Pathophysiology of Cushing's Disease

Cushing's Disease

The term "Cushing's syndrome" is used to describe a condition resulting from long-term exposure to excessive glucocorticoids. The syndrome is most commonly caused by the therapeutic administration of exogenous glucocorticoids. The term "Cushing's disease" is reserved for Cushing's syndrome that is caused by excessive secretion of adrenocorticotropin hormone (ACTH) by a pituitary tumor, usually an adenoma.

Cushing's disease is a disease in which the adrenal glands overproduce certain hormones. Another medical term for this disease is hyperadrenocorticism. The adrenal glands produce several vital substances, which regulate a variety of body functions and are necessary to sustain life. The most widely known of these substances is cortisol, commonly known as cortisone. Either deficient production or excessive production of these substances may be life-threatening. Cushing's disease is a form of Cushing's syndrome that is caused by an ACTH secreting pituitary adenoma. About 10% of pituitary adenomas secrete excess ACTH. This elevated ACTH in turn stimulates the adrenal glands to produce excess cortisol. This disease process is called Cushing's disease (named after the famous neurosurgeon, Harvey Cushing).

Cushing's disease is responsible for roughly two thirds of the cases of endogenous Cushing's syndrome. The remainder of the endogenous cases are caused by ectopic ACTH-secreting tumors and primary adrenal neoplasms. Cushing's disease occurs most frequently in women of reproductive age, but it can affect males and females of any age.

There are three mechanisms by which this disease can occur. Regardless of the cause, the clinical signs are essentially the same. It is important to identify the cause, however, because the various forms are treated differently and have different prognoses.

Pituitary gland tumor. The most common cause of Cushing's Disease (85% of all cases) is a tumor of the pituitary gland. The tumor may be either benign or malignant. The tumor causes the pituitary to overproduce a hormone, which stimulates the adrenal glands. Excessive cortisone secretion results. The pituitary tumors in Cushing's disease are usually microadenomas, which, by definition, are 10 mm or less in diameter. Microadenomas generally do not cause symptoms by local mass effect. These tumors are most often discovered when clinical manifestations of hypercortisolism resulting from hypersecretion of ACTH prompt an appropriate diagnostic work-up. Occasionally, microadenomas are found incidentally during imaging performed for other reasons.

Macroadenomas are uncommon in patients with Cushing's disease. These tumors cause mass effect when their size exceeds 15 mm in diameter. Suprasellar extension and optic chiasm compression, local bone erosion, cavernous sinus compression and panhypopituitarism may occur as a macroadenoma enlarges.

Adrenal gland tumor. Cushing's Disease may be the result of a benign or malignant tumor of the adrenal gland. If benign, surgical removal cures the disease. If malignant, surgery may help for a while, but the prognosis is less favorable than for a benign tumor.

Iatrogenic. Iatrogenic Cushing's Disease means that the excess of cortisone has resulted from excessive administration of cortisone. This may occur from oral or injectable medications. Although the injections or tablets were given for a legitimate medical reason, their excess is now detrimental.

Patients with Cushing's disease usually present with one or more signs and symptoms secondary to the presence of excess cortisol or ACTH. The clinical diagnosis must be based on the presence of one or more of these findings (Figure 1 showing Multiple wide striae on the abdomen of a patient with Cushing's disease.), because the syndrome itself has no true pathognomonic signs or symptoms.

The most common symptom is sudden weight gain. Obesity, usually with a central distribution, is the most frequent sign. Any sign or symptom of cortisol excess can develop initially, but muscle weakness, bruising, hypertension, facial rounding and plethora eventually occur. Hypertension is likely to develop in patients who are more than 40 years of age.

Cranial nerve III (oculomotor nerve) palsies are less well recognized, but they may occur in up to 25 percent of patients with pituitary macroadenomas and may be the lone presenting symptom in patients with pituitary adenomas. Pituitary tumors infrequently affect cranial nerves IV and VI. The mechanism for oculomotor palsies is usually direct compression by the expanding tumor as the nerve passes through the walls of the adjacent cavernous sinus. Noncompressive cranial nerve III paresis has also been reported in patients with Cushing's disease.

