Menstrual cycle

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Menstrual cycle MenstrualCycle2 en.svg
Menstrual cycle

The menstrual cycle is a series of natural changes in hormone production and the structures of the uterus and ovaries of the female reproductive system that makes pregnancy possible. The ovarian cycle controls the production and release of eggs and the cyclic release of estrogen and progesterone. The uterine cycle governs the preparation and maintenance of the lining of the uterus (womb) to receive an embryo. These cycles are concurrent and coordinated, normally last between 21 and 35 days, with a median length of 28 days, and continue for about 30–45 years.

Contents

Naturally occurring hormones drive the cycles; the cyclical rise and fall of the follicle stimulating hormone prompts the production and growth of oocytes (immature egg cells). The hormone estrogen stimulates the uterus lining (endometrium) to thicken to accommodate an embryo should fertilization occur. The blood supply of the thickened lining provides nutrients to a successfully implanted embryo. If implantation does not occur, the lining breaks down and blood is released. Triggered by falling progesterone levels, menstruation (a "period", in common parlance) is the cyclical shedding of the lining, and is a sign that pregnancy has not occurred.

Each cycle occurs in phases based on events either in the ovary (ovarian cycle) or in the uterus (uterine cycle). The ovarian cycle consists of the follicular phase, ovulation, and the luteal phase; the uterine cycle consists of the menstrual, proliferative and secretory phases. Day one of the menstrual cycle is the first day of the period, which lasts for about five days. Around day fourteen, an egg is usually released from the ovary. Menarche (the onset of the first period) usually occurs around the age of 12 years.

The menstrual cycle can cause some women to experience premenstrual syndrome with symptoms that may include tender breasts, and tiredness. More severe symptoms that affect daily living are classed as premenstrual dysphoric disorder, and are experienced by 3–8% of women. During the first few days of menstruation some women experience period pain that can spread from the abdomen to the back and upper thighs. The menstrual cycle can be modified by hormonal birth control.

Cycles and phases

Progression of the menstrual cycle and some of the hormones contributing to it Figure 28 02 07.jpg
Progression of the menstrual cycle and some of the hormones contributing to it

The menstrual cycle encompasses the ovarian and uterine cycles. The ovarian cycle describes changes that occur in the follicles of the ovary, [1] whereas the uterine cycle describes changes in the endometrial lining of the uterus. Both cycles can be divided into phases. The ovarian cycle consists of alternating follicular and luteal phases, and the uterine cycle consists of menstruation, the proliferative phase, and the secretory phase. [2] The menstrual cycle is controlled by the hypothalamus in the brain, and the anterior pituitary gland at the base of the brain. The hypothalamus releases gonadotropin-releasing hormone (GnRH), which causes the nearby anterior pituitary to release follicle-stimulating hormone (FSH) and luteinizing hormone (LH). Before puberty, GnRH is released in low steady quantities and at a steady rate. After puberty, GnRH is released in large pulses, and the frequency and magnitude of these determine how much FSH and LH are produced by the pituitary. [3]

Measured from the first day of one menstruation to the first day of the next, the length of a menstrual cycle varies but has a median length of 28 days. [4] The cycle is often less regular at the beginning and end of a woman's reproductive life. [4] At puberty, a child's body begins to mature into an adult body capable of sexual reproduction; the first period (called menarche) occurs at around 12 years of age and continues for about 30–45 years. [5] [6] Menstrual cycles end at menopause, which is usually between 45 and 55 years of age. [7] [8]

Ovarian cycle

Between menarche and menopause the ovaries regularly alternate between luteal and follicular phases during the monthly menstrual cycle. [9] Stimulated by gradually increasing amounts of estrogen in the follicular phase, discharges of blood flow stop and the uterine lining thickens. Follicles in the ovary begin developing under the influence of a complex interplay of hormones, and after several days one, or occasionally two, become dominant, while non-dominant follicles shrink and die. About mid-cycle, some 10–12 hours after the increase in luteinizing hormone, known as the LH surge, [4] the dominant follicle releases an oocyte, in an event called ovulation. [10]

