Clinical Chemistry Lecture 2 PDF

Summary

This document is a lecture note on Clinical Chemistry, specifically focusing on the adrenal gland. It provides detailed information about the adrenal gland, its functions, and related topics. This includes the synthetic pathway of steroid hormones including cholesterol, the hypothalamic-pituitary-adrenal axis, glucocorticoids, mineralocorticoids, and adrenal androgens.

Full Transcript

Lecture: 2 Dr. Maytham Ahmed

College of Pharmacy
Fifth Stage
Clinical Chemistry

Dr. Maytham Ahmed

Lectutre 2

The Adrenal Gland
 Lecture: 2 Dr. Maytham Ahmed

The adrenal glands are divided into two functionally distinct parts. The adrenal cortex
is part of the hypothalamic-pituitary-adrenal endocrine system. The adrenal medulla
is part of the sympathetic nervous system. The adult adrenal cortex consists of three
layers that secrete steroid hormones. The outer thin layer (zona glomerulosa) secretes
only aldosterone. The inner two layers (zona fasciculata and zona reticularis) form a
functional unit and secrete cortisol and androgens. Steroid hormones are derived from
the lipid cholesterol as appeared in Figure (1).

Figure (1) Synthetic pathway of steroid hormones from cholesterol

The hypothalamic-pituitary-adrenal axis
The hypothalamus, anterior pituitary gland and adrenal cortex form a functional unit.
The hypothalamic-pituitary-adrenal axis illustrated in Figure (2). Cortisol is
synthesized and secreted in response to ACTH released from the anterior pituitary
gland. The secretion of ACTH is dependent on corticotrophin releasing hormone
 Lecture: 2 Dr. Maytham Ahmed

(CRH), released from the hypothalamus. High plasma free cortisol concentrations
suppress CRH secretion (negative feedback) and alter the ACTH response to CRH,
thus acting on both the hypothalamus and the anterior pituitary gland.

Figure (2) The hypothalamic-pituitary-adrenal axis
Glucocorticoids
Cortisol and corticosterone are naturally occurring glucocorticoids. They stimulate
gluconeogenesis and the breakdown of protein and fat, that is, they antagonize some
of insulin’s action. Glucocorticoids in excess may impair glucose tolerance and alter
the distribution of adipose tissue. Cortisol helps maintain the extracellular fluid
volume and normal blood pressure. Circulating cortisol is bound to cortisol-binding
globulin (CBG; transcortin) and to albumin. At normal concentrations, only about 5
per cent of the total is unbound and physiologically active. Cortisone is not secreted
in significant amounts by the adrenal cortex. It is biologically inactive until it has
been converted in vivo to cortisol (hydrocortisone). Glucocorticoids are conjugated
with glucuronate and sulphate in the liver to form inactive metabolites, which
because they are more water soluble than the mainly protein-bound parent hormones,
can be excreted in the urine.
Mineralocorticoids (Aldosterone)
The aldosterone is secreted from zona glomerulosa of adrenal cortex. Synthesis of the
aldosterone is controlled by the renin-angiotensin system and not normally by
 Lecture: 2 Dr. Maytham Ahmed

ACTH. Although ACTH is important for maintaining growth of the zona
glomerulosa, deficiency of ACTH does not significantly reduce output of
aldosterone. In contrast to other steroids, aldosterone is not transported in plasma
bound to specific proteins. Aldosterone stimulates the exchange of sodium for
potassium and hydrogen ions across cell membranes and its renal action is especially
important for sodium and water homeostasis. Like the glucocorticoids, it is
inactivated by hepatic conjugation and is excreted in the urine.

Adrenal androgens
The main adrenal androgens are dehydroepiandrosterone (DHEA) and
androstenedione. They promote protein synthesis. Testosterone, the most powerful
androgen, is synthesized in the testes or ovaries but not in the adrenal cortex. Most
circulating androgens, like cortisol, are protein bound, mainly to sex-hormone-
binding globulin (SHBG) and albumin. There is extensive peripheral interconversion
of adrenal and gonadal androgens and then conjugated in the liver and excreted as
glucuronides and sulphates in the urine.

Control of cortisol hormone secretion
1. Feedback control
2. Inherent rhythms (circadian rhythm): ACTH is secreted episodically, each pulse
being followed 5-10 minutes later by cortisol secretion. Plasma cortisol
concentrations are usually highest between about 07.00 and 09.00 hour and lowest
between 23.00 and 04.00 hour.
3. Physical or mental stress, may over-ride the other mechanisms and cause sustained
ACTH secretion.

