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Topic of the month...Neuro-endocrinal dysfunction in the pediatric age group
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INTRODUCTION
NORMAL EMBRYOLOGY AND DEVELOPMENT OF
PITUITARY- HYPOTHALAMIC STRUCTURES
NEUROENDOCRINE DISORDERS OF CHILDHOOD
CONGENITAL AND DEVELOPMENTAL ABNORMALITIES OF
THE PITUITARY- HYPOTHALAMIC AXIS
ACQUIRED ABNORMALITIES
INFECTIOUS AND INFLAMMATORY DISORDERS
IMAGING OF NEUROENDOCRINE DISORDERS OF CHILDHOOD
Neuroendocrine disorders of childhood result from a variety of abnormalities of the developing hypothalamic-pituitary axis.
These disorders include hypopituitarism, growth failure, diencephalic syndrome, delayed puberty, precocious puberty,
diabetes insipidus, syndrome of inappropriate antidiuretic hormone (SIADH) secretion, and hyperpituitarism. [14,52]
NORMAL EMBRYOLOGY AND DEVELOPMENT OF PITUITARY- HYPOTHALAMIC STRUCTURES
The anterior and posterior lobes of the pituitary gland develop separately and from different origins. The anterior pituitary
gland (adenohypophysis) develops from Rathke's pouch or cleft, which becomes separated from the oropharynx between 6 and
7 weeks of gestational age. More recent evidence suggests that the pouch originates from the neuroectoderm rather than the
buccal cavity. [109] At week 7, the anterior pituitary cells adjacent to the posterior pituitary develop into the pars intermedia.
Cells of the anterior pituitary proliferate until the lobe constitutes 90% of the total gland at midgestation and 78% at term. [8]
The anterior lobe of the pituitary makes numerous hormones, including prolactin, growth hormone, adrenocorticotropic
hormone (ACTH), thyroid-stimulating hormone, follicle-stimulating hormone, and luteinizing hormone. The posterior lobe of
the pituitary (neurohypophysis) develops as a downgrowth of the hypothalamus, and connections are maintained to the
hypothalamus via the pituitary stalk and the hypothalamohypophyseal tract. Hormones made in the hypothalamus are stored
in the posterior lobe and include antidiuretic hormone (ADH) or vasopressin and oxytocin. The infundibulum can be identified
at 6 weeks. The infundibulum is normally not more than 2 mm in diameter. [100] There are numerous nuclei within the
hypothalamus, including the supraoptic and paraventricular nuclei, which secrete vasopressin and oxytocin. [72] Groups of
hypothalamic cells also produce peptidergic- releasing hormones. Some of these releasing hormones stimulate synthesis and
promote release, and others inhibit hormonal release from anterior lobar cells. These include releasing hormones for
corticotropin, follicle-stimulating hormone, luteinizing hormone, thyrotropin, and somatotropin and the release-inhibiting
2. hormones for melanocyte-stimulating hormone, somatostatin, and prolactin. [114]
The pituitary gland is primarily supplied by the hypophyseal portal system. The superior hypophyseal artery from the
supraclinoid internal carotid artery supplies the hypothalamus, pituitary stalk, and superior surface of the pituitary gland.
The inferior hypophyseal artery, from the cavernous internal carotid artery, supplies the posterior lobe of the pituitary and
the lateral surfaces of the anterior lobe of the pituitary.