After ovulation, the oocyte lives for 24 hours or less without fertilization, [11] while the remains of the dominant follicle in the ovary become a corpus luteum – a body with the primary function of producing large amounts of the hormone progesterone. [12] [lower-alpha 1] Under the influence of progesterone, the uterine lining changes to prepare for potential implantation of an embryo to establish a pregnancy. The thickness of the endometrium continues to increase in response to mounting levels of estrogen, which is released by the antral follicle (a mature ovarian follicle) into the blood circulation. Peak levels of estrogen are reached at around day thirteen of the cycle and coincide with ovulation. If implantation does not occur within about two weeks, the corpus luteum degenerates into the corpus albicans, which does not produce hormones, causing a sharp drop in levels of both progesterone and estrogen. This drop causes the uterus to lose its lining in menstruation; it is around this time that the lowest levels of estrogen are reached. [14]

In an ovulatory menstrual cycle, the ovarian and uterine cycles are concurrent and coordinated and last between 21 and 35 days, with a population average of 27–29 days. [15] Although the average length of the human menstrual cycle is similar to that of the lunar cycle, there is no causal relation between the two. [16]

Follicular phase

The ovaries contain a finite number of egg stem cells, granulosa cells and theca cells, which together form primordial follicles. [12] At around 20 weeks into gestation some 7 million immature eggs have already formed in an ovary. This decreases to around 2 million by the time a girl is born, and 300,000 by the time she has her first period. On average, one egg matures and is released during ovulation each month after menarche. [17] Beginning at puberty, these mature to primary follicles independently of the menstrual cycle. [18] The development of the egg is called oogenesis and only one cell survives the divisions to await fertilization. The other cells are discarded as polar bodies, which cannot be fertilized. [19] The follicular phase is the first part of the ovarian cycle and it ends with the completion of the antral follicles. [9] Meiosis (cell division) remains incomplete in the egg cells until the antral follicle is formed. During this phase usually only one ovarian follicle fully matures and gets ready to release an egg. [20] The follicular phase shortens significantly with age, lasting around 14 days in women aged 18–24 compared with 10 days in women aged 40–44. [14]

Through the influence of a rise in follicle stimulating hormone (FSH) during the first days of the cycle, a few ovarian follicles are stimulated. These follicles, which have been developing for the better part of a year in a process known as folliculogenesis, compete with each other for dominance. All but one of these follicles will stop growing, while one dominant follicle – the one that has the most FSH receptors – will continue to maturity. The remaining follicles die in a process called follicular atresia. [21] Luteinizing hormone (LH) stimulates further development of the ovarian follicle. The follicle that reaches maturity is called an antral follicle, and it contains the ovum (egg cell). [22]

The theca cells develop receptors that bind LH, and in response secrete large amounts of androstenedione. At the same time the granulosa cells surrounding the maturing follicle develop receptors that bind FSH, and in response start secreting androstenedione, which is converted to estrogen by the enzyme aromatase. The estrogen inhibits further production of FSH and LH by the pituitary gland. This negative feedback regulates levels of FSH and LH. The dominant follicle continues to secrete estrogen, and the rising estrogen levels make the pituitary more responsive to GnRH from the hypothalamus. As estrogen increases this becomes a positive feedback signal, which makes the pituitary secrete more FSH and LH. This surge of FSH and LH usually occurs one to two days before ovulation and is responsible for stimulating the rupture of the antral follicle and release of the oocyte. [18] [23]

