NURS 251 Pharmacology Module 4
Module 4
4.1: Introduction to Endocrinology
The endocrine system, also referred to as the hormone system, is a series of
... [Show More] glands located throughout the body that
functions to maintain homeostasis. By modulating the release of chemical messengers (hormones), the endocrine system
is able to send signals to regulate organ functions. The endocrine system is unique in that it works through hormones
that generally have a longer and slower onset and duration of action. There are actually eight endocrine glands
throughout the body including: the pineal, pituitary, thyroid, thymus, adrenal, pancreas, ovary and testis. Each of these
glands releases a hormone into the body that is responsible for regulating growth, metabolism, or reproduction. This
module will focus on select glands such as the pituitary gland, thyroid gland, and adrenal cortex and the pharmacologic
options available when they fail to work properly.
Physiology Overview
The pituitary gland is sometimes called the “master gland” because it controls many of the other glands within the
endocrine system. The pituitary gland is located in the region of the forebrain near the hypothalamus. Hormones
released from the pituitary gland work by a negative feedback loop. This means the pituitary gland releases a hormone
that signals an endocrine gland to release a subsequent hormone. The presence of this subsequent hormone then
signals back to the pituitary gland to stop releasing the original hormone.
The pituitary gland has two lobes, the anterior pituitary gland and the posterior pituitary gland. As outlined in Table 4.1,
each lobe secretes its own distinct hormones.
Table 4.1 Hormones of the Pituitary Gland
Anterior Pituitary Gland Posterior Pituitary Gland
Adrenocorticotropic Hormone (ACTH)
Follicle Stimulating Hormone (FSH)
Growth Hormone (GH)
Luteinizing Hormone (LH)
Prolactin (PH)
Thyroid Stimulating Hormone (TSH)
Antidiuretic Hormone (ADH)
Oxytocin
Pathophysiology and Related Drug Therapy
Pituitary
Generally, medications that affect the pituitary gland are being used as replacements for a hormone deficiency within
the body.
Examples of medications used to treat a pituitary hormone deficiency include (1) Somatropin (2) Octreotide, (3)
Vasopressin and (4) Desmopressin.
Somatropin- mimics the effects of growth hormone (GH) by promoting growth within the body. Typically, somatropin is
used in children to promote linear growth when they do not produce a sufficient amount of endogenous hormone on
their own.
Octreotide- inhibits GH release and is structurally similar to the body’s GH release-inhibiting factor or somatostatin. It is
useful in the treatment of severe watery diarrhea resulting from slow growing tumors because it reduces the
concentration of the protein that causes the diarrhea.
Vasopressin- is a potent vasoconstrictor and mimics the actions of the body’s antidiuretic hormone (ADH). It works by
increasing water reabsorption in the distal tubule and collecting duct of the nephron (see Module 3). This can reduce
water excretion up to 90%. It is also an especially effective vasoconstrictor in higher doses and can be used in emergency
situations when blood pressure is dropping dangerously low.
Desmopressin- is a synthetic vasopressin. As such, it also mimics ADH and works to increase water reabsorption in the
nephron. Additionally, desmopressin shows dose-dependent activity on clotting factors, making it useful in treating
certain blood disorders.
Thyroid
The thyroid gland is located in the neck and is responsible for the regulation of the body’s metabolism through the
release of three hormones: Thyroxine (T4), triiodothyronine (T3), and calcitonin. Thyroid Stimulating Hormone (TSH) is
the endogenous substance that the pituitary gland secretes to control the release of these thyroid gland hormones.
There are two main problems that can occur the thyroid gland: (1) Hypothyroidism and (2) Hyperthyroidism.
Hypothyroidism- A common condition characterized by diminished production of the thyroid hormones. Symptoms of
this condition include cold intolerance, unintentional weight gain, depression, dry brittle hair and nails, and fatigue.
Overall, think of the symptoms as a decrease in the body’s metabolism resulting in an overall slowing.
Drug Therapy- The treatment for hypothyroidism is relatively straight forward. It is to provide thyroid hormone
replacement to the patient. While there are natural and synthetic options available, the synthetic levothyroxine
(synthetic T4) is used in the majority of patients. Essentially, levothyroxine works in the same manner as the endogenous
hormones. By taking levothyroxine, the deficiency is corrected. Levothyroxine is the drug of choice in most cases due to
its predictable effects and long enough half-life to allow for once daily dosing. However, it can be impacted by food or
drugs, so it is recommended to take on an empty stomach 30-60 minutes prior to breakfast.
