  Infertility in womenHighlightsNew At-Home Fertility Test for Couples Fertell is a new at-home fertility test kit for couples. It screens for sperm motility concentrations and follicle-stimulating hormone (FSH) levels. Fertell may be helpful as an initial test for infertility, but for a definitive diagnosis it is important to consult a doctor. Infertility can be due to many different factors. Intracytoplasmic Sperm Injection Overused for Female Infertility The assisted reproductive technology intracytoplasmic sperm injection (ICSI) is being increasingly used in combination with in vitro fertilization (IVF), even for couples who do not have problems with male infertility, suggests a 2007 study in the New England Journal of Medicine. Researchers found that use of ICSI has increased 5-fold in the past decade. Some doctors are now recommending ICSI for women who have failed prior IVF cycles or who have few or poor-quality eggs. Doctors caution that ICSI should be used only to improve pregnancy chances for couples with male-factor infertility. Clomiphene Best for PCOS-Associated Infertility The infertility drug clomiphene (Clomid) works better than the diabetes drug metformin (Glucophage) for treating infertility resulting from polycystic ovarian syndrome (PCOS), indicates a 2007 study in the New England Journal of Medicine. Fertility Drugs and Breast Cancer Fertility drugs such as clomiphene and gonadotropins do not increase the risk for breast cancer, indicate several studies. In fact, according to a 2006 study in the Archives of Internal Medicine, clomiphene may decrease breast cancer risk. Iron Deficiency and Female Infertility Iron deficiency may increase the risk for ovulatory infertility, suggests a 2006 study in Obstetrics and Gynecology. Researchers found that women who took daily iron supplements were 40% less likely to be infertile than women who did not take supplements. Some experts recommend screening for iron deficiency as part of the clinical evaluation for infertility. IntroductionInfertility is the failure of a couple to become pregnant after one year of regular, unprotected intercourse. In both men and women the fertility process is complex. About 10% of couples who wish to have a baby are still unable to after a year of unprotected sex. About half of these couples can achieve pregnancy within 2 years after appropriate treatment of the woman, the man, or both. Even under ideal circumstances, the probability that a woman will get pregnant during a single menstrual cycle is only about 30%. And, when conception does occur, only 50 - 60% of pregnancies advance beyond the 20th week. (The inability of a woman to produce a live birth because of abnormalities that cause miscarriages is called infecundity and is not discussed in detail in this report.) Males and females each account for 40% of infertility. In the remaining 20%, either both partners are responsible or the cause is unclear. Although this report specifically addresses infertility in women, it is equally important for the male partner to be tested at the same time. [See In-Depth Report #67: Infertility in men.] The Reproductive SystemThe Primary Organs and Structures in the Reproductive System. The primary structures in the reproductive system are:
 The uterus is a hollow muscular organ located in the female pelvis between the bladder and rectum. The ovaries produce the eggs that travel through the fallopian tubes. Once the egg has left the ovary it can be fertilized and implant itself in the lining of the uterus. The main function of the uterus is to nourish the developing fetus prior to birth. Reproductive Hormones. The hypothalamus (an area in the brain) and the pituitary gland regulate the reproductive hormones.  Click the icon to see an image of the hypothalamus and pituitary gland. The pituitary gland is often referred to as the master gland because of its important role in many vital functions, many of which require hormones. In women, six key hormones serve as chemical messengers that regulate the reproductive system:
 Click the icon to see an image of the pituitary gland.
Ovulation. The process leading to fertility is very intricate. It depends on the healthy interaction of two sets of organs and hormone systems in both the male and female. In addition, reproduction is limited by the phases of female fertility. Nevertheless, this astonishing process results in conception within a year for about 80% of couples. Only 15% conceive within a month of their first attempts, however, and about 60% succeed after 6 months. A woman's ability to produce children occurs after she enters puberty and begins to menstruate. The process of conception is complex:
LH serves two important roles:
 Click the icon to see an image of the corpus luteum. Fertilization. The so-called "fertile window" is 6 days long and starts 5 days before ovulation and ends the day of ovulation. Fertilization occurs as follows:
 Click the icon to see an image of the placenta.
If the egg is not fertilized, the corpus luteum degenerates into a form called the corpus albicans, and estrogen and progesterone levels drop. Finally, the endometrial lining sloughs off and is shed during menstruation.
Onset of Menstruation (Menarche). Previous evidence had set the onset of menstruation, called the menarche, at an average age of 12 or 13. Recent studies, however, set the time of onset earlier by about 1 year in Caucasian girls and 2 years in African-American girls. Currently, the youngest possible age for normal puberty is 7 years old for Caucasians and 6 years old for African-Americans, down from a previous low of 8 years for both. Evidence is pointing to the increasing incidence of childhood obesity as a major cause of the trend in earlier menarche onset. (Obesity is also highly associated with hormonal disorders in girls entering puberty at young ages.) Environmental estrogens found in chemicals and pesticides are also suspects. Length of Monthly Cycle. The menstrual cycle can be very irregular for the first 1 - 2 years, usually being longer than the average of 28 days. The length then generally stabilizes to an average of 28 days, although the cycle length may range from 20 - 45 days and still be considered normal. A variation of 10 days or more -- either more or fewer days -- may have an impact on fertility, however. When a woman reaches her 40s the cycle lengthens, reaching an average of 31 days by age 49. Several factors can affect cycle length at any age.
Length of Periods. Periods average 6.6 days in young girls. By the age of 21, menstrual bleeding averages 6 days until women approach menopause. However, about 5% of healthy women menstruate less than 4 days, and 5% menstruate more than 8 days. Normal Absence of Menstruation. Normal absence of periods can occur in any woman under the following circumstances:
Risk FactorsIn the U.S., an estimated 10.2% of women ages 15 - 44, or about 6.1 million women, have impaired fertility, and the incidence is increasing. About 25% of women experience some period of infertility during their reproductive years. As a woman ages, her chances for fertility decline. Infertility in older women appears to be mostly due to a higher risk for chromosomal abnormalities that occur in her eggs as they age. Older women are also more likely to have health problems that may interfere with fertility. If fertilization occurs, older, healthy women can usually successfully bear a fetus to term, although they have a higher risk for miscarriage. Using population studies, experts have come up with estimated odds for pregnancy at different ages, given no fertility intervention. One analysis of pregnancy rates based on conception on the day of ovulation suggested that women ages 19 - 26 have twice the pregnancy rates as those ages 35 - 39.
