fisiologi siklus haid(dr.kanadi sumapraja
TRANSCRIPT
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Division of Reproductive Immunoendocrinology Department of Obstetrics and Gynecology Faculty of
Medicine University of Indonesia
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Which organ involved in Which organ involved in menstrual cycle menstrual cycle regulation ???regulation ???
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Hypothalamus
Composed of nerve cell grouped into a larged number of bundles called nuclei
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Paraventricle nucleus
Supraoptic nucleus
Paraventricle nucleus
Medial preoptic nucleus
Arcuate nucleus
Lies in the sella turcica, connected with pituitary stalk, divided to adenohypophysis, neurohypophysis, pars intermedia (avascular zone)
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Prl (prolactin)Prl (prolactin)
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Ovaries
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Uterus & Steroid receptor
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NeuroendocrinoloNeuroendocrinologygy
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Neurotransmitter
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Increased Melatonin
Decreased GnRH
Darkness
TemperaturesSleep
The role of Pineal Body
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Endorphine
Nucleus Arcuatus
DopamineNorepinephrine
GnRH pulse
AnteriorPituitary
FSHLH
Prolactin
+ -
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FolliculogenesisFolliculogenesis
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Folliculogenesis begins with the recruitment of a primordial follicle into the pool of growing follicles and ends with either ovulation or death by atresia.
In women, folliculogenesis is a very long process, requiring almost one year for a primordial follicle to grow and develop to the ovulatory stage.
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Folliculogenesis can be divided into two phases :
The first phase, termed the preantral or gonadotropin-independent phase, is characterized by the growth and differentiation of the oocyte.
The second, termed the antral (Graafian) or gonadotropin-dependent phase, is characterized by the tremendous increase of the size of the follicle itself (up to approximately 25 mm).
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The preantral phase is controlled by locally produced growth factors through autocrine/paracrine mechanisms. The second phase is regulated by FSH and LH as well as by growth factors. There is great interest in the growth factors because they can stimulate cell proliferation and modulate gonadotropin action.
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The timetable of normal folliculogenesis in women. Class 1: the preantral or gonadotropin-independent period. It takes =290 days for a recruited primordial follicle to grow to a fully-grown secondary follicle. Class 3-8: the antral (Graafian) or gonadotropin-dependent period. From cavitation or beginning antrum formation, it takes ~60 days to pass through the small (Class 2-4) medium (Class 5, 6) and large (Class 7) and preovulatory (stage 8) Graafian follicle stages. A dominant follicle is selected from a cohort of class 5 follicles. Once selected, it requires ~20 days for a dominant follicle to reach the ovulatory stage. Atresia can occur in developing follicles after the secondary stage. Number of granulosa cells (gc); days (d). (Gougeon A: Dynamics of follicular growth in the human: A model from preliminary results. Hum Reprod 1:81, 1986. Reproduced with permission from Oxford University Press.)
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2n
n2n
2n
2n2n
2n
nn
nn
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The primordial follicle
Histologically, a primordial follicle contains a small primary oocyte (~ 25µm in diameter) arrested in the dictyate stage of meiosis, a single layer of flattened or squamous granulosa cells and a basal lamina.
By virtue of the basal lamina, the granulosa and oocyte exist within a microenvironment in which direct contact with other cells does not occur.
Primordial follicles do not have an independent blood supply and thus have limited access to the endocrine system.
All primordial follicles (oocytes) are formed in the human fetus between the sixth and the ninth month of gestation . As a result, all oocytes capable of participating in reproduction during a woman's life are present in the ovaries at birth.
The number of eggs or primordial follicles in a woman's ovaries constitutes her ovary reserve (OR).
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The entry of an arrested primordial follicle into the pool of growing follicles is termed recruitment or the primordial-to-primary follicle transition.
A change in shape from squamous to cuboidal, and the acquisition of mitotic potential in the granulosa cells are histological hallmarks of recruitment. This is followed by gene activation and subsequent growth of the oocyte. Therefore, the primary mechanisms that control recruitment involve the granulosa cells and the oocyte is a responding tissue to the primary activation event
Photomicrographs of the early stages of human preantral folliculogenesis. A) Primordial follicle; arrow, squamous granulosa cell. B) Recruitment showing the primordial-to-primary transition; arrow, cuboidal granulosa cell. C) Primary follicle with multiple cuboidal granulosa cells. D) fully grown primary follicle at the primary-to-secondary transition stage; arrow, formation of a secondary layer of granulosa cells.