Ovulation

An ovary about to release an egg Ovulation.jpg
An ovary about to release an egg

Around day fourteen, the egg is released from the ovary. [24] Called ovulation, this occurs when a mature egg is released from the ovarian follicles into the fallopian tube, about 10–12 hours after the peak in LH surge. [4] Typically only one of the 15–20 stimulated follicles reaches full maturity, and just one egg is released. [25] Ovulation only occurs in around 10% of cycles during the first two years following menarche, and by the age of 40–50, the number of ovarian follicles is depleted. [26] LH initiates ovulation at around day 14 and stimulates the formation of the corpus luteum. [2] Following further stimulation by LH, the corpus luteum produces and releases estrogen, progesterone, relaxin (which relaxes the uterus by inhibiting contractions of the myometrium), and inhibin (which inhibits further secretion of FSH). [27]

The release of LH matures the egg and weakens the follicle wall in the ovary, causing the fully developed follicle to release its oocyte. [28] If it is fertilized by a sperm, the oocyte promptly matures into an ootid, which blocks the other sperm cells and becomes a mature egg. If it is not fertilized by a sperm, the oocyte degenerates. The mature egg has a diameter of about 0.1 mm (0.0039 in), [29] and is the largest human cell. [30]

Which of the two ovaries – left or right – ovulates appears random; [31] no left and right coordinating process is known. [32] Occasionally both ovaries release an egg; if both eggs are fertilized, the result is fraternal twins. [33] After release from the ovary, the egg is swept into the fallopian tube by the fimbria – a fringe of tissue at the end of each fallopian tube. After about a day, an unfertilized egg disintegrates or dissolves in the fallopian tube, and a fertilized egg reaches the uterus in three to five days. [34]

Fertilization usually takes place in the ampulla, the widest section of the fallopian tubes. A fertilized egg immediately starts the process of embryonic development. The developing embryo takes about three days to reach the uterus, and another three days to implant into the endometrium. It has reached the blastocyst stage at the time of implantation: this is when pregnancy begins. [35] The loss of the corpus luteum is prevented by fertilization of the egg. The syncytiotrophoblast (the outer layer of the resulting embryo-containing blastocyst that later becomes the outer layer of the placenta) produces human chorionic gonadotropin (hCG), which is very similar to LH and preserves the corpus luteum. During the first few months of pregnancy, the corpus luteum continues to secrete progesterone and estrogens at slightly higher levels than those at ovulation. After this and for the rest of the pregnancy, the placenta secretes high levels of these hormones – along with human chorionic gonadotropin (hCG), which stimulates the corpus luteum to secrete more progesterone and estrogens, blocking the menstrual cycle. [36] These hormones also prepare the mammary glands for milk [lower-alpha 2] production. [36]

Luteal phase

Lasting about 14 days, [4] the luteal phase is the final phase of the ovarian cycle and it corresponds to the secretory phase of the uterine cycle. During the luteal phase, the pituitary hormones FSH and LH cause the remaining parts of the dominant follicle to transform into the corpus luteum, which produces progesterone. [38] [lower-alpha 3] The increased progesterone starts to induce the production of estrogen. The hormones produced by the corpus luteum also suppress production of the FSH and LH that the corpus luteum needs to maintain itself. The level of FSH and LH fall quickly, and the corpus luteum atrophies. [40] Falling levels of progesterone trigger menstruation and the beginning of the next cycle. From the time of ovulation until progesterone withdrawal has caused menstruation to begin, the process typically takes about two weeks. For an individual woman, the follicular phase often varies in length from cycle to cycle; by contrast, the length of her luteal phase will be fairly consistent from cycle to cycle at 10 to 16 days (average 14 days). [14]

Uterine cycle

The anatomy of the uterus Illu cervix.svg
The anatomy of the uterus

The uterine cycle has three phases: menses, proliferative and secretory. [41]

Menstruation

Menstruation (also called menstrual bleeding, menses or a period) is the first and most evident phase of the uterine cycle and first occurs at puberty. Called menarche, the first period occurs at the age of around twelve or thirteen years. [8] The average age is generally later in the developing world and earlier in the developed world. [42] In precocious puberty, it can occur as early as age eight years, [43] and this can still be normal. [44] [45]

