Incidence

Adenoma derived from cells of the pars intermedia is the most common type of pituitary tumor in older horses, the second most common type in dogs, infrequent in certain strains of laboratory rats and nonhuman primates, and rare in other species. Nonbrachycephalic breeds of dogs develop adenomas in the pars intermedia more often than brachycephalic breeds.⁵

Clinical characteristics

Adenomas of the pars intermedia in dogs either are endocrinologically inactive and associated with varying degrees of hypopituitarism and diabetes insipidus or are endocrinologically active and secrete excessive ACTH, leading to bilateral adrenal cortical hyperplasia and the syndrome of cortisol excess. The clinical signs in these dogs are similar to those described previously for corticotroph adenomas of the pituitary gland. Malignancy is rare.

Two cell populations have been identified in the pars intermedia of normal dogs by immunocytochemistry.¹⁴ The predominant cell type (A cell) stains strongly for α‐MSH as in the pars intermedia of other species. A second cell type (B cell) in the canine pars intermedia stains intensely for ACTH but not for α‐MSH. This second cell population accounts for the high bioactive ACTH concentration found in the pars intermedia of dogs and most likely gives rise to corticotroph adenomas of the pars intermedia in dogs with the syndrome of cortisol excess.

The clinical syndrome associated with tumors or hyperplasia of the pars intermedia in horses (PPID; pituitary pars intermedia dysfunction) is characterized by polyuria, polydipsia, increased appetite, muscle weakness, somnolence, intermittent hyperpyrexia, and generalized hyperhidrosis (Figure 18.3A,B).¹⁵ The affected horses often develop a striking hypertrichosis (hirsutism) because of failure of the cyclic seasonal shedding of hair. The hair over most of the trunk and extremities is long (as much as 10–13 cm), abnormally thick, wavy, and often matted together (Figure 18.3A). Horses with larger tumors may have hyperglycemia (insulin‐resistant) and glycosuria, probably the result of a downregulation of insulin receptors on target cells induced by the chronic excessive intake of food and hyperinsulinemia.

The disturbances in carbohydrate metabolism and increased appetite, hirsutism, and hyperhidrosis are considered to be primarily a reflection of deranged hypothalamic function caused by the large pituitary tumors. Adenomas of the pars intermedia in affected horses often extend out of the sella turcica, expand dorsally because of the incomplete diaphragma sella, and severely compress the overlying hypothalamus (Figure 18.3C). The hypothalamus is known to be the primary center for homeostatic regulation of body temperature, appetite, and cyclic shedding of hair.

In addition to the space‐occupying effects, adenomas of the pars intermedia in horses are usually endocrinologically active but, the biochemical events in the pars intermedia lesions stimulate a unique pathogenesis with a different profile of pituitary hormones. Tumor tissue and plasma from horses with pars intermedia adenoma or hyperplasia contain high concentrations of immunoreactive peptides, such as corticotropin‐like intermediate lobe peptide (CLIP), α‐ and β‐melanocyte stimulating hormones (α‐ and β‐MSH), and β‐endorphin, which are derived from POMC and processed in the pars intermedia. POMC is a biosynthetic precursor of ACTH and other pituitary peptides and a high molecular weight (31,000–37,000 daltons) glycoprotein that undergoes different posttranslational processing in the pars distalis and intermedia (Figure 18.5). In the normal pars distalis, POMC is processed to ACTH (4500 Da), β‐lipotrophin, and γ‐lipotrophin, whereas in the normal pars intermedia POMC is cleaved into α‐MSH, CLIP (that contains amino acids 18–39 of ACTH), β‐MSH, and β‐endorphin. Plasma cortisol strongly inhibits ACTH secretion by the pars distalis, but has a much smaller effect on peptides secreted by the pars intermedia, which are under tonic dopaminergic inhibitory control.

Plasma cortisol and ACTH concentrations may be modestly elevated in horses with pars intermedia adenomas. The cortisol levels often lack the normal diurnal rhythm. The modest elevations of plasma ACTH appear to be due to the different processing of POMC in tumors derived from cells of the pars intermedia. This may explain the normal or slightly elevated blood cortisol levels and normal or mildly hyperplastic adrenal cortices observed in some horses with adenomas of the pars intermedia.¹⁶ The plasma and tumor levels of pars intermedia–derived peptides (CLIP, α‐MSH, β‐MSH, and β‐endorphin) are disproportionately elevated (40 times or more) compared to those of ACTH, apparently as the result of selective posttranslational processing of POMC similar to the normal pars intermedia. Immunoreactive peptides have been found in pars intermedia tumor extracts that have a larger molecular weight than those present in normal pituitary tissue.¹⁷ The larger peptides may be derived from improper intranuclear processing of POMC mRNA.