Hyperthyroidism- A condition characterized by excessive production of the thyroid hormones. In contrast to
hypothyroidism, hyperthyroidism causes an overall increase in the body’s metabolism. Symptoms of this condition
include diarrhea, flushing, increased appetite, muscle weakness, fatigue, palpitations, irritability, nervousness, heat
intolerance, and altered menstrual flow.
Drug Therapy- Propylthiouracil (PTU) and Methimazole are two anti-thyroid drugs available that work by inhibiting the
formation of the thyroid hormones. Two weeks of PTU therapy may be needed prior to symptom improvement. On the
other hand, Methimazole, is rarely used clinically. It is also important to note that is some cases where drug therapy is
ineffective, or the patient is unable to tolerate treatment, surgical resection of the thyroid gland is often performed. Such
a patient would be then considered to have hypothyroidism and would need thyroid hormone replacement for the rest
of their life.
Adrenal Glands
The adrenal glands are located on the upper surface of each kidney. Although there are two parts of the adrenal glands,
the adrenal medulla (the inner part) and the adrenal cortex (the outer part), the focus will be on the adrenal cortex in
this section. The hormones released by the adrenal cortex are generally referred to as corticosteroids or just steroids.
Importantly, there are two distinct types of corticosteroids: (1) glucocorticoids and (2) mineralocorticoids,
Glucocorticoids are critical to the body’s overall function and work to stimulate the production of glucose
(gluconeogenesis) and the breakdown of proteins (catabolism). When the body undergoes any type of stress including
trauma or surgery, the need for glucose increases. For tissues to be able to repair glucose is a necessary component. Two
specific glucocorticoid hormones exist and can be released in the form of either cortisol or cortisone. When there is a
deficiency in glucocorticoids, a person is said to have Addison’s disease. Conversely, when a person is producing excess
glucocorticoids, the patient is said to have Cushing’s disease.
Mineralocorticoids, such as the hormone aldosterone, are also released by the adrenal cortex. Aldosterone is critical to
the regulation of sodium and potassium as well as water in the extracellular fluid. The regulatory effects of aldosterone,
therefore, plays a role in blood pressure. The renin angiotensin system (Module 3) is a major regulator of aldosterone
secretion as is the adrenocorticotropic hormone (ACTH), although to a lesser degree.
Corticosteroids as Drug Therapy
Glucocorticoids and Mineralocorticoids are both endogenous hormones that work within the body. There are also
several synthetic versions of these hormones given through medications. The primary uses of these medications are both
as replacement therapy (as in Addison’s disease), but also in the treatment of inflammatory or allergic conditions.
Glucocorticoids are used more frequently clinically. Common examples of clinically useful steroids include the naturally
occurring steroids and synthetic preparations. Synthetic steroids have been altered in some way to produce greater antiinflammatory effect. The synthetic steroids also produce fewer undesirable mineralocorticoid side effects. Examples
include:
Natural Occurring Short Acting Steroids: Cortisone and Hydrocortisone
Synthetic Intermediate Acting Steroids: Methylprednisolone, Prednisolone, Prednisone, and Triamcinolone
Synthetic Long Acting Steroids: Betamethasone and Dexamethasone
Clinical Uses
Anti-inflammatory effects- The glucocorticoids work at the cellular level to bind to receptors that either activate the
production of anti-inflammatory proteins or prevent pro-inflammatory protein production. As virtually every cell in the
human body has glucocorticoid receptors, the effects of these drugs can be far reaching. Although this can be a good
thing, it also means that there are often many unwanted effects because the drugs are not limited to one site of action.
Synthetic glucocorticoids have many clinical uses. In high doses, they may be used to interrupt flares of inflammation
until another medication that is more targeted can take effect. In lower doses, they are often used to prevent flares and
protect the body from the damages of inflammation. Some of the more common glucocorticoids available and their
clinical uses, are shown in Table 4.2.
Table 4.2 Corticosteroids and corresponding indications
Adrenal Steroid Indication(s)
Fludrocortisone (Mineralocorticoid) Addison’s disease
Glucocorticoids
Budesonide nasal spray (Rhinocort) Allergic Rhinitis
Dexamethasone Allergic Disorders
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