Although most of a woman's estrogen is manufactured in her ovaries, 30% is produced in fat cells by a process that transforms circulating adrenal male hormones into estrogen. Because a normal hormonal balance is essential for the process of conception, it is not surprising that extreme weight levels, either high or low, can contribute to infertility. Being Overweight. Being overweight or obese (fat levels that are 10 - 15% above normal) can contribute to infertility in various ways. Obesity is highly associated with polycystic ovarian syndrome (PCOS), which is the cause of infertility in some cases. In one study, overweight women without PCOS were classified in one of five grades, depending on the severity of the obesity. The risk for irregular or absent periods increased two-fold by each increase in grade. In this group, amenorrhea (absent periods) was also highly associated with type 2 diabetes and blood sugar abnormalities. Being Underweight. Body fat levels 10 - 15% below normal can completely shut down the reproductive process. Women at risk include:
Exposure to environmental hazards (herbicides, pesticides, industrial solvents) may affect fertility. Estrogen-like hormone-disrupting chemicals are of particular concern for infertility in men and for effects on offspring of women. Phthalates, chemicals used to soften plastics, are under particular scrutiny for their ability to disrupt hormones. Specific phthalates of special concern include dibutyl phthalate (DBP) and others found in many products, including cosmetics and clay products sold to children (Fimo, Sculpey). Animals exposed to phthalates have significantly impaired sperm count and abnormalities in reproductive structures, such as the testes. In addition, there is some concern that exposure in pregnant women may affect the offspring. Neurotransmitters (chemical messengers) act in the hypothalamus gland, which controls both reproductive and stress hormones. Severely elevated levels of stress hormone can, in fact, shut down menstruation. Whether stress has any significant effect on fertility or fertility treatments is unclear. One 2005 study found that psychological stress does not affect the success or failure of in vitro fertilization.  Click the icon to see an image of the hypothalamus. CausesCauses of infertility can be found in about 90% of infertility cases but, despite extensive tests, about 10% of couples will never know why they cannot conceive. Between 10 - 30% of cases of infertility have more than one cause. Male or female infertility each account for about 30 - 40% of cases. In men, sperm defects (their quality and quantity) are usually responsible. Female infertility is more complex. Pelvic inflammatory disease (PID) is the major cause of female infertility worldwide. PID comprises a variety of infections caused by different bacteria that affect the reproductive organs, appendix, and parts of the intestine that lie in the pelvic area. The sites of infection most often implicated in infertility are in the fallopian tubes, a specific condition referred to as salpingitis. Causes of PID. PID may result from many different conditions that cause infections. Among them are:
Symptoms of PID. The infection may be subclinical (occurring without any symptoms), or there may be fever, chills, or pelvic pain indicating inflammation of the entire pelvic area. Effects of PID. Severe or frequent attacks of PID can eventually cause scarring, abscess formation, and tubal damage that result in infertility. About 20% of women who develop symptomatic PID become infertile. PID also significantly increases the risk of ectopic pregnancy (fertilization in the fallopian tubes). The severity of the infection, not the number of the infections, appears to pose the greater risk for infertility. Endometriosis may account for as many as 30% of infertility cases. Some evidence suggests that between 30 - 50% of women with endometriosis are infertile. Often, however, it is difficult to determine if endometriosis is the primary cause of infertility, particularly in women who have mild endometriosis. Endometriosis rarely causes an absolute inability to conceive, but, nevertheless, it can contribute to it both directly and indirectly.  Endometriosis is the condition in which the tissue that normally lines the uterus (endometrium) grows on other areas of the body causing pain and irregular bleeding. Direct Effect of Endometrial Cysts. Endometrial cysts may directly cause infertility in several ways:
Immune Factors and the Inflammatory Response. Researchers are focusing on defects in the immune system that not only may be responsible for endometriosis in the first place but may also cause the infertility associated with endometriosis. Even in early stage endometriosis, investigators have observed increased immune system activity. Other Conditions Linking Endometriosis and Infertility. Researchers have sometimes noted unusually low levels of specific substances that enable a fertilized egg to adhere to the uterine lining. (Such abnormalities are more often a factor in infertility in women with mild-to-moderate endometriosis than in those with severe cases.) One study found that the eggs in women with endometriosis appeared to have more genetic abnormalities than those in women without the disorder. Polycystic ovarian syndrome (PCOS) is a condition in which the ovaries produce high amounts of androgens (male hormones), particularly testosterone. PCOS occurs in about 6% of women, and amenorrhea or oligomenorrhea (infrequent menses) is quite common. According to one study, nearly 30% of obese women with PCOS had amenorrhea. (The rate was lower -- 4.7% -- in women with normal weight.)  Click the icon to see an image of polycystic ovarian syndrome. In PCOS, increased androgen production produces high luteinizing hormone (LH) levels and low follicle-stimulating hormone (FSH) levels, so that follicles are prevented from producing a mature egg. Without egg production, the follicles swell with fluid and form into cysts. Every time an egg is trapped within the follicle, another cyst forms, so the ovary swells, sometimes reaching the size of a grapefruit. Without ovulation, progesterone is no longer produced, whereas estrogen levels remain normal. The elevated levels of androgens (hyperandrogenism) can cause obesity, facial hair, and acne, although not all women with PCOS have such symptoms. Other male characteristics, such as deepening voice and clitoral enlargement, are rare. PCOS also poses a high risk for insulin resistance, particularly in women who are also obese. Insulin resistance is associated with diabetes type 2, in which insulin levels are normal or high but the body cannot use this hormone efficiently. About half of PCOS patients, in fact, also have diabetes. Premature ovarian failure is the early depletion of follicles before age 40, which, in most cases, leads to premature menopause. It affects about 1% of women and is typically preceded by irregular periods, which might continue for years. In this condition, follicle-stimulating hormone (FSH) levels are elevated, as they are during perimenopause. Premature ovarian failure is a significant cause of infertility, and women who have this condition have only a 5 - 10% chance to conceive without fertility treatments. Causes of Premature Ovarian Failure. There are numerous causes of premature ovarian failure. Often the cause of this disorder or other causes of premature ovarian failure is unknown. In some cases, premature ovarian failure may represent an acceleration of the aging process. The following conditions may produce premature ovarian failure:
Idiopathic hypogonadotropic hypogonadism is a rare condition in which follicle-stimulating hormone (FSH) and luteinizing hormone (LH) are underproduced, preventing the development of functional ovaries. There are no other abnormalities in the hypothalamus-pituitary axis (such as tumors or abnormal stress hormones or prolactin). In most cases, the causes of hypergonadotropic hypogonadism are unknown. Genetic factors, including Kallman syndrome, have been identified in about 20% of these cases. Functional hypothalamic amenorrhea (FHA) is the absence of menstruation due to disturbances in the thyroid gland and hypothalamus-pituitary-adrenal (HPA) system, which regulates reproduction and other important functions. The eating disorders anorexia and bulimia are most often associated with FHA. FHA may be due to other different factors, most unknown. Luteal phase defect is a general term referring to problems in the corpus luteum that result in inadequate production of progesterone. Because progesterone is necessary for thickening and preparing the uterine lining, the ovum fails to successfully implant in the endometrium. Between 25 - 60% of women who have recurrent miscarriages may have a luteal phase defect. A luteal phase defect, however, can also occur in fertile women, so other factors may be responsible for implantation failure. Benign fibroid tumors in the uterus are extremely common in women in their 30s. The effect of fibroids on fertility is controversial. One analysis suggested that they may account for infertility in only 1 - 2.4% of women who are having trouble conceiving. Large fibroids may cause infertility impairing the uterine lining, by blocking the fallopian tube, or by distorting the shape of the uterine cavity or altering the position of the cervix. Some evidence suggests that even small fibroids may reduce the chances of pregnancy in women who are undergoing assisted reproductive techniques. Treatments to reduce fibroids may be helpful in such women, although there has been little research on this subject.  Click the icon to see an image of uterine fibroids. Prolactin is a hormone produced in the pituitary gland that stimulates breast development and milk production in association with pregnancy. High levels of prolactin (hyperprolactinemia) reduce gonadotropin hormones and inhibit ovulation. Hyperprolactinemia in women who are not pregnant or nursing can be caused by hypothyroidism or pituitary adenomas. (These are benign tumors that secrete prolactin. They can cause headache and visual problems as well as breast secretions.) Some drugs, including oral contraceptives and some antipsychotic drugs, can also elevate levels of prolactin. Secretions from the breast not related to pregnancy or nursing (called galactorrhea) are a telltale symptom of high prolactin levels and should be investigated. Inborn Abnormalities. Inborn genital tract abnormalities may cause infertility. Mullerian agenesis is a specific malformation in which no vagina or uterus develops. Even in these cases, some women can become mothers by undergoing in vitro fertilization and having the fertilized egg implanted in another woman who is willing and able to carry the pregnancy (a surrogate mother). Uterine or Abdominal Scarring. Bands of scar tissue that bind together after abdominal or pelvic surgery or infection (called adhesions) can restrict the movement of ovaries and fallopian tubes and may cause infertility. Asherman syndrome, for example, is scarring in the uterus that can cause obstructions and secondary amenorrhea. It may be caused by surgery, repeated injury, or unknown factors. Laparoscopic surgery is less likely to cause adhesions than standard open surgery. In some of these cases, surgery may be helpful. One technique, called pressure lavage under ultrasound guidance (PLUG), may prove to be useful for treating some cases of mild scarring in the uterus (intrauterine adhesions). This technique is based on transvaginal sonohysterography, which uses ultrasound along with saline infused into the uterus to enhance visualization. Continuous accumulation of saline in the procedure is used to break up the scars. Ectopic Pregnancies. Ectopic pregnancies increase the risk for infertility, although subsequent pregnancy rates are quite variable. Ectopic pregnancies that terminate without treatment appear to pose a lower risk for future infertility. Even a ruptured tube does not appear to reduce the chance for a future pregnancy in most women. Such an event however can be dangerous and even life threatening for the woman. Laparoscopic surgery to remove a fallopian tube affected by an ectopic pregnancy may preserve fertility better than traditional abdominal surgery.  Click the icon to see an image of an ectopic pregnancy. Medications. Among the medications that can cause temporary infertility are those used to treat chronic disorders, as well as antidepressants, hormones, painkillers, and antipsychotic drugs. Inflammatory Bowel Disease. Inflammatory bowel disease (particularly Crohn's disease or surgery for ulcerative colitis) can affect fertility.  Click the icon to see an image of Crohn's disease. Celiac Sprue. Celiac sprue is a disease in which the patient cannot tolerate gluten, a common food chemical. The disorder is also highly associated with infertility in men and women, possibly through multiple effects on nutrition, immune factors, and hormones. The mechanisms are not altogether clear, but infertility is usually reversible with strict dietary control.  Click the icon to see an image of celiac sprue. Iron Intake. Nutritional iron deficiency may contribute to female infertility. According to a 2006 study, women who take iron supplements are 40% less likely to experience ovulatory infertility than women who do not take iron supplements. Some researchers suggest that screening for iron deficiency should be part of the standard work-up of infertility tests. Epilepsy. In one study of women with epilepsy, fertility rates were 33% lower than among women in the general population, perhaps due to certain antiepileptic drugs that increase the risk for birth defects. The social effects of epilepsy may also lead to marriage at an older age, which can be associated with delayed attempts to get pregnant and thereby affect fertility. Thyroid Problems. Thyroid problems, either too much thyroid hormone (hyperthyroidism) or too little (hypothyroidism), can interrupt cycles.  Click the icon to see an image of hyperthyroidism.  Click the icon to see an image of hypothyroidism. Metabolic Syndrome (also Called Syndrome X). Doctors diagnose this condition when at least three of the following abnormalities are present:
Metabolic syndrome is a pre-diabetic condition that is significantly associated with heart disease. One study reported that, as with polycystic ovarian syndrome, women with metabolic syndrome have higher levels of male hormones and are therefore at risk for infertility. Another study estimated that 24% of the population now has this condition. Other Medical Conditions. Medical conditions associated with delayed puberty and amenorrhea (absence of periods) include Cushing's disease, sickle cell disease, HIV, kidney disease, and diabetes. Genetic mutations that affect luteinizing hormone may also be responsible for some cases of light or absent menstruation. Other rare genetic disorders, such as Kallman syndrome, cause abnormalities in the hypothalamus of the brain. DiagnosisIn any fertility work-up, both male and female partners are tested if pregnancy fails to occur after a year of regular unprotected sexual intercourse. Fertility testing should be done earlier if a woman is over 35 years old or if either partner has known risk factors for infertility. An analysis of the man's semen should be performed before the female partner undergoes any invasive testing. The first step in any infertility work up is a complete medical history and physical examination. Sexual technique and timing, menstrual history, lifestyle issues (such as smoking and drug, alcohol, and caffeine consumption), any medications being taken, and a profile of the patient's general medical and emotional health can help the doctor decide on appropriate tests. Before embarking on an expensive fertility work-up, the following steps are free or low-cost and can be helpful:
Several laboratory tests may be used to detect the cause of infertility and monitor treatments: Hormonal Levels. Blood and urine tests are taken to evaluate hormone levels. Hormonal tests for ovarian reserve (the number of follicles and quality of the eggs) are especially important for older women. Examples of possible results include:
Clomiphene Challenge Test. Clomiphene citrate (Clomid, Serophene), a standard fertility drug, may be used to test for ovarian reserve. With this test, the doctor measures FSH on day 3 of the cycle. The woman takes clomiphene orally on days 5 and 9 of the cycle. The doctor measures FSH on the tenth day. High levels of FSH either on day 3 or day 10 indicate a poor chance for a successful outcome. Tissue Samples. To rule out luteal phase defect, premature ovarian failure, and absence of ovulation, the doctor may take tissue samples of the uterus 1 - 2 days before a period to determine if the corpus luteum is adequately producing progesterone. Tissue samples taken from the cervix may be cultured to rule out infection. Tests for Autoimmune Disease. Tests for autoimmune disease, such as hypothyroidism and diabetes, should be considered in women with recent ovarian failure that is not caused by genetic abnormalities. If an initial fertility work-up does not reveal abnormalities, as happens in about 40% of cases, more extensive tests will reveal abnormal tubal or uterine findings. The three major approaches for examining the uterus are ultrasound (particularly a variation called saline-infusion sonohysterography), hysterosalpingography, and hysteroscopy. Although combinations of these diagnostic approaches are often used to confirm diagnoses, one study indicated that with the introduction of saline-infusion sonohysterography, all are equally accurate and combinations do not increase accuracy. Furthermore, the ultrasound procedure is significantly less painful than the other two, suggesting that this should be the procedure of choice, if available. Ultrasound and Sonohysterography. Ultrasound is the standard imaging technique for evaluating the uterus and ovaries, detecting fibroids, ovarian cysts and tumors, and also obstructions in the urinary tract. It uses sound waves to produce an image of the organs and entails no risk and very little discomfort. Transvaginal sonohysterography uses ultrasound along with saline infused into the uterus, which enhances the visualization of the uterus. This technique is proving to be more accurate than standard ultrasound in identifying potential problems. It is currently the gold standard for diagnosing polycystic ovaries. Magnetic Resonance Imaging. Magnetic resonance imaging (MRI) gives a better image of any fibroids that might be causing bleeding, but it is expensive and not usually necessary. Hysteroscopy. Hysteroscopy is a procedure that may be used to detect the presence of endometriosis, fibroids, polyps, pelvic scar tissue, and blockage at the ends of the fallopian tubes. Some of these conditions can be corrected during the procedure by cutting away any scar tissue that may be binding organs together or by destroying endometrial implants. (It may miss cases of uterine cancer, however, and is not a substitute for more invasive procedures, such as dilation and curettage ( D&C) or endometrial biopsy, if cancer is suspected.) It is done in the office setting and requires no incisions. The procedure uses a long flexible or rigid tube called a hysteroscope, which is inserted into the vagina and through the cervix to reach the uterus. A fiber optic light source and a tiny camera in the tube allow the doctor to view the cavity. The uterus is filled with saline or carbon dioxide to inflate the cavity and provide better viewing. This frequently causes cramping. There are small risks of bleeding, infection, and reactions to anesthesia. Many patients experience temporary discomfort in the shoulders after the operation due to residual carbon dioxide that puts pressure on the diaphragm. The wound itself is minimally painful. Hysterosalpingography. Hysterosalpingography is performed to discover possible blockage in the fallopian tubes and abnormalities in the uterus:
The test has significant rates of false diagnoses, both positive and negative. There is a small risk of pelvic infection, and antibiotics may be prescribed prior to the procedure. One study suggested that flushing the tubes with an oil-based fluid (lipiodol) during this procedure may improve fertility rates in women with infertility of unknown causes. As women age, the number of follicles (and therefore their egg supply) declines. Researchers are developing tests that may help determine how many are left. Such tests include the following:
Eventually these markers may be useful for determining which women need more aggressive treatments. Genetic testing may be warranted in cases of male infertility or when genetic factors may be causing pregnancy failure in the woman. If genetic abnormalities are suspected in either partner, counseling is recommended. A technique called preimplantation genetic diagnosis (PGD) is now available in some centers that can examine all the chromosomes in a human embryo. It helps identify abnormalities that increase the risk for infertility, treatment failures, or genetic defects in the offspring. TreatmentSome doctors recommend that if a couple fails to conceive after 1 - 2 years of frequent unprotected sex, they should consult a fertility expert. Women who are 35 or older, however, may want to begin exploring their options if they do not become pregnant within 6 months to a year. Several approaches can treat infertility, depending on the cause:
Choosing a good fertility clinic is important. Those offering assisted reproductive techniques are not always regulated by the government, and abuses have been reported, including lack of informed consent, unauthorized use of embryos, and failure to routinely screen donors for disease. The clinic should always provide the following information:
Advanced fertility procedures and medications are extremely expensive and often not covered by insurance. Couples should be cautious about offers of rebates in the event of failure; the clinics offering them are often significantly more expensive than those that don't offer such gimmicks.