Recruitement
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Three activators of recruitment are known, namely, granulosa-derived kit ligand, theca-derived Bone Morphogenetic Protein-7, and high plasma levels of pituitary FSH. Müllerian Inhibiting Substance (MIS) has been found to inhibit recruitment.
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The process of recruitment continues until the pool of primordial follicles is exhausted after menopause. Recruitment of primordial follicles occurs at a relatively constant rate during the first three decades of a woman's life; however, when the OR reaches a critical number of ~25,000 at 37.5 ± 1.2 years of age, the rate of loss of primordial follicles accelerates ~2-fold. A decrease in fecundity accompanies this accelerated loss of OR. The age-related monotropic rise in plasma FSH that occurs in women after 36 years of age is believed to be involved in the acceleration of recruitment and reduced fertility. Presumably, the high concentration of plasma FSH acts to accelerate the primary-to secondary transition.
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Primary follicles
Is defined by the presence of one or more cuboidal granulosa cells that are arranged in a single layer surrounding the oocyte. The major developmental events that occur in the primary follicle include FSH receptor expression and oocyte growth and differentiation.
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Primary follicles (Cont.)
The granulosa cells express FSH receptors (15). In rodents (16), activin produced by the granulosa cells appears to play a role in stimulating the expression of FSH receptors through autocrine/paracrine mechanisms
The role of FSH ???
Erickson GF: Dissociation of Endocrine and Gametogenic Ovarian Function. In Lobo, R. (ed.): Perimenopause. Serono Symposia, Springer-Verlaag, 1997
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Primary follicles (Cont.)
During the preantral period, the oocyte increases in diameter from ~ 25µm to ~ 120µm. This enormous growth occurs as a consequence of the reactivation of the oocyte genome.
Some of the oocyte mRNAs are translated and the resulting proteins contribute to oocyte growth and differentiation. For example :
The zona pellucida (ZP) proteins, ZP-1, ZP-2, and ZP-3. The secreted ZP proteins begin to polymerize near the oocyte surface, forming the zona pellucida which eventually encapsulates the egg. ZP-3 is the species-specific sperm-binding molecule and therefore is responsible for initiating the acrosome reaction in capacitated sperm.
Growth Differentiation Factor-9 (GDF-9) and BMP-15. GDF-9 is of particular interest because studies in rodents have demonstrated that GDF-9 plays an important role in stimulating granulosa cell proliferation and theca development.
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An important event in primary follicle development is the development of gap junctions between the oocyte and granulosa cells.
Gap junctions are intercellular channels composed of proteins called connexins (Cx37) that directly couple adjacent cells allowing the diffusion of ions, metabolites, and potential signaling molecules such as cAMP and calcium.
It is believed that granulosa cells are connected to the oocyte via Cx37, and it is through these gap junctions that materials pass from the granulosa nurse cells into the oocyte.
These granulosa-derived materials are regulatory and nutrient molecules are required for oocyte growth and the acquisition of the potential to resume meiosis.
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The secondary follicle
The major changes occur during secondary follicle development include the accumulation of increased numbers of granulosa cells, and the acquisition of a theca. The development of a primary to a full-grown secondary follicle results from an active autocrine/paracrine regulatory process that involves growth factors produced by the oocyte.
A typical healthy secondary follicle. It contains a fully grown oocyte surrounded by the zona pellucida, 5 to 8 layers of granulosa cells, a basal lamina, a theca interna and externa with numerous blood vessels. (Bloom W, Fawcett DW In A Textbook of Histology. WB Saunders Company, Philadelphia 1975. With permission from Arnold.)
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The secondary follicle (Cont.)
Theca development is also accompanied by the neoformation of numerous small vessels, presumably through angiogenesis. Consequently, blood now circulates around the follicle, bringing nutrients and gonadotropins to, and waste and secretory products from, the developing follicle. At the completion of the preantral phase of folliculogenesis, a full-grown secondary follicle contains five distinct structural units: a fully grown oocyte surrounded by a zona pellucida, approximately 9 layers of granulosa cells, a basal lamina, a theca interna, a theca externa and a capillary net in the theca tissue
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The Graafian follicle
A Graafian follicle is characterized by a cavity or antrum containing a fluid termed follicular fluid or liquor folliculi.
Two proteins expressed by the follicle itself are essential for cavitation, namely granulosa-derived kit ligand and oocyte Cx 37.
