In January 2013 the U.S. Food and Drug Administration cut the recommended dose of the nation’s most popular sleep drug, Ambien, in half for women but not for men. The FDA had determined that 15 percent of the 5.7 million women using zolpidem products (the active ingredient in Ambien) were experiencing driving impairment eight hours after taking the drug, compared with 3 percent of the 3.5 million male zolpidem users.

Researchers had known for a long time that women, on average, clear zolpidem from their body much more slowly than men do. Indeed, drug metabolism, tolerance, side effects and benefits differ significantly between the average man and woman for many widely prescribed medications, with women having a 50 to 70 percent higher chance of an adverse reaction. Body size, proportion of fat to muscle and a host of other factors, including hormonal influences, account for these differences. But physicians rarely consider these dynamics when writing prescriptions. Ambien, which now comes in bottles with pink (low dose) and blue (original dose) labels, is a rare example of a “sex-specific” medical recommendation. (The fda now recommends that men also be started on the low dose of the drug, and doctors can use their discretion to increase the dose.)

Drug-dosing problems are just one example of how the health-care system is blind to biological sex differences. As a result, women are too often treated like men. Moreover, the system can be blind to gender bias; some disorders are considered “men’s” or “women’s,” even when both sexes suffer from them. Doctors often fail to diagnose stereotypical “male” conditions in women, and vice versa, until the condition has become dangerous.

These problems arise from a serious gap in our understanding of sex differences. The vast majority of animal research has been conducted only on males, mostly on rodents. And women have been grossly underrepresented in human clinical trials. Even when both sexes are included, sex-specific analyses are generally not reported—and because most subjects are men, the findings may not pertain to women. A 2019 study found that only 7 percent of reports on adverse drug reactions in people with heart failure gave data separately for women and men. And nearly half of these showed significant differences between the two. Not surprisingly, no one understood why a young woman hospitalized with a heart attack was twice as likely to die as a young man. Failure to include women in biomedical research was exacerbated by 1977 FDA guidelines that barred women of childbearing potential from participating in phase I (safety) and phase II (efficacy) trials, whether they were planning a pregnancy or not. Although the FDA now allows for inclusion of pregnant women in research that does not threaten pregnancy, few drugs are approved for pregnant women because safety and effectiveness data are not available.

Fixing the Problem

Changes in practices have been long in coming. In 1990 scientists, advocates and members of Congress pushed the National Institutes of Health to establish the Office of Research on Women’s Health. In 1991 cardiologist Bernadine Healy, the first and only woman director of the NIH, launched the Women’s Health Initiative, which enrolled nearly 162,000 women across the U.S. The study led to important changes in clinical care; without it, for example, physicians might still believe they should put most older women on hormone therapy, leading to many more heart attacks and strokes and cases of breast cancer. The 1993 NIH Revitalization Act required enrollment of female (and minority) participants in federally supported phase III trials—those designed to determine how a new treatment works in a large group. The act did not, however, require enrollment of enough women to determine how a given treatment affected women specifically.

More change came in 2001, when a landmark Institute of Medicine (IOM) report emphasized the important role that “sex” played in the basic biology that underpins health care. It concluded that “every cell has a sex.” Yet almost no cell biologists consider, or even know, the sex of the cells or tissues they study. Nor do they address how sex chromosomes affect the systems they are investigating. The IOM report defined sex as a biological quality or classification of sexually reproducing organisms, generally male or female, derived from chromosomes and sex hormones. Gender was defined, in human studies, as sociocultural—a person’s “self-representation as male or female.”

Credit: Jen Christiansen; Source: “Treatment Strategies for Women with Coronary Artery Disease: Future Research Needs: Identification of Future Research Needs from Comparative Effectiveness Review No. 66,” by Rowena J. Dolor et al. Agency for Healthcare Research and Quality, Report No. 13-Ehc073-ef; February 2013

This concept can be expanded to include gender norms (social expectations of “masculine” and “feminine” behaviors) and gender relations (how people react to one another because of gender), all of which can exert powerful influences on biology. For example, men are generally stronger than women not only because of biological factors such as larger muscles but also because of gender roles: in many societies, men lift and carry most of the heavy objects. Another example might be the twofold greater incidence of (unipolar) depression in women, which may result from an interaction of biological and social factors, such as women being more likely to be sexually assaulted.