Fetal histochemical studies have shown considerable differentiation and activity of the pituitary cells during gestation. On T1-
weighted imaging, the pituitary gland at birth has uniformly high signal intensity involving both the anterior and the posterior
lobes, as compared with the adjacent brain. [31,116] Possibly the rapid differentiation of the gland in utero with an
accompanying increase in protein synthesis accounts for the short T1 values. Beginning at 18 days of life, the high signal
intensity of the anterior lobe gradually disappears, but the posterior pituitary remains as a high-intensity structure and is
separately identified by the age of 6 weeks. [27,115] The decrease in intensity of the anterior pituitary gland may be the result
of a reduction of its high protein synthesis activity to a normal postnatal state. The hyperintensity of the posterior pituitary
may be due to its phospholipid content, although another theory attributes the high intensity to vasopressin (ADH) and its
neurophysin-carrier protein. [25,60,63] The bright signal of the posterior pituitary gland is seen in 90% to 100% of healthy
subjects [42,62] and always in healthy children. [5]
The size and shape of the pituitary gland varies with age. [27,36,100,106,107] Below 6 weeks of gestation, the gland is globular
in shape and flattens with growth. The pituitary gland is prominent at birth, during puberty (particularly in girls), and during
pregnancy. This appearance should not be mistaken for tumor. The pituitary gland changes during puberty [27,36] and
reaches a maximal height of 10 mm in adolescent girls with a spherical or upwardly convex margin. In pubertal boys, it may
reach 7 mm in height. [6] During pregnancy and the postpartum period, the anterior lobe may appear Tl hyperintense. [74, 82]
Figure 1. Normal appearance of the pituitary gland, notice the upper concave border,the
diffuse enhancement of the pituitary gland and the well corticated sellar floor.
The pituitary gland lies within the sella turcica of the sphenoid bone. The surrounding structures include the sphenoid sinus
anteriorly and inferiorly, the suprasellar cistern superiorly, the basilar artery and brain stem posteriorly, and the cavernous
sinuses bilaterally The suprasellar cistern contains the optic chiasm and nerves, hypothalamus, infundibulum, and arterial
structures of the circle of Willis. The diaphragms sella covers the sella turcica except for a tiny defect that allows the passage of
the infundibulum.
NEUROENDOCRINE DISORDERS OF CHILDHOOD
Hypopituitarism
The earliest and the most common manifestation of hypopituitarism in childhood is growth failure as a result of growth
hormone deficiency and thyroid deficiency Hypopituitarism has numerous causes and may result from congenital
abnormalities, such as pituitary aplasia or hypoplasia, or may be associated with anencephaly, holoprosencephaly, septo-optic
dysplasia, empty sella, midface anomalies, solitary central maxillary incisor, basal cephalocele, genetic and chromosomal
abnormalities, and cleft lip or cleft palate. The acquired causes of hypopituitarism include common neoplasms of childhood,
such as craniopharyngioma, pituitary adenoma, and optic and hypothalamic gliomas. In addition, other acquired causes of
hypopituitarism include infection such as meningitis, cranial irradiation, surgery, trauma, hemorrhage, hypoxic-ischemic
encephalopathy, histiocytosis, lymphocytic hypophysitis, tuberculosis, sarcoidosis, hemochromatosis (idiopathic and after
multiple blood transfusions), and cerebral edema. [14,16]
Growth Failure
3. Growth failure may result from a variety of causes. Pathologic causes of short stature include nutritional and endocrine
abnormalities, chromosomal defects, bone development disorders, metabolic causes, chronic illness, chronic drug intake, and
numerous others. [70] The endocrine causes of short stature include isolated growth hormone deficiency, hypothyroidism,
hypopituitarism, hypercortisolism, and precocious puberty [70] There are numerous syndromes and conditions associated with
growth hormone deficiency or insensitivity, which include genetic disorders as well as embryologic defects, some of which are
elucidated earlier for hypopituitarism. [80]
Diencephalic Syndrome
The diencephalic syndrome is a rare but important cause of failure to thrive in infancy and early childhoods' The syndrome is
characterized by profound emaciation with normal caloric intake, an absence of cutaneous adipose tissue, locomotor
hyperactivity, euphoria, and alertness. [2,28,30,84,85,91] It commonly occurs in association with chiasmatic and hypothalamic
gliomas. [2,28,30,84,85,91] It has also been described in association with other lesions, such as midline cerebellar astrocytoma,
suprasellar ependymoma, and suprasellar spongioblastoma.
Delayed Puberty
Normal puberty depends on normal hypothalamic and anterior pituitary gonadotropic control of gonadal hormone activity.