Lifestyle ChangesAlthough there are no dietary or nutritional cures for infertility, a healthy lifestyle is important. Ovulatory problems are reversible by changing behavioral patterns. Such conditions include:
There is no evidence of harm to a developing fetus from low exposure to microwaves or electromagnetic waves. Women who remain anxious may derive comfort by avoiding some of these devices (such as cellular phones or electric blankets) and remaining a foot or so away from others (such as computers or microwave ovens). Both male and female hormone levels fluctuate according to the time of day, and they vary from day to day and month to month. Some timing tips might be helpful. Male Hormone Levels and Sexual Activity. Male hormone levels are highest in the morning. (Sexual interest also tends to be higher in the morning.) In one study of men, their sexual activity was highest in October, when conception rates were also high. Fertility and Seasonal Changes. Different studies have reported higher sperm counts in the winter than in the summer. For women, fertility rates as measured by treatment success are highest in months when days are longest. Monitoring Basal Body Temperature. To determine the most likely time of ovulation and therefore the time of fertility, a woman is instructed to take her body temperature, called her basal body temperature. This is the body's temperature as it rises and falls in accord with hormonal fluctuations.
By studying the temperature patterns after a few months, couples can begin to anticipate ovulation and plan their sexual activity accordingly. Couples must try to avoid becoming fixated on the chart, however, in scheduling their sexual activity. Spontaneity can be lost, and the stress on the relationship can be quite severe. Hormone Monitoring Systems. A device called a saliva fertility monitor (Fertility Tracker) uses a microscope to view slides containing saliva and monitors estrogen levels. Home test kits that monitor reproductive hormone levels in the urine (ClearBlue) are also available. They are less costly than the saliva test but are messier. Monitoring hormones levels helps to determine when a woman is ovulating. Frequency of Intercourse. The question of how often a couple should have intercourse is in debate. Some doctors say that having sex more than 2 days a week adds no benefits. Moreover, frequent sexual activity lowers sperm count per ejaculation. Other studies have indicated, however, that having intercourse every day, or even several times a day, before and during ovulation, improves pregnancy rates. Although sperm count per ejaculation is low, a constantly replenished semen supply is more likely to result in a fertilized egg. The fertility process is a roller coaster of emotions that are present throughout and in both failure and success. There are almost no sure ways to predict which couples will eventually conceive. Some couples with multiple problems will overcome great odds, while other, seemingly fertile, couples fail to conceive. Many of the new treatments are remarkable, but a live birth is never guaranteed. The emotional burden on the couple is considerable, and some planning is helpful. Planning for Emotional Turmoil.
Managing Emotional Stress During the Process. Managing negative emotions can be viewed as important as medical treatment. The following are some ways women reduce stress while trying to conceive:
Managing the Emotional Effects of the Outcome. After enduring the process, the couple must face the outcome, and even a positive outcome has emotional repercussions.
MedicationsFertility drugs are often used alone as initial treatment to induce ovulation. If they fail as sole therapy, they may be used with assisted reproductive procedures or artificial insemination to produce multiple eggs, a process called superovulation. Clomiphene citrate (Clomid, Serophene) is usually the first fertility drug of choice for women with infrequent periods and long cycles. Unlike more potent drugs used in superovulation, clomiphene is gentler and works by blocking estrogen, which tricks the pituitary into producing follicle-stimulating hormone (FSH) and luteinizing hormone (LH). This boosts follicle growth and the release of the egg. Clomiphene can be taken orally, is relatively inexpensive, and the risk for multiple births (about 5%, mostly twins) is lower than with other drugs. Women with the best chances for success with this drug are those who have the following conditions:
Women with poorer chances of success with this drug have the following conditions:
One or two tablets are taken each day for 5 days, usually starting 2 - 5 days after the period starts. If successful, ovulation occurs about a week after the last pill has been taken. If ovulation does not occur, then a higher dose may be given for the next cycle. If this resgimen is not successful, treatment may be prolonged or additional drugs may be added. Doctors usually do not recommend more than 6 cycles. Clomiphene often reduces the amount and quality of cervical mucus and may cause thinning of the uterine lining. In such cases, other hormonal drugs may be given to restore thickness. Other side effects of clomiphene include ovarian cysts, hot flashes, nausea, headaches, weight gain, and fatigue. There is a 5% chance of having twins with this drug, and a slightly increased risk for miscarriage. If clomiphene does not work or is not an appropriate choice, gonadotropin drugs are a second option. Gonadotropins include several different types of drugs that contain either a combination of follicle-stimulating hormone (FSH) and luteinizing hormone (LH), or only FSH. Clomiphene works indirectly by stimulating the pituitary gland to secrete FSH, which prompts follicle production. In contrast, the gonadtropin hormones directly stimulate the ovaries to produce multiple follicles. Gonadotropins are given in a shot. (Your doctor may show you how to self-administer the injection.) Gonadotropins include:
Gonadotropin drugs are either natural compounds extracted from urine or synthetic compounds that are genetically engineered in a laboratory using recombinant DNA. Human Menopausal Gonadotropin (hMG). HMG drugs, also called menotropins, contain a mixture of both FSH and LH. These drugs (Pergonal, Repronex, Metrodin, Humegon) are all derived from the urine of postmenopausal women. HMG is administered as a series of injections 2 - 3 days after the period starts. Injections are usually given for 7 - 12 days, but the time may be extended if ovulation does not occur. In such cases, a shot of human chorionic gonadotropin (hCG) may trigger ovulation. Human Chorionic Gonadotropin (hCG). Human chorionic gonadotropin (hCG) is similar to LH. It mimics the LH surge, which stimulates the follicle to release the egg. Natural hCG drugs, derived from the urine of pregnant women, include Pregnyl, Profasi, Novarel, APL, Chorex, and Follutein. Ovidrel is the only available genetically modified hCG drug. Ovidrel has fewer side effects at the injection site, and its quality can be better controlled than the natural drugs. It is generally used after hMG or FSH to stimulate the final maturation stages of the follicles. Ovulation, if it occurs, does so about 36 - 72 hours after administration. Urofollitropin and Follitropin. Urofollitropin (Bravelle, Fertinex) is a purified form of FSH, derived from the urine of postmenopausal women. Follitropin drugs (Gonal-F, Follistim) are synthetic versions of FSH. These FSH drugs are sometimes given in combination with an hCG drug. GnRH Analogs (Agonists or Antagonists). Gonadotropin-releasing hormone (GnRH) is a hormone produced in the hypothalamus part of the brain. GnRH stimulates the pituitary gland to produce LH and FSH. GnRH analogs are synthetic drugs that are classified as either agonists or antagonists. They are similar to natural GnRH but have very different actions. While natural GnRH stimulates LH and FSH, these drugs actually prevent the LH and FSH surge that occurs right before ovulation. This action helps prevent the premature release of the eggs before they can be harvested for assisted reproductive technologies.