Horses have a marked seasonal variation in secretion of α‐MSH and ACTH from the pars intermedia. Serum concentrations of α‐MSH and ACTH are significantly greater in the autumn months. Therefore, control ranges of the hormone concentrations must be adjusted depending on the season. The sensitivity of serum α‐MSH and ACTH concentrations for diagnosis of early PPID is therefore greater in the autumn.¹⁶

Other tests that have value are endogenous ACTH, α‐MSH, thyrotropin‐releasing hormone (TRH) response test, combined hormone response tests, and measurement of ACTH after oral administration of domperidone.⁷ These tests may prove helpful in recognizing PPID in its early stages. The dexamethasone suppression test is useful for more advanced cases and it is easy to perform. Basal cortisol is not diagnostic and loss of diurnal secretion of cortisol is controversial. ACTH stimulation is not a useful test as it recognizes <20% of the cases likely because adrenocortical hyperplasia is not a prominent feature of PPID. Endogenous ACTH is also used to diagnose PPID. Using a 10–50 pg/mL reference range and a cut‐off of >55 pg/mL indicates PPID with a disease range of 104–1000 pg/mL. Variables include the cut‐off value (critical), time of day, and different reference ranges for ponies versus horses. It is imperative to use values set by the reference lab that analyzes the samples. Although this is a simple one‐collection procedure it does not recognize horses in the early stages of PPID and misses some horses in the late stages of the disease. Therefore basal ACTH is not ideal and provocative testing is recommended. Assays for ACTH should be validated for horses.

Measurement of α‐MSH may be better than ACTH in horses because MSH is produced primarily in the pars intermedia and ACTH is primarily secreted from the pars distalis. Plasma α‐MSH hormone concentration >91 pmol/L is considered diagnostic of PPID. However, there is seasonal variation in mean concentrations and ranges. Therefore additional guidelines considered diagnostic for PPID are if plasma α‐MSH is >19 pmol/L in spring, summer, or winter or is >148 pmol/L in the fall. Plasma α‐MSH and ACTH concentrations increase as daylight decreases, from maximum daylight hours to 12 hours of daylight, but serum insulin does not fluctuate. This occurs in normal horses and ponies and those with PPID, hence the season of the year should be considered when interpreting results. Ambiguous results can be repeated at a later time, even in a different season. Horses and ponies receiving pergolide (dopamine receptor agonist) have a reduced increase in α‐MSH and lower plasma ACTH. Another diagnostic approach is to measure α‐MSH after a dexamethasone suppression test (DST). An α‐MSH >90 pmol/L after a DST is the cut‐off value between normal horses and horses with PPID.

The pars intermedia is partially regulated by dopaminergic input from neurons in the hypothalamus and loss of dopaminergic inhibition is hypothesized to stimulate the pars intermedia, causing the hyperplastic lesions that lead to neoplasia and PPID syndrome. Domperidone is a synthetic benzimidazole used to treat fescue endophyte agalactia in mares and it blocks dopamine receptors. Therefore, the correct dose of domperidone should block dopamine receptors and permit melanotrophs to release the pars intermedia peptides α‐MSH, β‐endorphin, CLIP, and ACTH and the concentrations of these substances should be greater in horses with PPID than in normal horses. Basal ACTH is not consistently increased in horses with PPID; however, domperidone administration increased ACTH in horses with pituitary lesions characteristic of PPID.¹⁸

Macroscopic pathology

Adenomas of the pars intermedia in dogs produce only a moderate enlargement of the pituitary gland. The pars distalis is readily identifiable and sharply demarcated from the anterior margin of the neoplasm. The tumor may extend across the residual hypophyseal lumen and result in compression atrophy, but usually the posterior lobe is incorporated within the tumor and the infundibular stalk is intact. Degenerative changes within the neoplasm are minimal.

Adenomas of the pars intermedia in horses result in symmetrical enlargement of the hypophysis. Small adenomas often occur concurrently with nodular or diffuse hyperplasia of the pars intermedia (Figure 18.3B). Large adenomas extend out of the sella turcica and may severely compress the overlying hypothalamus (Figure 18.3C). The optic nerves are often displaced and compressed by the tumor; however, visual deficits are noted infrequently. The adenomas are yellow to white, multinodular, and incorporate the pars nervosa. On sectioning of the pituitary mass, multiple areas of hemorrhage are often present, and the pars distalis can be identified as a compressed subcapsular rim of tissue on the anterior margin (Figure 18.3D,E).

Histopathology

Adenomas of the pars intermedia in horses are partly encapsulated and sharply delineated from the compressed parenchyma of the pars distalis. The tumors are subdivided into nodules or compartments by fine septa of connective tissue that contain numerous capillaries. Areas of hemorrhage and necrosis are infrequent, although hemosiderin‐laden macrophages may be present within the connective tissue septa and pars nervosa (Figure 18.3E). The tumor cells are arranged in cords and nests along the capillaries and connective tissue septa. Tumor cells are large, cylindrical, spindle shaped or polyhedral, and have an oval hyperchromatic nucleus (Figure 18.3F). The histological pattern is often reminiscent of the prominent pars intermedia of normal horses. Cuboidal tumor cells often form follicular structures that contain dense eosinophilic colloid. In other areas the spindle‐shaped cells palisade around vessels. The cytoplasm is lightly eosinophilic and granular. Mitotic figures are uncommon. The compressed remnant of pars distalis is atrophic but contains granulated acidophils and basophils. The neurohypophysis is often infiltrated by an extension of neoplastic cells, compressed, and replaced by fibrous astrocytes and hemosiderin‐laden macrophages (Figure 18.3D,E). The hypothalamus is also compressed to varying degrees, depending upon the size of the adenoma, and has increased glial cells and a loss of nerve cell bodies. Lesions in the pars intermedia (PI) have been graded (normal, focal hyperplasia, diffuse adenomatous hyperplasia, microadenoma, and adenoma), which correlated with the circulating concentration of pituitary hormones.¹⁸