Another presentation or complication of Cushing's disease is opportunistic or bacterial infection. Immunosuppression resulting from corticosteroid excess is usually thought of as a cellular immune deficiency that increases the risk of opportunistic infections (Cryptococcus neoformans, Candida species, Norcardia species and other organisms). Eight of the 12 cases were complicated by bacterial infections. Subsequent case reports have further emphasized the frequency of bacterial infections in Cushing's disease.

A number of tests are necessary to diagnose and confirm Cushing's Disease. The primary one is the ACTH Stimulation Test. If it does not confirm the diagnosis, the Low-Dose Dexamethasone Suppression Test is performed. Other tests are needed to decide which form of the disease is present. An ultrasound examination can be a valuable part of the testing process. This permits us to visualize the adrenal gland tumor and determine its size. Although some of these tests are somewhat expensive, they are necessary.

Treatment is surgery to remove the pituitary tumor, if possible. After surgery, the pituitary may slowly start to work again and return to normal. During the recovery process, cortisol replacement treatments may be necessary. Radiation treatment of the pituitary gland may also be used. If the tumor does not respond to surgery or radiation, medications to stop the body from making cortisol are given. Untreated, Cushing's disease can cause severe illness, even death. Removal of the tumor may lead to full recovery, but the tumor can grow back.

Pathophysiology of Cushing's Disease

When stimulated by ACTH, the adrenal gland secretes cortisol and other steroid hormones. ACTH is produced by the pituitary gland and released into the petrosal venous sinuses in response to stimulation by corticotropin-releasing hormone (CRH) from the hypothalamus. ACTH is released in a diurnal pattern that is independent of circulating cortisol levels: peak release occurs just before awakening, and ACTH levels then decline throughout the day. Control of CRH and ACTH release is maintained through negative feedback by cortisol at the hypothalamic and pituitary levels. Neuronal input at the hypothalamic level can also stimulate CRH release.

Although the adenomas of Cushing's disease secrete excessive amounts of ACTH, they generally retain some negative feedback responsiveness to high doses of glucocorticoids. Ectopic sources of ACTH, usually in the form of extracranial neoplasms, are generally not responsive to negative feedback with high doses of glucocorticoids. However, some overlap exists in the response to negative feedback between pituitary and ectopic sources of excessive ACTH.

Cushing's syndrome is categorized as ACTH dependent or ACTH independent. This division is convenient for organizing the work-up of patients with suspected hypercortisolism.

Depression, alcoholism, medications, eating disorders and other conditions can cause mild clinical and laboratory findings, similar to those in Cushing's syndrome, termed "pseudo-Cushing's syndrome." The laboratory and clinical findings of hypercortisolism disappear if the primary process is successfully treated.

Dexamethasone, an exogenous glucocorticoid, is used to test for Cushing's syndrome. This gluococorticoid does not interfere with cortisol assays but induces similar physiologic responses. 

Hypothalamus - Neuroanatomy Transcription

CHAPTER 13- the hypothalamus and its connections

Hypothalamus

-          Small (about 0.3% of the total brain)

-          Controls the autonomic nervous system and the endocrine system

-          Indirectly controls body homeostasis

-          Lies in the center of the limbic system

-          Site of numerous converging and diverging neuronal pathways and through its adequate blood supply it is able to sample the blood chemistry

-          Makes appropriate controlling responses following the integration of its nervous and chemical inputs

-          Part of the diencephalon that extends from the region of the optic chiasma to the caudal border of the mammillary bodies

-          Lies below the thalamus and forms the floor and the inferior part of the lateral walls of the third ventricle

-          Caudally, the hypothalamus merges into the tegmentum of the midbrain

-          Lateral boundary is formed by the internal capsule

Preoptic area of the hypothalamus

-          Area anterior to the hypothalamus

-          Extends forward from the optic chiasma to the lamina terminalis and the anterior commissure

When observed from below, the hypothalamus is seen to be related to the following structures form anterior to posterior:

1. Optic chiasma
2. tuber cinereum and the infundibulum
3. mammillary bodies 

HYPOTHALAMIC NUCLEI

Microscopically:

-          the hypothalamus is composed of small nerve cells that are arranged in groups or nuclei, many of which are not clearly segregated from one another

Preoptic area

-          Included as part of the hypothalamus for functional reasons

• The nuclei are divided by an imaginary plane into medial and lateral zones
• Fornix and mammillothalamic tract- Lies within the plane and serves as markers