Adrenocortical hyperfunction
Cushing’s syndrome
Cushing’s syndrome is mainly caused by an excess of circulating cortisol but also
other steroids such as androgens. The clinical and metabolic features may include the
following:
 Lecture: 2 Dr. Maytham Ahmed

1. Obesity, involving the trunk and face, and a characteristic round, red face.
2. Impaired glucose tolerance and hyperglycaemia. Cortisol has the opposite
action to that of insulin, causing increased gluconeogenesis, and some patients may
have diabetes mellitus.
3. Increased protein catabolism, which also increases urinary protein loss. Thus,
there is a negative nitrogen balance associated with proximal muscle wasting with
weakness, thinning of the skin and osteoporosis. The tendency to bruising and the
purple striae.
4. Hypertension, caused by urinary retention of sodium and therefore of water,
which are due to the mineralocorticoid effect of cortisol. Increased urinary potassium
loss may cause hypokalaemia and alkalosis.
5. Androgen excess, which may account for the common findings of greasy skin
with acne vulgaris and hirsutism, and menstrual disturbances in women.
6. Psychiatric disturbances, such as depression.

Causes of Cushing’s syndrome
1. One of the most common causes of Cushing’s syndrome is iatrogenic and related
to excessive steroid treatment.

2. Increased endogenous cortisol production may be due to hyperstimulation of the
adrenal gland by ACTH, either from the pituitary gland or from an ectopic source
(increase glucocorticoids and ACTH). The secretion of ACTH is increased in the
following conditions:

A. Cushing’s disease: It is associated with bilateral adrenal hyperplasia, often
secondary to a basophil adenoma of the anterior pituitary gland.

B. Ectopic ACTH secretion: In this condition, usually from a small-cell carcinoma
of the bronchus, ACTH concentrations may be high enough to cause skin
pigmentation.
 Lecture: 2 Dr. Maytham Ahmed

3. Tumours of the adrenal cortex. (Increase glucocorticoids and decrease ACTH)
The secretion of ACTH is appropriately suppressed in primary cortisol secreting
tumours of the adrenal cortex. The tumours may be benign or malignant and are
usually derived from the zona fasciculata/zona reticularis of the adrenal cortex. These
glucocorticoid secreting tumours (benign adenomas or carcinomas) do not normally
secrete aldosterone, which is produced in the zona glomerulosa layer of the adrenal
cortex. The carcinomas secrete a variety of steroids, including androgens, and thus
may cause hirsutism or virilization.

Figure (3) Excess cortisol production caused either by hyperstimulation of the adrenal
gland by adrenocorticotrophic hormone (ACTH), from either the pituitary or an
ectopic source, or by autonomous hormone secretion from an adrenal tumour.

4. Pseudo-Cushing’s
Various conditions can mimic Cushing’s syndrome and thus give false-positive
results for screening tests. The following non-Cushing’s causes of abnormal cortisol
secretion are important to remember:
A. Stress over-rides the other mechanisms controlling ACTH secretion, with loss of
the normal circadian variation of plasma cortisol and a reduced feedback response.
 Lecture: 2 Dr. Maytham Ahmed

B. Endogenous depression may be associated with sustained high plasma cortisol and
ACTH concentrations.
C. Severe alcohol abuse can cause hypersecretion of cortisol that mimics Cushing’s
syndrome clinically and biochemically. The abnormal findings revert to normal when
alcohol is stopped.
D. Severe obesity.

Investigation of Cushing’s syndrome (Table 1)
1. Plasma cortisol concentrations (morning and evening)
One of the earliest features of Cushing’s syndrome is the loss of the diurnal variation
in cortisol secretion, with high concentrations in the late evening, when secretion is
normally at a minimum.

2. Estimation of 24-hours urinary free cortisol
Only the unbound fraction of cortisol in plasma is filtered at the glomeruli and
excreted in the urine (urinary free cortisol). In Cushing’s syndrome, because of the
loss of circadian rhythm, raised plasma values are present for longer than normal and
daily urinary cortisol excretion is further increased.

3. Low-dose overnight dexamethasone suppression test
A small dose, for example 1 mg, of this synthetic steroid inhibits ACTH, and thereby
cortisol secretion by negative feedback. This is usually given at midnight and blood is
taken for cortisol assay at 09.00 hour the following morning. A normal fall in plasma
cortisol concentrations makes the diagnosis of Cushing’s syndrome very unlikely, but
failure to suppress plasma cortisol to less than 50 nmol/L does not confirm it with
certainty.

4. Plasma ACTH concentrations
Plasma ACTH is detectable only in ACTH-dependent Cushing’s syndrome
(Cushing’s disease and ectopic ACTH), and plasma concentrations are suppressed
in patients with secreting adrenocortical tumours.
 Lecture: 2 Dr. Maytham Ahmed

5. The high-dose dexamethasone suppression test
The high-dose dexamethasone suppression test may be useful. The principle of this
test is the same as that of the low-dose test described above, but a higher dose (2 mg)
given over 48 h at 6-h intervals may suppress the relatively insensitive feedback
centre of pituitary dependent Cushing’s disease (this occurs in about 90 per cent of
cases). Plasma cortisol concentration suppression by about 50 per cent is usual. In the
other two categories, ectopic ACTH production or adrenal tumours, when pituitary
ACTH is already suppressed, even this high dose will usually have no effect.