Women with endometriosis often have an especially hard time getting pregnant. A 2006 review suggested that GnRH agonists may help women with endometriosis quadruple their chances of becoming pregnant when the drug is used 3 - 6 months prior to in vitro fertilization (IVF) or intracytoplasmic sperm injection (ICSI). [See In-Depth Report #74: Endometriosis.] Multiple Births. Overproduction of follicles can lead to ovarian enlargement. This event increases the risk for multiple births. There is a 25% chance of multiple births (about 17% for twins and 8% for triplets and or more). Ovarian Hyperstimulation Syndrome. The most serious complication with superovulation is ovarian hyperstimulation syndrome (OHS), which is associated with the enlarged ovary (although the precise cause is unknown). This can result in dangerous fluid and electrolyte imbalances and endanger the liver and kidney. OHS is also associated with a higher risk for blood clots. In rare cases, it can be fatal. Symptoms include abdominal bloating, nausea, vomiting, and shortness of breath. Bleeding and Rupture of Ovarian Cysts. Overproduction of follicles, if unchecked, may result in bleeding and rupture of ovarian cysts. Cancer Concerns. There has been concern that clomiphene and gonadotropins may increase the risks for ovarian and breast cancer. Most evidence to date does not indicate that ovulation-stimulating drugs increase the risks for these types of cancers. However, more research needs to be done. Some studies suggest that clomiphene, which is chemically related to the breast cancer drug tamoxifen, may actually decrease the risk for breast cancer. Progesterone. Progesterone is a hormone that is produced by the body during the menstrual cycle. Progesterone drugs are sometimes given to women who have experienced frequent miscarriages (a possible sign of progesterone deficiency). A progesterone drug may also be given after egg retrieval during an in vitro fertilization (IVF) cycle to help thicken the uterine lining (endometrium) so it can better hold the egg following implantation. Aromatase Inhibitors. Aromatase inhibitors block aromatase, an enzyme that is a major source of estrogen in many major body tissues. These drugs include anastrozole (Arimidex) and letrozole (Femara). These drugs are used for treating breast cancer and are being investigated for stimulating ovulation in infertile women. Although letrozole is not approved for treatment of infertility, it has become widely used for this purpose in recent years. Some doctors were concerned that letrozole could increase the risk of birth defects. However, a major 2006 study indicated that letrozole does not increase risk to the fetus. The study compared the rate of birth defects among babies whose mothers conceived with letrozole and those who used clomiphene (the standard first-line fertility drug). Researchers found no differences in birth outcomes between the two groups. Tamoxifen. Tamoxifen (Nolvadex) is a drug known as a selective estrogen-receptor modulator (SERM). It is used to prevent breast cancer in high-risk women. Studies suggest that it may equal clomiphene in its ability to induce ovulation. It may be especially useful when used along with IVF for preserving fertility in breast cancer patients. This drug is less expensive than clomiphene, but it poses some health hazards, including a risk for blood clots and uterine cancer. Glucocorticoids. Glucocorticoids are steroid hormones that are sometimes used in combination with IVF and intracytoplasmic sperm injection (ICSI). It is thought that anti-inflammatory effect of these drugs can help make the lining of the uterus more responsive to egg implantation. However, a 2007 review indicated that glucocorticoids do not help improve pregnancy success rates and should not be used routinely with assisted reproductive technologies. Regimens to induce ovulation vary widely according to individual need. A typical procedure, involving superovulation and in vitro fertilization (IVF) may be as follows:
Natural (Unstimulated) In Vitro Fertilization Cycles. An alternative to superovulation for some couples is natural in vitro fertilization (IVF) cycles. It allows multiple, consecutive cycles of treatment. Natural IVF is far less expensive than standard hyperstimulation methods and avoids their risks, including multiple births and ovarian hyperstimulation syndrome (OHS).