Medial Zone

The following hypothalamic nuclei are recognized from anterior to posterior:

1. Part of the preoptic nucleus
2. Anterior nucleus (merges with the preoptic nucleus) 
3. Part of the suprachiasmatic nucleus
4. Paraventricular nucleus
5. dorsomedial nucleus
6. ventromedial nucleus
7. Infundibular (arcuate) nucleus
8. Posterior nucleus

Lateral Zone

From anterior to posterior:

1. Part of the preoptic nucleus
2. Part of the suprachiasmatic nucleus
3. supraoptic nucleus
4. lateral nucleus
5. Tuberomamillary nucleus
6. The lateral tuberal nuclei

Modern technology: Histochemical, immunochemical and anterograde and retrograde tracer studies—precisely defines groups of neurons and their connections

• Most of the hypothalamic nuclei have ill-defined boundaries

Hypothalamic Lines of Communication

Hypothalamus receives information from the rest of the body through:

1. Nervous connections
2. Bloodstream
3. CSF

-          The neurons of the hypothalamic nuclei respond and exert their control via the same route

-          CSF may serve as a conduit between the neurosecretory cells of the hypothalamus and distant sites of the brain

AFFERENT NERVOUS CONNECTIONS OF THE HYPOTHALAMUS

Hypothalamus

-          Lies in the center of the limbic system

-          Receives many afferent fibers from:

o    the viscera

o   Olfactory mucous membrane

o   Cerebral cortex

o   Limbic system

• The afferent connections are numerous and complex
• Main pathways are as follows:

1. Somatic and visceral afferents
1. General somatic sensation, gustatory and visceral sensations, reach the hypothalamus through collateral branches of the lemniscal afferent fibers and the tractus solitarius and through the reticular formation
2. Visual Afferents
1. Leave the optic chiasma and pass to the suprachiasmatic nucleus
3. Olfaction
1. Travels through the medial forebrain bundle
4. Auditory afferents
1. Not been identified
5. Corticohypothalamic fibers
1. Arise from the frontal lobe of the cerebral cortex and pass directly to the hypothalamus
6. Hippocampohypothalamic fibers
1. Pass from hippocampus through the fornix to the mammillary body
2. Hypothalamus is the main output pathway of the limbic system
7. Amygdalohypothalamic fibers
1. Pass from the amygdaloid complex to the hypothalamus through the stria terminalis and by a route that passes inferior to the lentiform nucleus

8. Thalamohypothalamic fibers
1. Arise from the dorsomedial and midline thalamic nuclei
9. Tegmental fibers- arise from the midbrain

EFFERENT NERVOUS CONNECTIONS OF THE HYPOTHALAMUS

Main pathways:

1. Descending fibers to the brainstem and spinal cord
1. Influence the peripheral neurons of the ANS
2. Descend through a series of neurons in the reticular formation
3. The hypothalamus is connected to the parasympathetic nuclei of the oculomotor, facial, glossopharyngeal, and vagus nerves in the brainstem
4. The reticulospinal fibers connect the hypothalamus with sympathetic cells of origin in the lateral gray horns of the first thoracic segment to the second lumbar segment of the spinal cord and the sacral parasympathetic outflow at the level of the second, third, and fourth sacral segments of the spinal cord
2. mammillothalamic tract
1. Arises in the mammillary body
2. Terminates in the anterior nucleus of the thalamus
3. Here the pathway is relayed to the cingulated gyrus
3. mammillotegmental tract
1. Arises from the mammillary body and terminates in the cells of the reticular formation in the tegmentum of the midbrain
4. Limbic system (multiple pathways)

CONNECTIONS OF THE HYPOTHALAMUS WITH THE HYPOPHYSIS CEREBRI

-          The hypothalamus is connected to the hypophysis cerebri (pituitary gland) by 2 pathways:

1.                Nerve fibers that travel from the supraoptic and paraventricular nuclei to the posterior lobe of the hypophysis

2.                Long and short portal blood vessels that connect sinusoids in the median eminence and infundibulum with capillary plexuses in the anterior lobe of the hypophysis

-          these pathways enable the hypothalamus to influence the activities of the endocrine glands

HYPOTHALAMOHYPOPHYSEAL TRACT

Vasopressin and oxytocin

-          Synthesized in the nerve cells of the supraoptic and paraventricular nuclei