Since the IOM report, scientists, academicians and health policy advocates have been urging their institutions, journals and government agencies to confront the need to include women and female animals in research and to study sex differences. In 2009 the Gendered Innovations project at Stanford University engaged collaborators across the U.S., Canada and the European Union to develop practical methods for sex and gender analysis and to track progress on including sex and gender in research. In 2010 the Office of Research on Women’s Health issued a strategic plan that identified the need to integrate sex and gender perspectives in basic science and medical research.

That same year the Canadian Institutes of Health Research went further and began asking grant applicants to indicate whether sex or gender was accounted for in their study proposals. A May 2014 notice in the journal Nature, written by Francis Collins, who was then director of the NIH, and Janine Clayton, director of the Office of Research on Women’s Health, unveiled policies designed to ensure that NIH-funded preclinical research consider both females and males, as well as the sex of cells. And in January 2016 the NIH began to require that sex as a biological variable be factored into research designs, analyses and reporting. If grant applicants propose to study only one sex, they must present persuasive justification for doing so. In contrast to the Canadian Institutes, however, the NIH did not address the influence of gender on biology.

A Man’s Disease

Gender biases profoundly influence diagnoses and treatments and therefore health outcomes. Despite years of “Red Dress” campaigns, most people and many physicians still think of heart disease as a man’s disease. They are surprised to learn that heart disease is the number-one killer of U.S. women, far exceeding deaths from breast cancer. Younger women, in particular, often go undiagnosed because physicians do not consider the possibility. Furthermore, women commonly report a range of symptoms beyond chest pain—the key complaint of men—including back pain, nausea, headache, dizziness and pain down the right arm (not just the left). Physicians often refer to these common symptoms as “atypical” because men do not report them.

Source: “Sex Bias in Neuroscience and Biomedical Research,” by Annaliese K. Beery and Irving Zucker, in Neuroscience and Biobehavioral Reviews, Vol. 35, No. 3; January 2011

In addition, although men and older women are likely to have a blockage in one or more of the coronary arteries from localized plaque—a buildup of cholesterol, fat and other substances—younger women are more likely to have diffuse plaque that lines and narrows the entire artery, resulting in inadequate blood supply to the heart. Because no specific blockage is detected, they may be diagnosed as “free of heart disease” yet at high risk of a fatal heart attack. Although newer diagnostic tests can detect this nonobstructive disease, a physician has to consider the possibility that a young woman has heart disease to order them. Prevention and treatment guidelines for women are still based predominantly on male data, despite growing evidence of sex differences in risks and treatment outcomes.

Pregnancy, now recognized as a major cardiovascular stress test, also contributes to sex disparities, yet researchers have only recently begun to realize the serious long-term consequences. Pregnancy-related hypertension and preeclampsia, as well as gestational diabetes (high blood glucose developed during pregnancy), increase a woman’s chance of developing subsequent cardiovascular disease nearly twofold, as well as her risk of developing type II diabetes.

Hard to Decipher

Sex differences and gender biases influence medical diagnoses and treatments for everyone. Osteoporosis, characterized by reduced bone strength, is considered a woman’s disease because white women have twice the lifetime risk of fracturing a bone, compared with white men. Fracture-prevention trials have included few men. Yet men account for nearly one in three hip fractures, and their medical outcomes are worse after the injury.

Men are more susceptible to viral, bacterial, parasitic and fungal infections than women are, although women have greater rates of sexually transmitted infections such as HIV and herpes simplex virus 2. On the other hand, the more robust immune system of women may explain why they constitute more than 70 percent of the 24 million Americans with autoimmune diseases, in which the immune system attacks one’s own body tissues. Pregnancy may play a role here as well. Some fetal cells cross into the mother’s blood and are found in her circulation decades later, and they have been implicated in some autoimmune diseases.

Sex and gender also shape neurological and mental diseases. Accumulating evidence suggests that the placenta of the male fetus responds to environmental stressors by promoting fetal growth, whereas the female placenta promotes gene and protein expression that increases chances of survival. This difference may contribute to developmental disorders that are diagnosed more often in boys, such as autism and dyslexia—although diagnostic methods may overlook girls.