Menstruation is initiated each month by falling levels of estrogen and progesterone and the release of prostaglandins, [20] which constrict the spiral arteries. This causes them to spasm, contract and break up. [46] The blood supply to the endometrium is cut off and the cells of the top layer of the endometrium (the stratum functionalis) become deprived of oxygen and die. Later the whole layer is lost and only the bottom layer, the stratum basalis, is left in place. [20] An enzyme called plasmin breaks up the blood clots in the menstrual fluid, which eases the flow of blood and broken down lining from the uterus. [47] The flow of blood continues for 2–6 days and around 30–60 milliliters of blood is lost, [15] and is a sign that pregnancy has not occurred. [48]

The flow of blood normally serves as a sign that a woman has not become pregnant, but this cannot be taken as certainty, as several factors can cause bleeding during pregnancy. [49] Menstruation occurs on average once a month from menarche to menopause, which corresponds with a woman's fertile years. The average age of menopause in women is 52 years, and it typically occurs between 45 and 55 years of age. [50] Menopause is preceded by a stage of hormonal changes called perimenopause. [7]

Eumenorrhea denotes normal, regular menstruation that lasts for around the first 5 days of the cycle. [24] Women who experience menorrhagia (heavy menstrual bleeding) are more susceptible to iron deficiency than the average person. [51]

Proliferative phase

During the menstrual cycle, levels of estradiol (an estrogen) vary by 200 percent. Levels of progesterone vary by over 1200 percent. Estradiol and progesterone %25 changes across the menstrual cycle.tif
During the menstrual cycle, levels of estradiol (an estrogen) vary by 200 percent. Levels of progesterone vary by over 1200 percent.

The proliferative phase is the second phase of the uterine cycle when estrogen causes the lining of the uterus to grow and proliferate. [40] The latter part of the follicular phase overlaps with the proliferative phase of the uterine cycle. [31] As they mature, the ovarian follicles secrete increasing amounts of estradiol, an estrogen. The estrogens initiate the formation of a new layer of endometrium in the uterus with the spiral arterioles. [2]

As estrogen levels increase, cells in the cervix produce a type of cervical mucus [53] that has a higher pH and is less viscous than usual, rendering it more friendly to sperm. [54] This increases the chances of fertilization, which occurs around day 11 to day 14. [11] This cervical mucus can be detected as a vaginal discharge that is copious and resembles raw egg whites. [55] For women who are practicing fertility awareness, it is a sign that ovulation may be about to take place, [55] but it does not mean ovulation will definitely occur. [15]

Secretory phase

The secretory phase is the final phase of the uterine cycle and it corresponds to the luteal phase of the ovarian cycle. During the secretory phase, the corpus luteum produces progesterone, which plays a vital role in making the endometrium receptive to the implantation of a blastocyst (a fertilized egg, which has begun to grow). [56] Glycogen, lipids, and proteins are secreted into the uterus [57] and the cervical mucus thickens. [58] In early pregnancy, progesterone also increases blood flow and reduces the contractility of the smooth muscle in the uterus [22] and raises basal body temperature. [59]

If pregnancy does not occur the ovarian and uterine cycles start over again. [47]

Anovulatory cycles and short luteal phases

Only two-thirds of overtly normal menstrual cycles are ovulatory, that is, cycles in which ovulation occurs. [15] The other third lack ovulation or have a short luteal phase (less than ten days [60] ) in which progesterone production is insufficient for normal physiology and fertility. [61] Cycles in which ovulation does not occur (anovulation) are common in girls who have just begun menstruating and in women around menopause. During the first two years following menarche, ovulation is absent in around half of cycles. Five years after menarche, ovulation occurs in around 75% of cycles and this reaches 80% in the following years. [62] Anovulatory cycles are often overtly identical to normally ovulatory cycles. [63] Any alteration to balance of hormones can lead to anovulation. Stress, anxiety and eating disorders can cause a fall in GnRH, and a disruption of the menstrual cycle. Chronic anovulation occurs in 6–15% of women during their reproductive years. Around menopause, hormone feedback dysregulation leads to anovulatory cycles. Although anovulation is not considered a disease, it can be a sign of an underlying condition such as polycystic ovary syndrome. [64] Anovulatory cycles or short luteal phases are normal when women are under stress or athletes increasing the intensity of training. These changes are reversible as the stressors decrease or, in the case of the athlete, as she adapts to the training. [60]