-          Passed along the axons together with carrier proteins called neurophysins, and are released at the axon terminals

·          Here the hormones are absorbed into the bloodstream in fenestrated capillaries of the posterior lobe of the hypophysis

Vasopressin

-          Antidiuretic hormone

-          Produced mainly in the nerve cells of the supraoptic nucleus

-          Function: causes vasoconstriction

-          Also has an important antidiuretic function, causing increased absorption of water in the distal convoluted tubules and collecting tubules of the kidney

Oxytocin

-          produced mainly in the paraventricular nucleus

-          Stimulates the contraction of the smooth muscle of the uterus and causes contraction of the myoepithelial cells that surround the alveoli and ducts of the breast

-          Produced in large amounts during the end of pregnancy

-          Stimulates labor contractions of the uterus

-          Stimulated by the suckling of the nipples by the babies promoting contraction of the myoepithelial cells and assists in the expression of the milk from the breasts

Supraoptic nucleus

-          Produces vasopressin

-          Act as an osmoreceptor

-          Osmotic pressure increase vasopressin increase causing reabsorption of water

Hypophyseal Portal System

Releasing hormones and release inhibitory hormones

-          produced by the neurosecretory cells situated mainly in the medial zone of the hypothalamus

-          Hormones are packaged into granules and transported along the axons of these cells in the medial eminence and infundibulum

o   Here the granules are released by exocytosis onto fenestrated capillaries at the upper end of the hypophyseal portal system

* HPS is formed from the superior hypophyseal arterty, which is a branch of the internal carotid artery

* The portal system carries the releasing hormones and the release-inhibitng hormones to the secretory cells of the anterior lobe of the hypophysis

Releasing hormones stimulate the production and release of

                - ACTH

- FSH

- LH

-Thyrotropic hormone or thyroid stimulating hormone (TSH)

- Growth hormone (GH)

Release of inhibiting hormones inhibits the release of:

-          melanocyte-stimulating hormone (MSH)

-          Luteotropic hormone (LTH)

Luteotropic hormone (LTH)

-          Also known as lactogenic hormone or prolactin

-          Stimulates the corpus luteum to secrete progesterone and the mammary gland to produce milk

Somatostatin

-          Inhibits the release of growth hormone

-          Growth hormone inhibitory hormone

Neurons of the hypothalamus

-          Influenced by the Afferent fibers passing to the hypothalamus

-          responsible for the production of the releasing hormones and the release-inhibiting hormones

-          Also influenced by the level of hormone produced by the target organ controlled by the hypophysis

-          Should the level of thyroxine in the blood fall the releasing factor for the thyrotropic hormone would be produced in increased quantities

FUNCTIONS OF THE HYPOTHALAMUS

Autonomic Control

Hypothalamus

-          Has a controlling influence on the autonomic nervous system

-          Appears to integrate the autonomic and neuroendocrine systems

-          Preserves body homeostasis

-          Regarded as a higher nervous center for control of lower autonomic centers in the brainstem and spinal cord

-          Anterior hypothalamic area and the preoptic area influence parasympathetic responses. This include:

o   Lowering of the blood pressure

o   Slowing of the heart rate

o   Contraction of the bladder

o   Increased motility of the GIT

o   Increase acidity of the gastric juice

o   Salivation

o   Pupillary constriction

-          Stimulation of the posterior and lateral nuclei causes sympathetic responses, which include:

o   Elevation of blood pressure

o   Acceleration of the heart rate

o   Cessation of persitalsis in the GIT

o   Papillary dilation

o   Hyperglycemia

ENDOCRINE CONTROL

Nerve cells of the hypothalamic nuclei

-          produces releasing factors or release-inhibiting factors

-          Control the hormone production of the anterior lobe of the hypophysis (pituitary gland)

Anterior lobe hormones include:

-          growth hormone

-          prolaction (luteotropic hormone)

-          adrenocorticotropic hormone

-          thyroid-stimulating hormone

-          luteinizing hormone

-          follicle stimulating hormone

* Some of these hormones act directly on body tissues while others such as ACTH act through an endocrine organ which in turn produces additional hormones that influence the activities of general body tissues

* Each stage is controlled by negative and positive feedback mechanisms

TEMPERATURE REGULATION

Anterior portion of the hypothalamus

-          controls those mechanisms that dissipate heat loss

-          Stimulation of this area causes dilatation of skin blood vessels and sweating, which lower the body temperature