Adenomas of the pars intermedia in dogs appear to arise from the lining epithelium of the residual hypophyseal lumen covering the infundibular process. They are relatively small and more strictly localized than corticotroph (chromophobe) adenomas in dogs arising in the pars distalis. Adenomas of the pars intermedia extend across the residual hypophyseal lumen to compress the pars distalis and are sharply demarcated from the pars distalis, but they are not encapsulated. The histological appearance is strikingly different from adenomas arising in the pars distalis in that there are numerous large colloid‐filled follicles interspersed between nests of chromophobic cells of varying size (Figure 18.4A). The follicles are lined by simple columnar epithelium, which is partly ciliated and contains interspersed mucin‐secreting goblet cells. The follicular colloid is densely eosinophilic and periodic acid–Schiff (PAS) positive. The nests of cells between the follicles are primarily chromophobic, but an occasional acidophilic or basophilic cell may be present.

Endocrinologically active (ACTH‐secreting) adenomas of the pars intermedia in dogs have prominent large corticotrophs with abundant eosinophilic cytoplasm and more widely scattered follicles. Dense bands of fibrous connective tissue are occasionally interspersed between the follicles and nests of chromophobic cells, particularly in the endocrinologically inactive adenomas of the pars intermedia. Mitotic figures are observed infrequently. The neoplastic cells compress and frequently invade the pars nervosa and infundibular stalk.

Ultrastructural and immunohistochemical characteristics

Electron microscopy of adenomas of the pars intermedia in horses reveals numerous secretory granules in the cytoplasm. Their mean diameter is approximately 300 nm, and they have a closely applied limiting membrane. The rough endoplasmic reticulum and Golgi apparatus are particularly well developed.

Immunocytochemical staining of adenomas of the pars intermedia are similar to that of the non‐neoplastic equine pars intermedia.¹⁹ There is a strong diffuse cytoplasmic staining for pro‐opiomelanocortin (POMC), a moderately strong staining for α‐MSH and β‐endorphin, a weak staining for ACTH, and negative immunostaining for prolactin, glial fibrillary acidic protein, and neuron‐specific enolase (Figure 18.3G,H). The immunocytochemical findings support the biochemical studies that indicate horses with PPID develop a unique clinical syndrome that is the result of hypothalamic and neurohypophyseal derangement as well as an autonomous production of excess amounts of POMC‐derived peptides (Figure 18.5). The clinical syndrome in horses with pituitary tumors is distinctly different from that in Cushing’s disease, which occurs in dogs, cats, and human patients. Corticotroph adenomas in dogs and humans associated with Cushing’s disease are characterized by variable immunostaining for ACTH and weak to moderate immunostaining for α‐MSH (Figure 18.4B,C). Some corticotrophs that contain numerous cytoplasmic secretory granules will stain intensely for ACTH, but many will have modest staining due to little storage of preformed hormone and rapid secretion.

Incidence

Neoplasms derived from granulated acidophils are uncommon in all domestic animal species, but are common in many strains of adult rats. Acidophil adenomas and rarely adenocarcinoma have been reported in dogs, sheep, and cats.^20–22

Clinical characteristics

Acidophil adenomas in sheep are rare, may attain considerable size, and remain confined to the sella turcica. Sheep have a complete diaphragma sella separating the pituitary from the brain (Figure 18.6A). The remaining adenohypophysis and neurohypophysis are compressed severely, and the sella turcica is enlarged and deepened due to pressure‐induced osteolysis (Figure 18.6B). Increased development of mammary tissue and galactorrhea has been observed in sheep with acidophil adenomas, suggesting an overproduction of prolactin by the tumor cells.

A spectrum of clinical problems have been associated with acidophil adenomas in cats, including diabetes mellitus, diabetes insipidus, cranial nerve deficits, and muscular atrophy. Clinical laboratory evaluation often reveals acidosis, hyperglycemia and glycosuria, and resistance to insulin therapy. Acidophil adenomas in cats with clinical signs of diabetes mellitus have degranulation and vacuolation of the beta cells of the pancreatic islets. This suggests that the tumors were secreting excess growth hormone, which resulted in a downregulation of insulin receptors and resistance to the action of insulin. Feline acidophil adenomas have been associated with insulin‐resistant diabetes mellitus and acromegaly and localization of growth hormone in the cytoplasm of tumor cells.^21,23 Cats with growth hormone‐secreting pituitary adenomas also develop degenerative arthritis with joint cartilage proliferation and chronic renal disease associated with periglomerular fibrosis and mesangial proliferation in the glomerulus.

