eventually settle on plants and other vegetation surfaces These plants and vegetation are them eaten by cows and other animals Humans end up eating the produce milk eggs and meat produced by these animals that have consumed dioxin covered vegetation Dioxins are more harmful when ingested this way Multiple studies have led to the idea that increased dioxin levels can increase one s risk for breast cancer A study done in 1976 after a chemical plant explosion in Seveso Italy concluded that high dioxin level exposure in a woman s body correlated with a more than double chance of developing breast cancer 78 Light at night and disturbance of circadian rhythm edit In 1978 Cohen et al proposed that reduced production of the hormone melatonin might increase the risk of breast cancer and citing environmental lighting as a possible causal factor 86 Researchers at the National Cancer Institute NCI and National Institute of Environmental Health Sciences conducted a study in 2005 that suggests that artificial light during the night can be a factor for breast cancer by disrupting melatonin levels 87 According to a research in 2008 a reduced melatonin level in postmenopausal women is linked to a higher risk of breast cancer 88 In 2007 shiftwork that involves circadian disruption was listed as a probable carcinogen by the World Health Organization s International Agency for Research on Cancer IARC Press release No 180 89 Multiple studies have documented a link between night shift work and the increased incidence of breast cancer 90 91 92 93 A review of current knowledge of the health consequences of exposure to artificial light at night including the increased incidence of breast cancer and an explanation of the causal mechanisms has been published in the Journal of Pineal Research in 2007 94 Tonsillectomy editA systematic review and meta analysis of eight studies revealed an association of prior tonsillectomy and risk of breast cancer in females 95 Ethnicity related and socioeconomic factors editIncidence and mortality vary with ethnic background and social status Incidence rises with improving economic situation while mortality is tied to low economic status In the US incidence is significantly lower and mortality higher among black women and this difference appears to persist even after adjustment for economic status It is currently unclear if significant ethnic differences in incidence and mortality persist after adjustment for economic status between women of white Hispanic and Asian origin in the US 96 Several studies have found that black women in the U S are more likely to die from breast cancer even though white women are more likely to be diagnosed with the disease Even after diagnosis black women are less likely to get treatment compared to white women 97 98 99 Scholars have advanced several theories for the disparities including inadequate access to screening reduced availability of the most advanced surgical and medical techniques or some biological characteristic of the disease in the African American population 100 Some studies suggest that the racial disparity in breast cancer outcomes may reflect cultural biases more than biological disease differences 101 However the lack of diversity in clinical trials for breast cancer treatment may contribute to these disparities with recent research indicating that black women are more likely to have estrogen receptor negative breast cancers which are not responsive to hormone treatments that are effective for most white women 102 Research is currently ongoing to define the contribution of both biological and cultural factors 98 103 Part of the differences in incidence that is attributable to race and economic status may be explained by past use of hormone replacement therapy 104 Factors with inconclusive research edit1 3 Butadiene edit 1 3 Butadiene is an environmental factor that can be found in air pollution and can be produced by combustion engines as well as petroleum refineries It is found in cigarette smoke and is also used in the making and processing of certain synthetic rubber products and fungicides The National Toxicology Program has labeled 1 3 Butadiene as definite human carcinogen The EPA has stated that people are mainly put in contact with this chemical through the means of simple inhalation 78 Mammographic density edit Mammographic density refers to the relative proportions of radiodense area compared to the radiolucent area on a mammogram which is basically an x ray of the breast The radiodense area on a mammogram is white and is associated with ductal and lobular epithelium connective tissue and fluid in the breast The radiolucent area is dark gray or black and is associated with fat in the breast High mammographic density is associated with a higher risk of developing breast cancer but the reasons for this link are not certain and are being studied 105 106 Conversely patients with very low mammographic breast density were found to hold a poorer prognosis irrespective of age BMI and menopausal status 107 Red No 3 edit Red No 3 is a coloring agent used in some foods In laboratory tests human breast cell DNA was