Menstrual health

A human primary ovarian follicle viewed by microscopy. The round oocyte stained red in the center is surrounded by a layer of granulosa cells, which are enveloped by the basement membrane and theca cells. The magnification is around 1000 times. (H&E stain) Human ovarian follicle.jpg
A human primary ovarian follicle viewed by microscopy. The round oocyte stained red in the center is surrounded by a layer of granulosa cells, which are enveloped by the basement membrane and theca cells. The magnification is around 1000 times. (H&E stain)

Although a normal and natural process, [65] some women experience premenstrual syndrome with symptoms that may include acne, tender breasts, and tiredness. [66] More severe symptoms that affect daily living are classed as premenstrual dysphoric disorder and are experienced by 3 to 8% of women. [4] [67] [66] [68] Dysmenorrhea (menstrual cramps or period pain) is felt as painful cramps in the abdomen that can spread to the back and upper thighs during the first few days of menstruation. [69] [70] [71] Debilitating period pain is not normal and can be a sign of something severe such as endometriosis. [72] These issues can significantly affect a woman's health and quality of life and timely interventions can improve the lives of these women. [73]

There are common culturally communicated misbeliefs that the menstrual cycle affects women's moods, causes depression or irritability, or that menstruation is a painful, shameful or unclean experience. Often a woman's normal mood variation is falsely attributed to the menstrual cycle. Much of the research is weak, but there appears to be a very small increase in mood fluctuations during the luteal and menstrual phases, and a corresponding decrease during the rest of the cycle. [74] Changing levels of estrogen and progesterone across the menstrual cycle exert systemic effects on aspects of physiology including the brain, metabolism, and musculoskeletal system. The result can be subtle physiological and observable changes to women's athletic performance including strength, aerobic, and anaerobic performance. [75]

Changes to the brain have also been observed throughout the menstrual cycle [76] but do not translate into measurable changes in intellectual achievement – including academic performance, problem-solving, memory, and creativity. [77] Improvements in spatial reasoning ability during the menstruation phase of the cycle are probably caused by decreases in levels of estrogen and progesterone. [74]

In some women, ovulation features a characteristic pain [lower-alpha 4] called mittelschmerz (a German term meaning middle pain). The cause of the pain is associated with the ruptured follicle, causing a small amount of blood loss. [20]

Even when normal, the changes in hormone levels during the menstrual cycle can increase the incidence of disorders such as autoimmune diseases, [81] which might be caused by estrogen enhancement of the immune system. [4]

Around 40% of women with epilepsy find that their seizures occur more frequently at certain phases of their menstrual cycle. This catamenial epilepsy may be due to a drop in progesterone if it occurs during the luteal phase or around menstruation, or a surge in estrogen if it occurs at ovulation. Women who have regular periods can take medication just before and during menstruation. Options include progesterone supplements, increasing the dose of their regular anticonvulsant drug, or temporarily adding an anticonvulsant such as clobazam or acetazolamide. If this is ineffective, or when a woman's menstrual cycle is irregular, then treatment is to stop the menstrual cycle occurring. This may be achieved using medroxyprogesterone, triptorelin or goserelin, or by sustained use of oral contraceptives. [82] [83]