Histopathology

Acidophil adenomas enlarge the pituitary gland and indent the overlying hypothalamus to varying degrees (Figure 18.7A). The enlarged hypophysis is composed of irregular columns of acidophils interspersed between numerous blood‐filled sinusoids. The fibrous stroma is sparse. Although the degree of cytoplasmic granulation of acidophils varies from cell to cell, the predominating type of neoplastic acidophil usually contains many secretory granules. The nuclei of the densely granulated acidophils are small, oval, and hyperchromatic. Sparsely granulated (chromophobic) cells are often interspersed between the densely granulated acidophils (Figure 18.7B). Their cytoplasm is more abundant and lightly acidophilic. The nucleus is large, round, and vesicular. Mitotic figures are observed infrequently. Secretory granules of the acidophils are evident on H&E‐stained sections but are more readily visualized as bright red granules when stained either with acid fuchsin–aniline blue or Crossman’s modification of Mallory’s trichrome stain. Orange‐G stains the granules an intense yellow‐orange, but they are PAS negative (Figure 18.7B).

Colloid‐containing follicles lined by follicular cells are found occasionally within acidophil adenomas in dogs. The colloid is intensely PAS positive. Numerous sinusoids are distended with erythrocytes, detached neoplastic cells, and large masses of fibrin. The pars nervosa and infundibular stalk are compressed to varying degrees, partly replaced by fibrous astrocytes, and infiltrated at the periphery by neoplastic cells; however, this limited extension of neoplastic cells into adjacent parts of the pituitary gland is not interpreted as a criterion of malignancy.

Ultrastructural and immunocytochemical characteristics

Two types of acidophils have been found within pituitary acidophil tumors. The predominating type of acidophil is smaller and contains many secretory granules. The plasma membranes of adjacent cells are relatively straight with uncomplicated interdigitations and are connected by an occasional desmosome. The Golgi apparatus is comparatively small and associated with few pro‐secretory granules. The rough endoplasmic reticulum is composed of small, flattened membranous sacs with attached ribosomes. A few mitochondria are distributed randomly throughout the cytoplasm.

The less common type of neoplastic acidophil has a greater cytoplasmic and nuclear area, and the cytoplasm contains numerous organelles but few mature secretory granules. The rough endoplasmic reticulum is extensive and consists of aggregates of lamellar arrays of granular membranes. The Golgi apparatuses are prominent and are composed of agranular membranes associated with numerous small pro‐secretory granules. Mitochondria are more numerous in this type of acidophil. These hypertrophied acidophils are considered to be actively synthesizing and secreting cells.

Immunoreactive prolactin cells occur in small groups of large polygonal cells with prominent granules in the ventrocentral and cranial parts of the normal canine pars distalis. A diffuse increase in this population of cells occurs in pregnant animals near parturition. Growth hormone‐secreting cells are present singly along capillaries in the dorsal region of the pars distalis near the pars intermedia. They are small, round to oval, and have fine cytoplasmic granules. Somatotrophs frequently undergo diffuse hyperplasia and hypertrophy in old dogs, especially females.

Incidence

Pituitary carcinomas are rare compared with pituitary adenomas, but they have been seen in dogs and cows.^24,25 These carcinomas are usually endocrinologically inactive, but may cause significant functional disturbances by destruction of the pars distalis and neurohypophysis, leading to panhypopituitarism and diabetes insipidus. The designation of carcinoma is based primarily on definitive invasion of the tumor into the CNS or adjacent structures combined with hemorrhage, necrosis, and anaplasia. Metastases are reported, but are exceedingly rare.

Macroscopic pathology and histopathology

Pituitary carcinomas are large, extensively invade the overlying brain, and aggressively infiltrate into the sphenoid bone of the sella turcica (Figure 18.8A,B). Metastasis is rare but occurs in regional lymph nodes or to distant sites, such as the spleen, kidney or liver (Figure 18.8C).

Malignant tumors of pituitary chromophobes are highly cellular and often have large areas of hemorrhage and necrosis. Giant cells, nuclear pleomorphism, and mitotic figures are encountered more frequently than in chromophobe adenomas; however, pituitary cytology is not a dependable criterion of malignancy. Invasion of neoplastic cells into the adjacent sphenoid bone, vascular invasion with formation of tumor cell thrombi, extensive aggressive invasion (not just extension along lines of least resistance) into the overlying brain, and establishment of metastases at distant sites are criteria for the diagnosis of pituitary carcinoma. Limited extension of neoplastic cells into the adjacent pars nervosa and infundibular stalk are observed frequently with larger pituitary adenomas.