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The Graafian follicle (Cont.)
Graafian follicle growth and development can be arbitrarily divided into four stages based on size. Each dominant follicle has a destiny to complete the transition from the small (1-6 mm), medium (7-11 mm), large (12-17 mm), to the preovulatory state (18-23 mm) in women. An atretic follicle usually fails to develop beyond the small to the medium stage (1-10 mm).
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The granulosa cells and oocyte are distributed as a mass of precisely shaped and precisely positioned cells. This spatial organization gives rise to four subtypes of granulosa cells: the membrana, the periantral area, the cumulus oophorus, and the corona radiata granulosa cells. All the granulosa cells express FSH receptors during Graafian follicle development; however, each group of granulosa cells is influenced by its position to express a specific differentiated state in response to FSH stimulation. For example, the membrana granulosa cells express P450arom and LH receptor whereas in the periantral area, cumulus, and corona radiata granulosa cells do not
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The theca externa consists of concentrically arranged smooth muscle cells, which are innervated by autonomic nerves. The physiological significance of the theca externa is unknown.
The theca interna contains a population of large epithelioid cells termed the theca interstitial cells. They have the ultrastructural characteristics typical of active steroid producing cells, i.e., the cytoplasm is filled with lipid droplets, smooth endoplasmic reticulum and mitochondria with tubular cristae.
The theca interstitial cells possess cell receptors for LH and insulin. In response to LH and insulin stimulation, they produce high levels of androgens, most notably androstenedione. The theca interna is richly vascularized by a loose capillary network that surrounds the Graafian follicle during its growth.
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The underlying mechanism of selection involves the secondary rise in plasma FSH. During the menstrual cycle, the secondary FSH rise in women begins a few days before plasma progesterone falls to basal levels at the end of luteal phase. FSH levels remain elevated through the first week of the follicular phase of the cycle. Increased and sustained levels of circulating FSH are obligatory for selection and female fertility. It is believed that decreased estradiol and inhibin A production by the corpus luteum (CL) are the major causes for the secondary rise in FSH and dominant follicle selection
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In mammals, 99.9% of all the follicles (oocytes) die by atresia. A fundamental property of atresia is the activation of apoptosis in the oocyte and granulosa cells.
The importance of FSH in preventing apoptosis has led to the concept that FSH is a follicle survival factor.
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Hormone Hormone regulationregulation
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The role of FSH at granulosa cell
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The role of LH at theca cell
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Two-Cell, Two-Gonadotropin system
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Cytokine involved in follicle development
• FSH stimulates production of : IGF-1 or IGF-2• IGF stimulate androgen output at theca and
aromatization to oestrogen at granulosa• FSH supress the synthesis of IGFBP and produce
protease which cleaves the IGF from its IGFBP• Capture of IGF by its binding protein would further
impair the effectiveness of FSH• Inhibin stimulates thecal androgen androgen and
granulosa aromatization, meanwhile the activin act as an opposite
• Dominant follicle : high ratios of inhibin : activin, IGF : IGFBP
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Photomicrograph showing the effects of the LH/FSH surge on egg-cumulus expansion in situ. The oocyte has resumed meiosis, the corona radiata is radiating from the zona pellucida, and the cumulus, (but not the membrana and periantral), granulosa cells have lost their attachments and appear as individual cells dispersed within the proteoglycan matrix, due to mucification
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Corpus Luteum
After ovulation, the follicle wall develops into the corpus luteum. The corpus luteum is a large endocrine gland that produces large amounts of progesterone and estradiol during the first week of the luteal phase of the cycle. There is a fibrin clot where the antrum and liquor folliculi were located, into which loose connective tissue and blood cells invade. Cells that make up the corpus luteum are contributed by the membrana granulosa, theca interna, theca externa, and invading blood tissue
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Corpus Luteum (Cont.)
The granulosa lutein cells express large amounts of StAR, P450scc, 3ß-HSD, and P450arom. Accordingly they have a high capacity to produce progesterone and estradiol. During the process of luteinization, LH is required for maintaining steroidogenesis by the granulosa lutein cells. This is also evidence that lipoproteins have potent luteotrophic effects on progesterone production
The theca-interstitial cells also are incorporated into the corpus luteum, becoming the theca-lutein cells. Theca-lutein cells also exhibit the ultrastructure of active steroid-secreting cells. They strongly express the enzymes in the androgen biosynthetic pathway and produce androstenedione.
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