Disorders of pubertal development include delayed puberty and precocious puberty. Pubertal development is delayed if the
initial physical changes of puberty are not seen in girls by 13 years of age or boys by age 14 or if puberty started and then is
not progressing normally. Causes of delayed or lack of pubertal development may be secondary to hypergonadotropic states
(primary gonadal failure), including chromosomal or genetic disorders (e.g., Turner's syndrome, Klinefelter's syndrome, and
Noonan's syndrome) or acquired disorders, such as autoimmune disorders, radiation therapy and chemotherapy, surgery,
torsion, trauma, or infection. Hypogonadotropic (hypothalamic-pituitary defect or lag) states may also cause a delay or lack of
pubertal development. These states include hypothalamic-pituitary deficiencies, such as gonadotropin deficiency and
endocrinopathies. Delayed or deferred function may be constitutional or re-rated to chronic illness, drug abuse, obesity,
endocrinopathies, or malnutrition. [68]
Precocious Puberty
Precocious puberty is defined as pubertal development occurring before the age of 8 years in girls and before 9.5 years in boys.
[67[ Central precocious puberty is more common in girls than in boys and is more often idiopathic. If present in boys, there
may be underlying pathology, such as a central lesion. Central nervous system causes of precocious puberty include congenital
anomalies, such as arachnoid cyst, hydrocephalus, hypothalamic hamartoma, and septo-optic dysplasia. Acquired
abnormalities include abscess; chemotherapy; cranial surgery; radiation therapy; trauma; and tumors such as hypothalamic
astrocytoma, craniopharyngioma, ependymoma, and rarely pituitary adenoma. Precocious puberty may also be associated
with syndromes, such as the McCune-Albright syndrome and neurofibromatosis 1 (NF-1) (especially in the setting of optic or
hypothalamic glioma). Other causes of precocious puberty include non-central nervous system tumors, such as adrenal
adenoma or carcinoma, gonadotropin producing choriocarcinoma, teratoma, hepatoblastoma, and ovarian and testicular
tumors. Precocious puberty may also be associated with hypothyroidism, exogenous steroids or gonadotropins, ovarian cysts,
and congenital virilizing adrenal hyperplasia. [68]
Diabetes Insipidus
Diabetes insipidus (DI) may result from vasopressin (ADH) deficiency or resistance (central DI), primary renal disease
(nephrogenic DI), or rarely primary polydipsia. Central DI may result from traumatic or surgical injury of the pituitary stalk;
tumors such as germinoma, glioma, or rarely craniopharyngioma; and infiltrative diseases, such as Langerhans' cell
histiocytosis, sarcoidosis, tuberculosis, and Wegener's granulomatosis. Other causes include congenital malformations,
infections, autoimmune hypophysitis, and hereditary conditions. Central DI may be idiopathic, but in approximately 20% of
cases, it precedes the signs and symptoms of hypothalamic tumor by months or years. [5,17]
Syndrome of Inappropriate Antidiuretic Hormone Secretion
SIADH is characterized by the central nervous system sequelae of fluid and electrolyte imbalance. These patients may have
symptoms as severe as encephalopathy, seizures, and brain swelling. SIADH in children most commonly results from
intracranial or pulmonary disease. [17] Central nervous system causes include hydrocephalus, meningitis or encephalitis,
abscess, tumor, demyelinating disease, and psychosis. Non-central nervous system causes include pneumonia, intrathoracic
neoplasm, drugs such as tricycle antidepressants, chemotherapeutic agents such as vincristine, and neoplasms elsewhere in the
body.
4. Hyperpituitarism
Hyperpituitarism may be primary or secondary. Primary hyperpituitarism is related to hypersecretion by tumor. Secondary
hyperpituitarism is related to target organ failure. Hypersecretory pituitary adenomas that occur in childhood include
prolactin-secreting adenomas, which may present as microadenomas or macroadenomas. Endocrine disorders such as growth
hormone excess cause tall stature (pituitary gigantism). Nonendocrine disorders that are associated with tall stature include
cerebral gigantism (Soto's syndrome), Kline- felter's syndrome, other chromosomal abnormalities such as the XXY male,
Marfan syndrome, homocystinuria, and constitutional tall stature. [41] Excessive growth hormone secretion is associated with
pituitary adenomas. Cushing's disease (hypercortisolism resulting from an ACTH-producing pituitary adenoma) is extremely
rare in childhood.