Incidence

Craniopharyngioma is a benign tumor that is derived from epithelial remnants of the oropharyngeal ectoderm of dorsal extensions of the craniopharyngeal duct (Rathke’s pouch). They occur in animals younger than those with other types of pituitary neoplasms and are present either in a suprasellar or infrasellar location. Craniopharyngiomas are one cause of panhypopituitarism and dwarfism in young dogs resulting from a subnormal secretion of somatotropin and other trophic hormones beginning at an early age, prior to closure of the growth plates; however, most pituitary neoplasms of this type develop in young adult (2‐ to 4‐year‐old) dogs. Malignant craniopharyngiomas have been reported in two middle‐aged cats.²⁶

It has been proposed that pleomorphic neoplasms in the suprasellar region of younger dogs be classified as germ cell tumors rather than craniopharyngiomas.²⁷ The diagnosis of germ cell tumors was based upon three criteria: (1) midline suprasellar location, (2) presence within the tumor of several distinct cell types (one population resembling a seminoma or dysgerminoma and others suggesting teratomatous differentiation into secretory glandular and squamous elements), and (3) positive staining for α‐fetoprotein. The source of the germ cells is unknown but various germ cell tumors are reported in the brain (such as dysgerminomas and teratomas).

Clinical features

The clinical signs are due to the large size of this type of pituitary tumor and are usually a combination of several factors, including (1) lack of secretion of pituitary trophic hormones resulting in trophic atrophy and subnormal function of the adrenal cortex and thyroid gland (Figure 18.9A), gonadal atrophy and, occasionally, a failure to attain somatic maturation due to a lack of growth hormone secretion, (2) diabetes insipidus, (3) deficits in cranial nerve function, and (4) CNS dysfunction due to extension into the overlying brain.

Macroscopic pathology

Craniopharyngiomas are often large and grow along the ventral aspect of the brain where they can incorporate several cranial nerves and destroy much of the pars distalis and pars nervosa. In addition, they may extend dorsally into the hypothalamus and thalamus (Figure 18.9A); however, dorsal growth of the tumor is not considered to be evidence of malignancy but rather extension along lines of least resistance.

Histological characteristics

Craniopharyngiomas have alternating solid and cystic areas. The histological characteristics of craniopharyngiomas are distinctive and unique for an intracranial tumor on the ventral aspect of the brain. The solid areas are composed of nests of epithelial cells (cuboidal, columnar, or squamous cells) with prominent focal areas of keratinization (Figure 18.9B,C) and occasional mineralization that compress the overlying hypothalamus. The areas of keratin accumulation are densely eosinophilic and are frequently associated with fragments of nuclear chromatin. The neoplastic epithelial cells are large and pleomorphic with vesicular nuclei and prominent nucleoli, and they frequently have discrete vacuoles in their cytoplasm (Figure 18.9B,C). Often there is an admixture with smaller cuboidal to polyhedral cells that have acidophilic secretory granules that stain positive for either prolactin or growth hormone by immunocytochemistry. The cystic spaces are lined by either columnar or squamous cells and contain keratin debris and colloid. Colloid‐containing follicles may be formed that are lined either by cuboidal or by columnar cells and contain variable amounts of eosinophilic colloid.

An alternative interpretation is that these suprasellar pleomorphic neoplasms in dogs are of germ cell origin and that the secretory (glandular) and squamous elements represent teratoma differentiation.²⁷ Additional cases need to be studied utilizing a spectrum of immunocytochemical stains for the protein and glycoprotein pituitary hormones, α‐subunit, chorionic gonadotropin, α‐fetoprotein, and placental ALP to determine which of the pleomorphic neoplasms in the suprasellar region are derived from remnants of the oropharyngeal epithelium of the craniopharyngeal duct and which have their origin from multipotential germ cells.

Despite their relatively large size, squamous differentiation and heterogeneous cytology these tumors are invariably benign in dogs. In the two cats reported with craniopharyngiomas, they were classified as malignant due to local bone invasion and anaplasia.

Incidence and pathogenesis

Adenomas of the adrenal cortex occur most frequently in neutered domestic ferrets and old dogs (8 years and older) and sporadically in cats, horses, cattle, goats, and sheep.^1–3 Adrenal cortical carcinomas occur less frequently than adenomas, and they occur most often in ferrets and dogs, and rarely in other species. Carcinomas develop in adult to older animals. Humans have a high incidence (5%) as adults of nonfunctional adenomas (incidentalomas) and carcinomas are very rare. In dogs, adenomas and carcinomas are often functional.

The stem and proliferative cells of the adrenal cortex occur in the subcapsular region and junction of the zona glomerulosa and fasiculata.⁴ Differentiation of the cortical cells occurs in a linear manner in the cords of cells from the zona glomerulosa to the cortical medullary junction. ACTH from the pituitary gland induces expression of the melanocortin‐2 receptor (MC2R, also known as ACTH receptor) on the cortical cells that differentiate to produce glucocorticoids. The stem cells of the adrenal cortex are thought to be the origin of adrenocortical tumors that result from genetic and epigenetic alterations of the cortical cells.¹ Gonadectomy increases pituitary secretion of luteinizing hormone (LH) due to reduced negative feedback from sex steroids. High levels of LH induce proliferation of adrenocortical stem cells and differentiation into sex steroid‐producing cells (particularly in ferrets and mice), which may represent the cells of origin of adrenocortical tumors in these animals.⁵ Neutered domestic ferrets have a high incidence of nodular adrenocortical hyperplasia, adenomas, and carcinoma.⁶ Castrated male goats are reported to have a higher incidence of cortical adenomas than intact males.⁷ Adrenocortical tumors that occur in gonadectomized animals often have expression of LH receptor and GATA4, which is a transcription factor specific for sex steroid‐producing cells.