6. If there is virilization, measure plasma androgens such as testosterone and
DHEA. High concentrations suggest an adrenocortical carcinoma while benign
adenomas is a glucocorticoid-secreting tumours only.

7. The insulin tolerance or insulin stimulation test
The insulin tolerance test may be appropriate. Elevated plasma cortisol
concentrations suppress the stress response to hypoglycaemia, and this test may be of
value in differentiating Cushing’s syndrome from pseudo-Cushing’s syndrome due to
depression or obesity. This test is not without hazards due to severe hypoglycaemia.

Table (1) Some biochemical test results in patients with Cushing’s syndrome
 Lecture: 2 Dr. Maytham Ahmed

Adrenocortical hypofunction
1. Primary adrenocortical hypofunction (Addison’s disease)
Addison’s disease is caused by bilateral destruction of all zones of the adrenal
cortex, usually as the result of an autoimmune process. Tuberculosis, amyloidosis,
mycotic infections, acquired immunodeficiency syndrome (AIDS) and secondary
deposits often originating from a bronchial carcinoma. An important cause of acute
adrenal crisis is bilateral adrenal haemorrhage.

Glucocorticoid deficiency contributes to the hypotension and causes marked
sensitivity to insulin; hypoglycaemia may be a presenting feature. Sometimes
tiredness, weight loss, mild hypotension and pigmentation of the skin and buccal
mucosa may occur. Androgen deficiency is not clinically evident because
testosterone production by the testes is unimpaired in males and because androgen
deficiency does not produce obvious effects in women. The pigmentation that
develops in some cases of Addison’s disease is due to the high circulating levels of
ACTH or related peptides resulting from the lack of cortisol suppression of the
feedback mechanism. Addison’s disease is characterized by low cortisol, high
ACTH concentration, hypoglycaemia, hypotension, pigmentation, hyponatraemia
and hyperkalaemia.

2. Secondary adrenocortical hypofunction
The ACTH release may be impaired by disorders of the hypothalamus or the anterior
pituitary gland, most commonly due to a tumour, infarction, infection and surgery.
Corticosteroids suppress ACTH release and, if such drugs have been taken for a long
time, the ACTH releasing mechanism may be slow to recover after the steroid is
stopped. Patients may present with non-specific symptoms such as weight loss and
tiredness. Hypoglycaemia may occur because of marked insulin sensitivity. Unlike
primary adrenal hypofunction, pigmentation is absent because plasma ACTH
concentrations are not raised. Secondary adrenal hypofunction is characterised by low
cortisol and low ACTH concentration.
 Lecture: 2 Dr. Maytham Ahmed

Investigation of adrenocortical hypofunction
1. Plasma cortisol concentrations
The low plasma cortisol concentrations give primary indication of adrenocorticol
hypofunction. It may not distinguish between primary and secondary adrenocortical
hypofunction.

2. Plasma ACTH concentrations
Plasma ACTH is assay may be of value when inappropriately low plasma cortisol
concentrations have been found; a raised plasma ACTH concentration indicates
primary insufficiency, whereas a low ACTH concentration suggests secondary
insufficiency.

3. The tetracosactide (Synacthen) stimulation test
Synacthen has the same biological action as ACTH but, because it lacks the antigenic
part of the molecule, there is much less danger of an allergic reaction. If the plasma
cortisol concentrations are equivocal, perform a Synacthen test. Synacthen is given
by intramuscular or intravenous injection. Blood is taken for cortisol assay at baseline
(0), 30 and 60 min.
 Normally the plasma cortisol concentration increases by at least 200 nmol/L, to a
concentration of at least 580 nmol/L.
 The peak is usually at 30 min, although a steady increase at 60 min may imply
secondary adrenocortical hypofunction due to pituitary or hypothalamic disease
(delay response).
 If the plasma cortisol concentration not increased when compared with baseline,
primary adrenocortical hypofunction is more likely (no response).

4. A plasma autoantibody (adrenal antibodies), hyponatraemia, hyperkalaemia and
hypoglycaemia and are compatible with an Addisonian crisis.
 Lecture: 2 Dr. Maytham Ahmed

Primary hyperaldosteronism (Conn’s syndrome)
Primary hyperaldosteronism (PH) is considered an important cause of secondary
hypertension. The majority of cases of PH are due to adrenal aldosterone producing
adenomas (APAs), although 45 per cent of cases may be due to bilateral idiopathic
adrenal hyperplasia (IAH). There is also a genetic-familial variety of PH.

Hypertension and a hypokalaemic metabolic alkalosis in the face of kaliuria
(urinary potassium more than 20 mmol/L) are suggestive of mineralocorticoid excess
such as Conn’s syndrome. A urinary potassium is thus a useful screening test. In PH,
plasma aldosterone concentration will be raised, with suppressed renin levels.