The basic disadvantage to this approach is that the eggs may be released before there is a chance for them to be harvested. Women report far lower stress levels with this approach, however, even though it requires more treatment cycles. In one study, the live-birth rate was 32%. Not all women are appropriate candidates, however. Women should have regular menstrual cycles and infertility of unknown cause or associated with problems in the fallopian tubes. Pregnancy rates are still very low in older women. Clomiphene. Another gentler alternative to superovulation is the use of clomiphene before IVF, which works slightly better than unstimulated IVF. Assisted Reproductive TechnologiesAssisted reproductive technologies (ART) are medical techniques that help couples conceive. These procedures involve either:
Fertilization may occur either in the laboratory or in the uterus. In the U.S., the number of live birth deliveries from ART increased by 128% between 1996 and 2002. More than 45,000 babies are now born in the U.S. each year using assisted reproductive technologies. ART includes fertility drug treatments, artificial insemination (AI), in vitro fertilization (IVF), intracytoplasmic sperm injection (ICSI), and other procedures. Artificial insemination (AI) is the least complex of the assisted reproductive technologies and is often tried first in uncomplicated cases of infertility. AI either involves placing the sperm directly in the cervix (called intracervical insemination) or into the uterus (called intrauterine insemination, or IUI). IUI is the standard AI procedure. It is useful under the following circumstances:
Those in whom AI fails, couples with specific fertility defects, or older women may be candidates for more advanced reproductive technologies. Pregnancy Rates. A review of 45 studies reported that in unexplained infertility cases, the per-cycle pregnancy rates were 4% for intrauterine insemination (IUI) alone and 8 - 17% per cycle for IUI combined with superovulation, a procedure that uses fertility drugs to bolster egg recovery. Researchers in one study suggested IUI as a reasonable first option for many women under age 43. It is less expensive and poses less risk for multiple births than the more advanced assisted reproductive technologies (ART), such as in vitro fertilization. Although IVF procedures are more effective per cycle, couples tend to be able to afford more IUI cycles, so the pregnancy rates over time are very similar. The Artificial Insemination Procedure. The AI procedure is as follows:
The administration of fertility drugs and sperm retrieval is timed so that the process can coincide with ovulation. About 71% of assisted reproductive technologies (ART) procedures now use in vitro fertilization (IVF) with the woman's own eggs. An in vitro procedure is one that is performed in the laboratory. Advances in these procedures have dramatically increased the rate of live births. The best candidates for IVF are women with damaged fallopian tubes, and some experts believe it is a better option than attempting surgical repair. IVF is also used when infertility is unexplained or when the male partner has the infertility problem. A typical IVF procedure is as follows:
IVF success rates for the first three cycles of treatment are about equal. They then decline modestly for the fourth cycle and drop significantly after the fifth cycle. Gamete/Zygote Intrafallopian Transfer. Gamete intrafallopian transfer (GIFT) and zygote intrafallopian transfer (ZIFT) are adaptations of IVF. GIFT and ZIFT are used in unexplained female infertility and in mild male infertility. The success rates are similar to those of IVF, but a woman must have at least one functioning fallopian tube. GIFT: The procedure is as follows:
ZIFT: The procedure is as follows.
In 2002, more than 45,000 American babies were born using in vitro fertilization (IVF). Success rates have increased in all age groups (although they are still considerably lower in older than in younger women). Chances for assisted reproductive technologies (ART) success are also greater among women who do not have uterine abnormalities and have had previous successful pregnancies. Success rates are also higher or lower depending on whether the woman uses her own eggs or whether they are donated and also whether the eggs are fresh or frozen. The highest live birth rates are with donated fresh eggs (an average of 50% per transfer). The lowest rates are when a woman uses her own frozen eggs (an average of 29% per transfer). However, using frozen eggs is less expensive than fresh eggs, so a couple may be able to afford more cycles with frozen eggs. Use of Donor Eggs. Older women are more likely to use donor eggs. In a 2002 study, success rates were the same for women who used donors with an age range of 20 - 40. There were also no differences in delivery rates for recipients up to age 45. Women over 45, however, increasingly had problems with implantation, pregnancy, and delivery. Use of Frozen Eggs. Frozen eggs tend to have lower success rates because of toxins released by cells damaged in the freezing and thawing tissues. Intracytoplasmic sperm injection (ICSI) is an assisted reproductive technology used for couples when male infertility is the main problem. It involves injecting a single sperm into an egg obtained from in vitro fertilization (IVF). The procedure is very simple:
The greatest concern with this procedure has been whether it increases the risk for birth defects. However, several studies have reported no higher risks of birth defects in children born using ICSI procedures. While some studies have shown a higher number of birth defects in children conceived with ICSI, experts think that this may have more to do with the genetic background of the parents than ICSI itself. Recent research suggests that ICSI children develop normally. A 2006 study of 8-year-old children conceived with ICSI found no important differences between these children and children who were conceived naturally. A 2007 study in the New England Journal of Medicine indicated that ICSI use has increased 5-fold over the past decade, even though the proportion of men receiving treatment for male infertility has remained the same. In 1995, 11% of IVF cycles used ICSI. By 2004, 57.5% of IVF cycles used ICSI. Doctors caution that while ICSI is an important assisted reproductive technology for male infertility, it may be overused. Some doctors recommend ICSI for women who have failed prior IVF attempts or who have few or poor-quality eggs, even if their male partners have normal semen measurements. There is little evidence that ICSI helps improve pregnancy success for couples who do not have a problem with male factor infertility, according to the Society for Assisted Reproductive Technology. In Vitro Maturation. A technique called in vitro maturation allows fertilization without the use of fertility drugs. In this process, follicles are harvested a few days before ovulation. In such cases, up to 50 have already begun to mature. At this time, about 15 of these maturing follicles can be removed, out of which 2 or 3 can produce healthy embryos. Blastocyst Transfer. Blastocyst transfer is very promising. Instead of implanting the standard 2- or 3-day-old embryos in the uterus, the procedure implants blastocysts, which are more complex, 5-day-old embryos. Fewer blastocysts than embryos need to be implanted, reducing the risk for