Clinical characteristics

Adenomas and carcinomas of the adrenal cortex in dogs may be functional (endocrinologically active) and secrete excessive amounts of cortisol. There are multiple pathogenic mechanisms that result in the syndrome of cortisol excess (Figure 18.12G).⁸ The clinical signs of functional adrenal cortical tumors in dogs usually are the result of cortisol excess and are similar to those described previously for corticotroph (ACTH‐secreting) adenomas of the pituitary. The clinical picture of adrenal cortical carcinoma may be complicated by compression of adjacent organs by a large tumor, invasion into the aorta or posterior vena cava, and metastasis to distant sites. Ultrasonography and/or radiographic detection of adrenal enlargement with or without calcification has proven to aid in the diagnosis of adrenal neoplasms.⁹ In horses, adrenal tumors have been reported to be associated with endocrine disturbances.

Adrenal tumors are recognized with high frequency (~20%) in ferrets that are neutered as adolescents (in the United States and Japan) and kept as household pets and living to a more advanced age (4–5 years of more).³ The adrenal enlargements are either bilateral (~15%) or unilateral (~85%) due to nodular hyperplasia (56%), adenoma (16%), or carcinoma (26%).¹⁰ However, there may be considerable variability between pathologists in the diagnosis of adrenal tumors in ferrets due to their pleomorphic growth patterns. In contrast to adrenal tumors in dogs that produce excess glucocorticoids, adrenal tumors in ferrets produce sex steroids. Clinical signs in ferrets include vulvar enlargement; bilaterally symmetrical alopecia, especially on the ventral abdomen and medial aspects of the rear legs; polyuria; and polydipsia. Adrenal tumors develop in adult ferrets (mean age 5 years), with females more frequently affected than males (sex ratio of 2:1 or greater) and the left side more commonly than the right. Other functional disturbances including anemia, thrombocytopenia, pyometra, endometrial hyperplasia, and squamous metaplasia of the prostate gland are consistent with an overproduction of estrogenic steroids. About one‐third of ferrets with adrenal cortical tumors also have neoplasms derived from the insulin‐producing beta cells of the pancreatic islets, which can be associated with hypoglycemia and elevated levels of serum insulin, resulting in seizures, lethargy, and weakness.

The most consistent endocrinologic change in ferrets with adrenal tumors is an elevation in plasma levels of 17β‐estradiol. It is presumed that the 17β‐estradiol is produced by the tumor directly, but an alternative possibility would be that the adrenal tumors secrete androgenic steroids that are aromatized peripherally to estrogenic steroids. There is no increase in circulating 17β‐estradiol in response to exogenous ACTH, but plasma levels decrease following adrenalectomy. Plasma cortisol and corticosterone levels in ferrets with adrenal tumors are normal or below normal and the contralateral adrenal cortex is not atrophic, as would be expected if the adrenal tumor was secreting excess cortisol. However, the urinary cortisol:creatinine ratio has been reported to be elevated in ferrets with adrenal cortical tumors.¹¹ This is probably due to the stress of the disease rather than secretion of excess cortisol by the neoplasm. The clinical signs in ferrets with adrenal cortical tumors can be effectively reversed by adrenalectomy.

Primary hyperaldosteronism occurs infrequently in cats and rarely in dogs with adrenocortical adenomas or carcinomas that secrete excessive amounts of aldosterone.¹² Clinical signs include hypertension, blindness, and weakness due to hypokalemic polymyopathy.

Macroscopic pathology

Cortical adenomas usually are well‐demarcated single nodules in one adrenal gland, but they may be bilateral in approximately 10% of the dogs. Larger cortical adenomas are yellow to red, distort the external contour of the affected gland, and are partially or completely encapsulated. Adjacent cortical parenchyma is compressed, and the tumor may extend into the medulla (Figure 18.12A).

Smaller cortical adenomas are more yellow or similar in color to the normal adrenal cortex because of the high lipid content. They are surrounded by mildly compressed cortex and may be difficult to distinguish from areas of nodular cortical hyperplasia observed frequently in old dogs. Nodular hyperplasia usually consists of multiple foci of various sizes in both adrenals with no evidence of encapsulation and is often associated with extracapsular nodules of hyperplastic cortical tissue extending into the periadrenal connective tissues and into the adrenal medulla. Nodular hyperplasia does not cause clinical disease or atrophy of the contralateral or ipsilateral adrenal cortex.

Adrenal cortical carcinomas are larger than adenomas and may be more likely to develop in both glands (Figure 18.12B). In dogs they are composed of a variegated, yellow to brownish red, friable tissue that incorporates most or all of the affected adrenal gland. They are often fixed in location because of extensive invasion of surrounding tissues and the posterior vena cava, forming a large tumor cell thrombus. Carcinomas may attain considerable size in cattle (as much as 10 cm or more in diameter) and have multiple areas of mineralization or ossification.