Hormonal contraception

Hormonal contraceptives prevent pregnancy by inhibiting the secretion of the hormones, FSH, LH and GnRH. Hormonal contraception that contains estrogen, such as combined oral contraceptive pills (COCPs), stop the development of the dominant follicle and the mid-cycle LH surge and thus ovulation. [84] Sequential dosing and discontinuation of the COCP can mimic the uterine cycle and produce bleeding that resembles a period. In some cases, this bleeding is lighter. [85]

Progestin-only methods of hormonal contraception do not always prevent ovulation but instead work by stopping the cervical mucus from becoming sperm-friendly. Hormonal contraception is available in a variety of forms such as pills, patches, skin implants and hormonal intrauterine devices (IUDs). [86]

Evolution and other species

Most female mammals have an estrous cycle, but only ten primate species, four bat species, the elephant shrews and the Cairo spiny mouse (Acomys cahirinus) have a menstrual cycle. [87] [88] The cycles are the same as in humans apart from the length, which ranges from 9 to 37 days. [89] [87] The lack of immediate relationship between these groups suggests that four distinct evolutionary events have caused menstruation to arise. [90] In species that have a menstrual cycle, ovulation is not obvious to potential mates and there is no mating season. [91] [92] There are four theories on the evolutionary significance of menstruation: [90]

  1. Control of sperm-borne pathogens. [93] [94] [95] This hypothesis held that menstruation protected the uterus against pathogens introduced by sperm. Hypothesis 1 does not take into account that copulation can take place weeks before menstruation and that potentially infectious semen is not controlled by menstruation in other species. [90]
  2. Energy conservation. [94] [96] This hypothesis claimed that it took less energy to rebuild a uterine lining than to maintain it if pregnancy did not occur. Hypothesis 2 does not explain other species that also do not maintain a uterine lining but do not menstruate. [90]
  3. A theory based on spontaneous decidualization (a process that results in significant changes to cells of the endometrium in preparation for, and during, pregnancy, in which the endometrium changes into the decidua). Decidualization leads to the development of the endothelium, which involves cells of the immune system, [89] the formation of a new blood supply, hormones and tissue differentiation. In non-menstruating mammals, decidualization is driven by the embryo, not the mother. [94] It evolved in some placental mammals because it confers advantages in that it allows females to prepare for pregnancy without needing a signal from the fetus. [90] Hypothesis 3 defers to an explanation of the evolutionary origin of spontaneous decidualization and does not explain the evolution of menstruation alone. [90]
  4. Uterine pre-conditioning. [97] This hypothesis claims that a monthly pre-conditioning of the uterus is needed in species, such as humans, that have deeply invasive (deep-rooted) placentas. In the process leading to the formation of a placenta, maternal tissues are invaded. This hypothesis holds that menstruation was not evolutionary, rather the result of a coincidental pre-conditioning of the uterus to protect uterine tissue from the deeply rooting placenta, in which a thicker endometrium develops. [97] Hypothesis 4 does not explain menstruation in non-primates. [90]

Notes

  1. Progesterone levels exceed those of estrogen (estradiol) by a hundred-fold. [13]
  2. Breastfeeding women can experience complete suppression of follicular development, follicular development but no ovulation, or resumption of normal menstrual cycles. [37]
  3. In the corpus luteum, cholesterol side-chain cleavage enzyme converts cholesterol to pregnenolone, which is converted to progesterone. [39]
  4. Uncharacteristic mid-cycle pain may be caused by medical conditions such as ectopic pregnancy or ruptured ovarian cyst [78] [79] or may be confused with appendicitis. [80]

Related Research Articles

<span class="mw-page-title-main">Endometrium</span> Inner mucous membrane of the mammalian uterus

The endometrium is the inner epithelial layer, along with its mucous membrane, of the mammalian uterus. It has a basal layer and a functional layer: the basal layer contains stem cells which regenerate the functional layer. The functional layer thickens and then is shed during menstruation in humans and some other mammals, including other apes, Old World monkeys, some species of bat, the elephant shrew and the Cairo spiny mouse. In most other mammals, the endometrium is reabsorbed in the estrous cycle. During pregnancy, the glands and blood vessels in the endometrium further increase in size and number. Vascular spaces fuse and become interconnected, forming the placenta, which supplies oxygen and nutrition to the embryo and fetus. The speculated presence of an endometrial microbiota has been argued against.