found positive for damage when put into contact with Red No 3 which means that it is genotoxic 108 Viruses edit Several kinds of viruses with oncogenic potential are suspected to play a role or cause breast cancer Among the three most commonly studied are the human papilloma virus HPV 109 mouse mammary tumour virus 110 MMTV and the Epstein Barr virus EBV 110 A study published in 2011 reviewing 85 original molecular research investigations on the presence of one or more of these three viruses found that only seven of the studies convincingly demonstrated the presence of an oncogenic virus biomarker while twenty five of the studies were able to show the absence of the virus studied and the remaining studies were excluded due to shortcomings Thus the data from these investigations do not justify a conclusion as to whether HPV MMTV or EBV play a causal role in human breast cancer development 111 Humans are not the only mammals susceptible to breast cancer Some strains of mice namely the house mouse Mus domesticus are prone to breast cancer which is caused by infection with the mouse mammary tumour virus MMTV or Bittner virus for its discoverer John Joseph Bittner by random insertional mutagenesis It is the only animal breast cancer with a known etiology 111 These findings are taken to mean that a viral origin of human breast cancer is at least possible though there is no definitive evidence to support the claim that MMTV causes human breast cancer For example there may be critical differences between cancer pathogenesis in mice and people A human homologue of the mammary virus has been described in 1971 and linked to human breast cancer in several small epidemiologic studies 112 113 Factors with minimal or no impact editThere is no significant association between first trimester abortion and breast cancer risk 114 There is no scientific evidence to prove that any kind of brassiere can cause cancer 115 116 The myth that breast cancer is linked with deodorant use has been widely circulated and appears to originate from a spam email sent in 1999 117 There is however no evidence to support the existence of such a link 118 There is no persuasive connection between fertility medications and breast cancer 119 History editIn past centuries the development of breast cancer was most commonly seen as divine punishment or a trial From ancient Greek medicine until the end of the 17th century the dominant medical explanation was an imbalance of the four humors 120 By the start of the 18th century humoralism had generally been rejected Many other theories were put forward often related to sexual activity In 1713 Bernardino Ramazzini said that nuns developed breast cancer at a higher rate than married women because they did not engage in sexual intercourse and the unnatural lack of sexual activity caused instability of the breasts others countered that the cause was frequently too much sexual activity 121 Other theories from the 18th century included various sorts of problems with the movement of body fluids such as lymphatic blockages curdled breast milk or the transformation of pus left after an infection 121 In modern times women are more likely to blame themselves perhaps deciding that their diet childbearing history decision not to breastfeed or level of exercise is the cause 120 See also editCarcinogen IARC classification of carcinogens Epidemiology of breast cancer Mouse models of breast cancer metastasis Silent Spring InstituteReferences edit a b Institute of Medicine 2012 Breast Cancer and the Environment A Life Course Approach Institute of Medicine Washington D C National Academies Press pp 52 53 doi 10 17226 13263 ISBN 978 0 309 22069 9 Madigan MP Ziegler RG 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E Gligorov J Lokiec F Spielmann M September 2008 The use of deodorants antiperspirants does not constitute a risk factor for breast cancer The use of deodorants antiperspirants does not constitute a risk factor for breast cancer Bulletin du Cancer Comprehensive literature review in French 95 9 871 80 doi 10 1684 bdc 2008 0679 inactive 1 August 2023 PMID 18829420 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint DOI inactive as of August 2023 link Potashnik G Lerner Geva L Genkin L Chetrit A Lunenfeld E Porath A May 1999 Fertility drugs and the risk of breast and ovarian cancers results of a long term follow up study Fertility and Sterility 71 5 853 9 doi 10 1016 S0015 0282 99 00085 0 PMID 10231045 a b Yalom M 1997 A history of the breast New York Alfred A Knopf p 234 ISBN 978 0 679 43459 7 a b Olson JS 2002 Bathsheba s breast women cancer amp history Baltimore The Johns Hopkins University Press pp 32 33 ISBN 978 0 8018 6936 5 External links editBreast Cancer Myths and Facts Breast cancer at Curlie GeneReviews NCBI NIH UW entry on BRCA1 and BRCA2 Hereditary Breast Ovarian Cancer Breast cancer database at Silent Spring Institute Risk factors for breast cancer at Curlie Retrieved from https en wikipedia org w index php title Risk factors for breast cancer amp oldid 1176500663, wikipedia, wiki, book, books, library,

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