Functional (cortisol‐secreting) adrenal cortical adenomas and carcinomas are associated with profound cortical atrophy of the contralateral gland because of negative feedback inhibition of the pituitary ACTH secretion by the elevated blood cortisol levels (Figure 18.12B). The atrophic cortex consists primarily of the adrenal capsule and zona glomerulosa with few secretory cells remaining in the zonae fasciculata and reticularis. A similar parenchymal atrophy is present in the uncompressed cortex around functional adenomas. The severity of the atrophy can be mild to marked, most likely due to chronicity. The adrenal medulla appears expanded and relatively more conspicuous because of the lack of surrounding cortical parenchyma.

Histopathology

Cortical adenomas are composed of well‐differentiated steroid hormone‐producing cells that resemble secretory cells of the normal zona fasciculata or reticularis (Figure 18.12C–F). Tumor cells are arranged in broad trabeculae or nests separated by small vascular spaces. The abundant cytoplasmic area of tumor cells is lightly eosinophilic, often vacuolated, and filled with many lipid droplets. Some tumor cells can be spindle shaped, often with fewer cytoplasmic vacuoles. Adenomas are partially or completely surrounded by a thin fibrous connective tissue capsule and a rim of compressed cortical parenchyma. The junction of an adenoma with normal cortex can be subtle in areas without a fibrous capsule (Figure 18.12F). Focal areas of mineralization, extramedullary hematopoiesis, and accumulations of fat cells may be found in cortical adenomas. Extramedullary hematopoiesis with megakaryocytes and erythroid and granulocytic colonies is a characteristic finding in canine adrenal cortical adenomas. Larger adenomas have areas of necrosis and hemorrhage with vascular proliferation near the center (Figure 18.12E).

Nodular cortical hyperplasia and myelolipoma must be differentiated histologically from adrenal cortical adenomas. The presence of a partial or complete fibrous capsule surrounding one or two progressively expanding areas of proliferating cortical cells suggests an adenoma rather than nodular hyperplasia. Nodular hyperplasia appears as multiple small nodules of cortical tissue, non‐encapsulated and located most commonly outside the capsule (Figure 18.12H), next in the cortex, and sometimes in the medulla. Myelolipoma is a benign lesion encountered in the adrenal glands of cattle and nonhuman primates and infrequently in other animals. It is composed of well‐differentiated adipose cells and hematopoietic tissue, including both myeloid and erythroid elements. Areas of well‐differentiated lamellar bone formation may occur in myelolipomas. Although the origin of myelolipomas is uncertain, they appear to develop by metaplastic transformation of cells in the adrenal cortex or cells lining adrenal sinusoids. In addition, teratomas have been reported in the ferret adrenal gland, and are rare in other species.¹³

Adrenal cortical carcinomas are composed of more highly pleomorphic cells than adenomas, which are subdivided into groups by a fibrovascular stroma of varying thickness. The architecture of the affected adrenal is completely obliterated by the carcinoma. The pattern of growth varies between individual tumors and within the same carcinoma, resulting in the formation of trabeculae, lobules, or nests of tumor cells. Tumor cells usually are large and polyhedral with a vesicular nucleus, prominent nucleoli, and densely eosinophilic or vacuolated cytoplasm. Anaplastic carcinomas may have spindle‐shaped cells with a smaller and more lightly eosinophilic cytoplasm. Areas of hemorrhage within the tumors are common because of rupture of thin‐walled vessels. Invasion of tumor cells through the adrenal capsule into adjacent tissues and into vessels and lymphatics, forming emboli, is frequently detected in carcinomas of the adrenal cortex and when present makes the diagnosis of carcinoma straightforward.

Adrenal adenomas and carcinomas in ferrets are typically pleomorphic, with small undifferentiated cells, larger well‐differentiated cortical cells with cytoplasmic lipid vacuoles, and variable degrees of spindle cell differentiation (Figure 18.13A,B).¹⁴ Some carcinomas develop myxoid differentiation with lumen‐like spaces containing alcian blue‐positive acid mucopolysaccharides (Figure 18.13B).¹⁵ IHC markers for the tumor cells include vimentin, α‐inhibin, synaptophysin, estrogen receptor, and GATA4 (Figure 18.13C,D). The neoplastic spindle cells may also differentiate to smooth muscle‐like cells and stain immunohistochemically positive for α‐smooth muscle actin and desmin.

IHC for specific cytochrome P450 enzymes in adrenocortical tumors has the potential to characterize the type of differentiation of the tumor cells, especially in functional tumors.¹⁶ For example, tumors that secrete aldosterone would be expected to express aldosterone synthase (CYP11B2). Additional IHC markers for adrenocortical tumors include steroidogenic factor‐1 (SF‐1), steroid receptor co‐activator‐1 (SRC‐1), StAR protein (steroidogenic acute regulator protein), α‐inhibin, calreticulin, GATA6 (GATA4 in ferrets), Melan‐A, and synaptophysin. Tumor cells are typically negative for keratin and chromogranin A.