<span class="mw-page-title-main">Ovulation</span> Release of egg cells from the ovaries

Ovulation is the release of eggs from the ovaries. In women, this event occurs when the ovarian follicles rupture and release the secondary oocyte ovarian cells. After ovulation, during the luteal phase, the egg will be available to be fertilized by sperm. In addition, the uterine lining (endometrium) is thickened to be able to receive a fertilized egg. If no conception occurs, the uterine lining as well as the egg will be shed during menstruation.

Amenorrhea is the absence of a menstrual period in a female who has reached reproductive age. Physiological states of amenorrhoea are seen, most commonly, during pregnancy and lactation (breastfeeding). Outside the reproductive years, there is absence of menses during childhood and after menopause.

<span class="mw-page-title-main">Luteinizing hormone</span> Gonadotropin secreted by the adenohypophysis

Luteinizing hormone is a hormone produced by gonadotropic cells in the anterior pituitary gland. The production of LH is regulated by gonadotropin-releasing hormone (GnRH) from the hypothalamus. In females, an acute rise of LH known as an LH surge, triggers ovulation and development of the corpus luteum. In males, where LH had also been called interstitial cell–stimulating hormone (ICSH), it stimulates Leydig cell production of testosterone. It acts synergistically with follicle-stimulating hormone (FSH).

<span class="mw-page-title-main">Corpus luteum</span> Temporary endocrine structure in ovaries

The corpus luteum is a temporary endocrine structure in female ovaries involved in the production of relatively high levels of progesterone, and moderate levels of estradiol, and inhibin A. It is the remains of the ovarian follicle that has released a mature ovum during a previous ovulation.

<span class="mw-page-title-main">Oogenesis</span> Egg cell production process

Oogenesis, ovogenesis, or oögenesis is the differentiation of the ovum into a cell competent to further develop when fertilized. It is developed from the primary oocyte by maturation. Oogenesis is initiated in the embryonic stage.

Anovulation is when the ovaries do not release an oocyte during a menstrual cycle. Therefore, ovulation does not take place. However, a woman who does not ovulate at each menstrual cycle is not necessarily going through menopause. Chronic anovulation is a common cause of infertility.

An anovulatory cycle is a menstrual cycle characterised by the absence of ovulation and a luteal phase. It may also vary in duration from a regular menstrual cycle.

The estrous cycle is a set of recurring physiological changes induced by reproductive hormones in females of mammalian subclass Theria. Estrous cycles start after sexual maturity in females and are interrupted by anestrous phases, otherwise known as "rest" phases, or by pregnancies. Typically, estrous cycles repeat until death. These cycles are widely variable in duration and frequency depending on the species. Some animals may display bloody vaginal discharge, often mistaken for menstruation. Many mammals used in commercial agriculture, such as cattle and sheep, may have their estrous cycles artificially controlled with hormonal medications for optimum productivity. The male equivalent, seen primarily in ruminants, is called rut.

<span class="mw-page-title-main">Folliculogenesis</span> Process of maturation of primordial follicles

In biology, folliculogenesis is the maturation of the ovarian follicle, a densely packed shell of somatic cells that contains an immature oocyte. Folliculogenesis describes the progression of a number of small primordial follicles into large preovulatory follicles that occurs in part during the menstrual cycle.

<span class="mw-page-title-main">Hypothalamic–pituitary–gonadal axis</span> Concept of regarding the hypothalamus, pituitary gland and gonadal glands as a single entity

The hypothalamic–pituitary–gonadal axis refers to the hypothalamus, pituitary gland, and gonadal glands as if these individual endocrine glands were a single entity. Because these glands often act in concert, physiologists and endocrinologists find it convenient and descriptive to speak of them as a single system.