multiple births. (There is, however, a higher risk for identical twins compared to other procedures.) Offspring may be more likely to be males than females. Pregnancy rates are about 36% with a first attempt but then drop significantly. The procedure is more likely to be successful in younger than older women. Ooplasmic Transfer. Ooplasmic transfer is a controversial experimental procedure that uses the woman's own egg and a female donor's egg and the male sperm for fertilization. Genetic material from the donor's egg plus the sperm are added to the woman's own egg. This has been successful in a few cases, but studies are very early and long-term effects are unknown. Research on this and similar procedures is currently conducted outside the U.S. Complications of Assisted Reproductive TechnologiesSince assisted reproductive technology (ART) procedures have become more widespread since 1980, multiple births have significantly increased. About 35% of all ART births are multiple ones, with 4.3% being triplets or more. Multiple births increase the risk of complications, for both the mother and the child. Assisted reproductive technology (ART), and multiple births, increase the risks for pregnancy complications. According to a 2005 study, the type of complications may depend on the infertility treatment:
Multiple births can also increase the risk of pregnancy death. A 2006 study indicated that women who carry multiple fetuses have a 3.6 times greater risk of dying from pregnancy complications than women with singleton pregnancies. The leading causes of death were blood clot (embolism), high blood pressure complications, excessive bleeding (hemorrhage), and infections. The main risks for children conceived with assisted reproductive technology (ART) are complications associated with pregnancy problems and multiple births. Children conceived with ART are more likely to be born premature and to have extremely low birth weight. These conditions increase the risk for heart and lung problems, as well as learning and developmental disabilities. Premature delivery is also associated with cerebral palsy, a brain injury condition that affects muscle coordination. A 2006 study indicated that children born after in vitro fertilization have an increased risk for cerebral palsy. However, studies suggest that ART does not increase the risk for chromosomal damage or other major birth defects. Couples undergoing ART may have other factors, such as older age or genetic predispositions, which make complications more likely. Infertility itself, even without ART, can pose a risk factor for birth defects. Children conceived naturally by couples with infertility problems tended to have more disorders of the nervous system, digestive system, and musculoskeletal system than children born to fertile couples, according to a 2006 study in the British Medical Journal. Children born to couples treated for infertility with ART may also have a slightly increased risk for these problems, as well as genital organ malformations, but the overall risk for birth defects appears to be very small. ART remains a good option for many infertile couples. The likelihood of having a healthy single child of normal birth weight using ART is about 94%. The likelihood of having a child free of major birth defects is about 91%. Frozen eggs do not appear to pose any higher risk for developmental problems. Preimplantation genetic diagnosis (PGD) is now available in some fertility centers. It can help identify genetic defects in the offspring and may help parents determine future problems. Such testing, however, also raises significant emotional issues that should be addressed beforehand. Given the hazards of multiple births, parents must make some hard decisions if the treatment produces multiple embryos. The choices are limited:
At this time, the best approach is to limit the number of implanted embryos in the first place. Researchers are attempting to develop methods to reduce the risk for multiple births:
Resources
ReferencesBoomsma CM, Keay SD, Macklon NS. Peri-implantation glucocorticoid administration for assisted reproductive technology cycles. Cochrane Database Syst Rev. 2007 Jan 24;(1):CD005996. Chavarro JE, Rich-Edwards JW, Rosner BA, Willett WC. Iron intake and risk of ovulatory infertility. Obstet Gynecol. 2006 Nov;108(5):1145-52. Dieterle S, Ying G, Hatzmann W, Neuer A. Effect of acupuncture on the outcome of in vitro fertilization and intracytoplasmic sperm injection: a randomized, prospective, controlled clinical study. Fertil Steril. 2006 May;85(5):1347-51. Hvidtjorn D, Grove J, Schendel DE, Vaeth M, Ernst E, Nielsen LF, et al. Cerebral palsy among children born after in vitro fertilization: the role of preterm delivery--a population-based, cohort study. Pediatrics. 2006 Aug;118(2):475-82. Jain T, Gupta RS. Trends in the use of intracytoplasmic sperm injection in the United States. N Engl J Med. 2007 Jul 19;357(3):251-7. Jensen A, Sharif H, Svare EI, Frederiksen K, Kjaer SK. Risk of breast cancer after exposure to fertility drugs: results from a large Danish cohort study. Cancer Epidemiol Biomarkers Prev. 2007 Jul;16(7):1400-7. Epub 2007 Jun 21. Lee SJ, Schover LR, Partridge AH, Patrizio P, Wallace WH, Hagerty K, et al. American Society of Clinical Oncology recommendations on fertility preservation in cancer patients. J Clin Oncol. 2006 Jun 20;24(18):2917-31. Legro RS, Barnhart HX, Schlaff WD, Carr BR, Diamond MP, Carson SA, et al. Clomiphene, metformin, or both for infertility in the polycystic ovary syndrome. N Engl J Med. 2007 Feb 8;356(6):551-66. Mackay AP, Berg CJ, King JC, Duran C, Chang J. Pregnancy-Related Mortality Among Women With Multifetal Pregnancies. Obstet Gynecol. 2006 Mar;107(3):563-568. Ombelet W, Martens G, De Sutter P, Gerris J, Bosmans E, Ruyssinck G, et al. Perinatal outcome of 12,021 singleton and 3108 twin births after non-IVF-assisted reproduction: a cohort study. Hum Reprod. 2006 Apr;21(4):1025-32. Sallam HN, Garcia-Velasco JA, Dias S, Arici A. Long-term pituitary down-regulation before in vitro fertilization (IVF) for women with endometriosis. Cochrane Database Syst Rev. 2006 Jan 25;(1):CD004635. Shevell T, Malone FD, Vidaver J, Porter TF, Luthy DA, Comstock CH, et al. Assisted reproductive technology and pregnancy outcome. Obstet Gynecol. 2005 Nov;106(5 Pt 1):1039-45. Smith C, Coyle M, Norman RJ. Influence of acupuncture stimulation on pregnancy rates for women undergoing embryo transfer. Fertil Steril. 2006 May;85(5):1352-8. Terry KL, Willett WC, Rich-Edwards JW, Michels KB. A prospective study of infertility due to ovulatory disorders, ovulation induction, and incidence of breast cancer. Arch Intern Med. 2006 Dec 11-25;166(22):2484-9. Tulandi T, Martin J, Al-Fadhli R, Kabli N, Forman R, Hitkari J, et al. Congenital malformations among 911 newborns conceived after infertility treatment with letrozole or clomiphene citrate. Fertil Steril. 2006 Jun;85(6):1761-5. Westergaard LG, Mao Q, Krogslund M, Sandrini S, Lenz S, Grinsted J. Acupuncture on the day of embryo transfer significantly improves the reproductive outcome in infertile women: a prospective, randomized trial. Fertil Steril. 2006 May;85(5):1341-6. Zhu JL, Basso O, Obel C, Bille C, Olsen J. Infertility, infertility treatment, and congenital malformations: Danish national birth cohort. BMJ. 2006 Sep 30;333(7570):679. Epub 2006 Aug 7.
Review Date:
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