Growth and metastasis

Adrenal cortical adenomas usually are slow growing, well demarcated, relatively small tumors that may be associated with a hypersecretion of cortisol or infrequently other adrenal steroid hormones (e.g., aldosterone, androgens, or estrogens). Carcinomas of the adrenal cortex are larger, locally invasive, and metastasize to distant sites. They often invade through the thin wall of the posterior vena cava, forming a large tumor cell thrombus, and into the adventitial layer of the abdominal aorta in dogs and cattle. Metastases are found primarily in the liver, kidney, lungs, and mesenteric lymph nodes.

It can be challenging to differentiate adrenal cortical adenomas from carcinoma in dogs, especially in biopsy specimens. Histologic features alone are often not sufficient, but sometimes the pathologist is restricted by the sample provided. Many cortical carcinomas are well differentiated, but can still have metastatic potential. Definitive criteria of malignancy are local invasion through the adrenal capsule into surrounding tissues, vascular invasion, and metastasis. Indicators of malignancy for adrenocortical carcinomas in dogs included size (greater than 2 cm), fibrosis, capsular invasion, trabecular growth pattern, decreased cytoplasmic vacuolation, hemorrhage, necrosis, and increased proliferation index (Ki67 positivity was 9% in carcinomas and 1% in adenomas).¹⁷

In addition, metastases, such as in the lungs or liver, can be difficult to identify as originating from the adrenal gland. IHC markers to help identify adrenal cortical neoplasms, such as metastases, include steroidogenic factor‐1 (SF‐1), steroid receptor co‐activator‐1 (SRC‐1), α‐inhibin, calreticulin, GATA4, Melan‐A, and synaptophysin. SF‐1 and SRC‐1 have a high degree of specificity and sensitivity for adrenocortical tumors.

Differentiation of adrenocortical adenomas from carcinomas in ferrets is also challenging, since the neoplasms are often multinodular with different cell types and degrees of differentiation. Capsular invasion and metastasis (especially to the liver) are definitive criteria of invasion. Complete surgical excision of early invasive carcinomas often has a good prognosis with a low incidence of metastasis.¹⁸

Incidence and classification

Pheochromocytomas are the most common tumors in the adrenal medulla of animals, although other tumors may develop from the neuroectodermal cells, which differentiate into either secretory cells or sympathetic ganglion cells (Figure 18.14).^1–4 Neuroblastomas are uncommon; they arise from primitive neuroectodermal cells, often in younger animals, and form a large intra‐abdominal neoplasm that may metastasize to peritoneal surfaces. Ganglioneuromas are rare; they usually are well‐differentiated small tumors that have sympathetic ganglion cells and neurofibrils.

Pheochromocytomas develop most often in dogs, cattle, and horses and infrequently in other domestic animals.^1–5 They are common in some strains of rats.^1,6 Pheochromocytomas in dogs usually develop in middle‐aged to older dogs with no apparent gender or breed predisposition. Occasionally, pheochromocytomas may develop concurrently with calcitonin‐secreting C‐cell (ultimobranchial) tumors of the thyroid gland.^7,8 This appears to represent a multicentric neoplastic transformation of multiple types of endocrine cells of neuroectodermal origin in the same individual and resembles the syndrome of multiple endocrine neoplasia (MEN) in human patients.

Clinical characteristics

Functional pheochromocytomas are associated with tachycardia, hypertension, edema, and cardiac hypertrophy, which are attributed to excessive catecholamine secretion. Arteriolar sclerosis and widespread medial hyperplasia of arterioles occur in dogs with pheochromocytomas that were associated with paroxysmal hypertension. Infrequently, hyperadrenocorticism may occur concurrently in dogs with pheochromocytoma.⁹ Hypercalcemia may occur in sporadic cases of pheochromocytoma.¹⁰

Norepinephrine is the principal catecholamine extracted from pheochromocytomas in dogs. This is similar to normal pups, where norepinephrine is the predominant catecholamine, but in adult dogs epinephrine predominates. The catecholamine content in pheochromocytomas from bulls has been found to be higher than in the normal adrenal medulla.¹¹ Plasma and urinary metabolites of epinephrine or norepinephrine (metanephrine and normetanephrine, respectively) are increased in animals with functional pheochromocytomas.^12,13

Many adrenal medullary tumors in animals are found as incidental findings at necropsy or surgery. However, malignant pheochromocytomas are often large and invade into the posterior vena cava, forming a intravascular tumor cell thrombus. The vena cava is distended greatly and partially occluded by the thrombus, leading to impaired venous return and potentially severe regional hemorrhage. In a study of 50 dogs with pheochromocytomas, local tumor invasion was present in 52%, regional lymph node metastasis in 12%, and distant metastases in 24%.²

Macroscopic pathology

Pheochromocytomas are tumors of chromaffin cells and are almost always located in the adrenal gland, although a few extra‐adrenal tumors have been found along the posterior aorta and vena cava in sites analogous with the organ of Zuckerkandl in humans. They usually are unilateral, but may be bilateral. Although size varies considerably, pheochromocytomas can be large (10 cm or more in diameter) and incorporate the majority of the affected adrenal. A small remnant of the adrenal gland usually can be found at one pole. Smaller tumors are completely surrounded by a thin compressed rim of adrenal cortex (Figure 18.15B,C).

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