Posterior portion of the hypothalamus

-          Stimulation results in vasoconstriction of the skin blood vessels and inhibition of sweating

-          There is shivering, in which the skeletal muscles produce heat

·         Normally, the hypothalamus sets the body temperature at 98.0-98.6f when measured orally and one degree higher when measured rectally

·         The temperature can be altered in response to extremes in environmental temperatures or in infection

REGULATION OF WATER AND FOOD INTAKE

Lateral region of the hypothalamus

-          Stimulation initiates the feeing of hunger and results in an increase in food intake

-          Referred to as the “hunger center”

-          Bilateral destruction results in anorexia with loss of body weight

Medial region

-          Simulation inhibits eating and reduces food intake

-          Referred to as the “Satiety center”

-          Bilateral destruction produces an uncontrolled voracious appetite causing extreme obesity

Thirst Center

-          Area in the lateral region of the hypothalamus that causes an immediate increase in the desire to drink water

Vasopressin (ADH)

-          Secretion is controlled by the hypothalamus controlling the osmolarity of the blood by the posterior lobe of the hypophysis

-          Causes a great increase in the reabsorption of water in the distal convoluted tubules and the collecting tubules of the kidneys

EMOTION AND BEHAVIOR

-          Function of the hypothalamus, limbic system, and the prefrontal cortex

-          The hypothalamus is the integrator of afferent information received from other areas of the nervous system and brings about the physical expression of emotion

o   Can produce an increase in the heart rate

o   Elevate the blood pressure

o   Cause dryness of the mouth

o   Flushing or pallor of the skin

o   Sweating

o   Often produce a massive peristaltic activity of the GIT

CONTROL OF CIRCADIAN RHYTHMS

-          Controlled by the hypothalamus

-          Circadian rhythms include:

o   Body temperature

o   Adrenocortical activity

o   Eosinophil count

o   Renal secretion

-          Sleeping, wakefulness, although dependent on the activities of the thalamus, limbic system, and the reticular activating system are also controlled by the hypothalamus

Lesions of the anterior part of the hypothalamus

-          Seriously interfere with the rhythm of sleeping and waking

Suprachiasmatic nucleus

-          receives afferent fibers from the retina

-          Appears to play an important role in controlling biological rhythms

-          Where nerve impulses generated in response to variations in the intensity of light are transmitted  to influence the activities of many of the hypothalamic nuclei

CLINICAL NOTES

Clinical Disorders Associated with Hypothalamic Lesions

• The hypothalamus may be the site of inflammation, neoplasm, or vascular disorder because of its deep-seated position
• Can be pressed upon by tumors of the surrounding brain tissue or may be compressed as the result of the development of internal hydrocephalus
• A lesion will produce a large number of different syndromes
• An acute lesion is more likely to produce signs and symptoms than is a slowly growing tumor

Obesity and Wasting

Severe obesity

-          Can occur as the result of hypothalamic lesions

-          Associated with genital hypoplasia or atrophy

Wasting

-          Less common

-          Severe cachexia is suggestive of damage to the hypophysis (pituitary gland)

Sexual Disorders

-          In children: there may be sexual retardation and rarely sexual precocity with hypothalamic lesions

-          After puberty: Patient with hypothalamic disease may have impotence or amenorrhea

Hyperthermia and Hypothermia

Hyperthermia    

-          Can follow lesions of the hypothalamus caused by head injury or following surgical operations in the regions of the hypothalamus

-          Otherwise normal and has no signs of malaise, which occurs with pyrexia secondary to infections

Hypothermia

-          Can follow a lesion of the hypothalamus

Diabetes Insipidus

-          Result from a lesion of the supraoptic nucleus or from the interruption of the nervous pathway to the posterior lobe of the hypophysis

-          Patient passes large volumes of urine of low specific gravity

-          Patient is extremely thirsty and drinks large quantities of fluids

-          In diabetes mellitus there is glucosuria

Disturbances of Sleep

-          frequent short periods of sleep during the waking hours or insomnia in patients with hypothalamic lesions

Emotional Disorders

-          Attacks of unexplained weeping or laughter

-          Uncontrollable rage, depressive reactions

-          Maniacal outbursts