Credit: Illustrations by Mesa Schumacher, Graphics by Jen Christiansen; Sources: “The Recent Prevalence of Osteoporosis and Low Bone Mass in the United States Based on Bone Mineral Density at the Femoral Neck or Lumbar Spine,” by Nicole C. Wright et al., in Journal of Bone and Mineral Research, Vol. 29, No. 11; November 2014 (osteoporosis); “GBD Compare.” Institute for Health Metrics and Evaluation, Seattle, Wa. Accessed July 2017 http://vizhub.healthdata.org/gbdcompare (multiple sclerosis and heart disease); “Deaths: Final Data for 2014,” by Kenneth D. Kochanek et al., in National Vital Statistics Reports, Vol. 65, No. 4; June 30, 2016 (Alzheimer's disease); “Mechanistic Pathways of Sex Differences in Cardiovascular Disease,” by Vera Regitz-Zagrosek and Georgios Kararigas, in Physiological Reviews, Vol. 97, No. 1; January 2017 (heart illustrations)

Gender bias surrounding mental illnesses seems to be widespread. The suggestion that boys and men manifest depression with anger, rather than withdrawal, may arise from a biased expectation that males externalize behaviors and females internalize them. Some mental health professionals around the world still assign certain symptoms almost exclusively to women, such as being “hysterical,” whereas men are likely to be diagnosed as “antisocial.” These biases affect treatments and health outcomes. In addition, a woman is much more likely to be diagnosed with depression than a man with identical presentation because of gender biases in the medical system. Women also receive more antidepressants and less adequate pain medication when reporting pain because of an incorrect belief that they have a greater tolerance to it. In fact, they have a lower threshold for almost every kind of pain investigated.

Bias is rampant when it comes to the brain. Pop psychology loves the idea that men and women have different brains. Reports show that males have more cortical connections within each of the brain’s two hemispheres, whereas women have more connections between the hemispheres. But the reports fail to mention that 86 to 88 percent of all these combined connections are similar—suggesting that male and female brains are more alike than different. Research also increasingly shows that any individual’s brain development over a person’s lifetime is greatly influenced by neuroplasticity—the ability of brain cells to rewire over time. If the daily experiences of boys and men differ markedly from those of girls and women, differences in brain structure and function should be expected.

This complicated picture makes it difficult to pin down causes and treatments for brain illnesses. Almost two thirds of the more than six million Americans who have Alzheimer’s disease are women, not only because more women than men survive to age 65 but also because more women acquire the disease across all age groups.

Time to Get Personal

Clearly, medical researchers and physicians have a lot of untangling to do before they can offer better health care to women. A deeper understanding of sex differences will improve health directives for men, too. In 2015 the NIH launched a Precision Medicine Initiative to address the problem that most treatments have been designed for the “average patient” instead of different individuals. “Precision” or “personalized” medicine is expected to take into account variability in genes, environment and lifestyle for each person. Yet genome-wide studies that try to pinpoint genetic variants that may be linked to specific diseases have generally excluded X and Y chromosomes, suggesting that sex is not an important focus of precision medicine.

In 2015 the Canadian Institutes of Health Research rolled out an online training course on sex and gender in health research, and the League of European Research Universities released a report on how to integrate sex and gender into research processes. In 2016 the NIH mandated that researchers consider sex as a biological variable in animal and human studies, and a panel of 13 experts representing nine countries developed the Sex and Gender Equity in Research guidelines, a comprehensive procedure for reporting sex and gender information in study design, data analyses, results and interpretation of findings. Despite the initiation in 2015 of U.S. educational summits calling for integrating sex- and gender-based evidence into medicine and education, relatively little progress has been made. Several summits have been held to assess any new developments—the latest was held virtually in November 2021. Advancing understanding of sex and gender differences in health and disease and integrating those perspectives into emerging basic science fields and in translational research and technologies are two of the key themes of the NIH report on women’s health research.

We might need further mandates, through policy and funding restrictions, to ensure that female biology makes it into textbooks and testing protocols. We might also need to require best practices—standards of care that must be adhered to as part of the ethical code of “do no harm”—to ensure that clinicians and health-care providers consider both sex and gender in medical diagnoses, screening and treatments. Both women and men would benefit enormously. Without sex and gender as a focus, physicians cannot achieve the precision medicine, specific to each of us, that we all hope to receive.