MSH-release inhibiting factor - tradução para russo
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MSH-release inhibiting factor - tradução para russo

HORMONES THAT STIMULATE OR INHIBIT RELEASE OF OTHER HORMONES
Releasing factor; Liberins; Liberin; Release hormone; Releasing hormone; Inhibiting hormone; Inhibiting hormones

MSH-release inhibiting factor      

общая лексика

фактор (гипоталамуса) угнетающий высвобождение меланоцитостимулирующего гормона

release factor         
CLASS OF PROTEINS / COMPLEXES
Prokaryotic release factors; Bacterial class I release factors; Prokaryotic release factor; Draft:Release factor; User:Abdul tameem/sandbox; Eukaryotic release factors

общая лексика

фактор высвобождения

рилизинг-фактор

time release         
  • A 54mg tablet of Concerta, which uses OROS technology.
MECHANISM THAT DELIVERS A DRUG WITH A DELAY AFTER ITS ADMINISTRATION
Slow release; Time release technology; Time Release Capsule; Sustained Release; Extended release; Continuous release; Sustained-release; Slow Release; Timed release; Timed-release; Time-release; Time release; Extended-release; Sustained release; Sustained release dosage forms; Sustained action; Time Release Technology (medicine); Delayed release (pharmacology); Time-released formula; Time released formula; Time-release formula; Time release formula; Timed release formula; Timed-release formula; Timed-released formula; Timed-released medication; Timed released medication; Timed release medication; Timed-release medication; Timed-release drug; Timed release drug; Timed released drug; Time released drug; Time release drug; Time-release drug; Extended release formula; Extended-release formula; Extended release drug; Extended-release drug; Extended release medication; Extended-release medication; Controlled-release medication; Controlled release medication; Controlled release drug; Controlled-release drug; Controlled-release formula; Controlled release formula; Continuous release formula; Continuous release drug; Continuous release medication; Modified release; Time release technology (medicine); Slow-release; Extended-release formulation; Extended release formulation; Instant release; Instant-release; Immediate-release; Immediate release; Controlled release; Depot tablet; Modified-release dosage (medicine); Time Release; Controlled-release; Targeted-release; Sustained-release dosage form; Prolonged-release; Prolonged release; Prolonged release formulation; Prolonged-release formulation; Prolonged-release form; Prolonged release form; Delayed-release (pharmacology); Delayed-release (pharmacy); Delayed release (pharmacy)

общая лексика

размыкатель с выдержкой времени

Definição

Интермедин

меланотропин, гормон средней доли Гипофиза; то же, что Меланоцитостимулирующий гормон.

Wikipédia

Releasing and inhibiting hormones

Releasing hormones and inhibiting hormones are hormones whose main purpose is to control the release of other hormones, either by stimulating or inhibiting their release. They are also called liberins () and statins () (respectively), or releasing factors and inhibiting factors. The principal examples are hypothalamic-pituitary hormones that can be classified from several viewpoints: they are hypothalamic hormones (originating in the hypothalamus), they are hypophysiotropic hormones (affecting the hypophysis, that is, the pituitary gland), and they are tropic hormones (having other endocrine glands as their target).

For example, thyrotropin-releasing hormone (TRH) is released from the hypothalamus in response to low levels of secretion of thyroid-stimulating hormone (TSH) from the pituitary gland. The TSH in turn is under feedback control by the thyroid hormones T4 and T3. When the level of TSH is too high, they feed back on the brain to shut down the secretion of TRH. Synthetic TRH is also used by physicians as a test of TSH reserve in the pituitary gland as it should stimulate the release of TSH and prolactin from this gland.

The main releasing hormones are as follows:

  • The hypothalamus uses thyrotropin-releasing hormone (TRH or thyroliberin) to tell the pituitary to release thyrotropin.
  • The hypothalamus uses corticotropin-releasing hormone (CRH or corticoliberin) to tell the pituitary to release corticotropin.
  • The hypothalamus uses gonadotropin-releasing hormone (GnRH or gonadoliberin) to tell the pituitary to release gonadotropin.
  • The hypothalamus uses growth hormone–releasing hormone (GHRH or somatoliberin) to tell the pituitary to release somatotropin.

The main release-inhibiting hormones or inhibiting hormones are as follows:

  • The hypothalamus uses somatostatin to tell the pituitary to inhibit somatotropin and to tell the gastrointestinal tract to inhibit various gastrointestinal hormones.

There are various other inhibiting factors that also have tropic endocrine inhibition activity. Such activity is only one of many functions that they have (such as neurotransmitter and receptor antagonist roles), and they are not always called hormones, although many are neuropeptides or neurosteroids. They include the following:

  • The hypothalamus uses dopamine as a prolactostatin to tell the pituitary to inhibit prolactin; it is also created elsewhere in the brain and the adrenal cortex as a neurotransmitter to affect many other systems.
  • The hypothalamus uses RFRP-3 in mammals or GnIH in avian species to inhibit GnRH.
  • The hypothalamus uses follistatin to tell the pituitary to inhibit follicle-stimulating hormone; it also has many other systemic effects.
  • Myocytes use myostatin to tell each other to inhibit myogenesis.
  • Melanocyte-inhibiting factor (melanostatin) inhibits release of other neuropeptides such as alpha-MSH and also has many other functions.
  • There is a neuropeptide called cortistatin and a class of steroidal cortistatins.

Examples of releasing and inhibiting hormones for exocrine hormones are gastrin-releasing peptide (GRP) and gastric inhibitory polypeptide (GIP), which regulate gastrin production.

Como se diz MSH-release inhibiting factor em Russo? Tradução de &#39MSH-release inhibiting factor&#3