Luteolysis is the structural and functional degradation of the corpus luteum, which occurs at the end of the luteal phase of both the estrous and menstrual cycles in the absence of pregnancy.

<span class="mw-page-title-main">Luteal phase</span> The latter part of the menstrual cycle associated with ovulation and an increase in progesterone

The menstrual cycle is on average 28 days in length. It begins with menses during the follicular phase, followed by ovulation and ending with the luteal phase. Unlike the follicular phase which can vary in length among individuals, the luteal phase is typically fixed at approximately 14 days and is characterized by changes to hormone levels, such as an increase in progesterone and estrogen levels, decrease in gonadotropins such as follicle-stimulating hormone (FSH) and luteinizing hormone (LH), changes to the endometrial lining to promote implantation of the fertilized egg, and development of the corpus luteum. In the absence of fertilization by sperm, the corpus luteum degenerates leading to a decrease in progesterone and estrogen, an increase in FSH and LH, and shedding of the endometrial lining (menses) to begin the menstrual cycle again.

<span class="mw-page-title-main">Follicular phase</span> Phase of the estrous or menstrual cycle

The follicular phase, also known as the preovulatory phase or proliferative phase, is the phase of the estrous cycle during which follicles in the ovary mature from primary follicle to a fully mature graafian follicle. It ends with ovulation. The main hormones controlling this stage are secretion of gonadotropin-releasing hormones, which are follicle-stimulating hormones and luteinising hormones. They are released by pulsatile secretion. The duration of the follicular phase can differ depending on the length of the menstrual cycle, while the luteal phase is usually stable, does not really change and lasts 14 days.

Controlled ovarian hyperstimulation is a technique used in assisted reproduction involving the use of fertility medications to induce ovulation by multiple ovarian follicles. These multiple follicles can be taken out by oocyte retrieval for use in in vitro fertilisation (IVF), or be given time to ovulate, resulting in superovulation which is the ovulation of a larger-than-normal number of eggs, generally in the sense of at least two. When ovulated follicles are fertilised in vivo, whether by natural or artificial insemination, there is a very high risk of a multiple pregnancy.

Poor ovarian reserve is a condition of low fertility characterized by 1): low numbers of remaining oocytes in the ovaries or 2) possibly impaired preantral oocyte development or recruitment. Recent research suggests that premature ovarian aging and premature ovarian failure may represent a continuum of premature ovarian senescence. It is usually accompanied by high FSH levels.

Hypomenorrhea or hypomenorrhoea, also known as short or scanty periods, is extremely light menstrual blood flow. It is the opposite of heavy periods or hypermenorrhea which is more properly called menorrhagia.

<span class="mw-page-title-main">Fertility testing</span>

Fertility testing is the process by which fertility is assessed, both generally and also to find the "fertile window" in the menstrual cycle. General health affects fertility, and STI testing is an important related field.

Gonadotropin surge-attenuating factor (GnSAF) is a nonsteroidal ovarian hormone produced by the granulosa cells of small antral ovarian follicles in females. GnSAF is involved in regulating the secretion of luteinizing hormone (LH) from the anterior pituitary and the ovarian cycle. During the early to mid-follicular phase of the ovarian cycle, GnSAF acts on the anterior pituitary to attenuate LH release, limiting the secretion of LH to only basal levels. At the transition between follicular and luteal phase, GnSAF bioactivity declines sufficiently to permit LH secretion above basal levels, resulting in the mid-cycle LH surge that initiates ovulation. In normally ovulating women, the LH surge only occurs when the oocyte is mature and ready for extrusion. GnSAF bioactivity is responsible for the synchronised, biphasic nature of LH secretion.

Ovarian follicle dominance is the process where one or more follicles are selected per cycle to ovulate.

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