Imaging Evaluation
Neuroimaging evaluation of the child with a neuroendocrine disorder is best done with high-resolution magnetic resonance
(MR) imaging using thin section coronal and sagittal T1-weighted images through the pituitary-hypothalamic axis before and
after the intravenous administration of gadolinium. Fluid attenuating inversion recovery (FLAIR) and T2-weighted fast spin-
echo (FSE) or conventional spin-echo (CSE) images are also important. MR imaging provides multiplanar imaging with high
resolution and fine anatomic detail of the hypothalamic-pituitary region, including adjacent structures such as the optic
chiasm, the cavernous sinuses, and the circle of Willis. CT may be needed to confirm calcification or hemorrhage.
CONGENITAL AND DEVELOPMENTAL ABNORMALITIES OF THE PITUITARY- HYPOTHALAMIC AXIS
Hypoplasia or Absence of the Pituitary Gland
Hypoplasia or absence of the pituitary gland is extremely rare. It may include absence or hypoplasia of the gland or the stalk.
[10] There may be associated midline anomalies of the cranial and facial structures, the optic nerves, and the septum
pellucidum as well as hypoplasia of the adrenal glands, ovaries, and testes. [63] Clinically the patient presents with pituitary-
hypothalamic dysfunction and associated growth failure. On MR imaging, the pituitary gland and sella turcica are absent or
small in size.
Ectopic Posterior Pituitary
Ectopic posterior pituitary is associated with pituitary dwarfism and has been noted in 40% of patients with idiopathic growth
hormone deficiency [1, 56] Other additional hormone deficiencies may occur. On MR imaging, there is a small sella and
pituitary gland, absence or hypoplasia of the pituitary stalk, and an ectopic posterior pituitary bright spot. [65] If necessary,
an ectopic posterior pituitary may be differentiated from a hypothalamic lipoma by the lack of fat suppression). The initial
theories for the ectopic posterior pituitary and pituitary dwarfism have included birth trauma [43] in particular breech
delivery, leading to damage of the infundibulum and its blood supply. These patients may have associated midline defects,
therefore invoking the theory that it is related to abnormal development of the hypothalamus and pituitary. [110] In addition,
there have been numerous hereditary syndromes of growth hormone deficiency or insensitivity described. [110] One of the
growth hormone deficiency syndromes is related to an abnormality of the Pit-I gene. The Pit-1 gene of chromosome 3 is
responsible for a pituitary-specific transcription factor, which binds to and transactivates promoters of growth hormone and
prolactin genes. [81] Mutations in this gene may lead to a combined pituitary hormone deficiency, including growth hormone
failure, and may explain some cases of pituitary dwarfism. In one report of three siblings with combined pituitary hormone
deficiency, an unusual and unexplained pattern of enhancement was observed consisting of rim enhancement of a normal or
minimally enlarged pituitary. [37]
Septo-optic Dysplasia
Some of the syndromes that may be associated with pituitary-hypothalamic dysfunction include septo-optic dysplasia,
Kallmann's syndrome, and empty sella syndrome. In addition, other developmental anomalies may be associated with
pituitary-hypothalamic defects, including agenesis of the corpus callosum, holoprosencephaly, and basal cephaloceles.
Septo-optic dysplasia, a disorder of ventral induction, is considered a mild form of holoprosencephaly. It is a disorder of
abnormal induction of the midline mesoderm occurring at the same time as the development of the optic vesicles. Failure of
differentiation of the mesoderm into the optic stalk results in aplasia of the stalk. [47] Septo-optic dysplasia is characterized by
absence or hypoplasia of the septum pellucidum associated with hypoplasia of the optic nerves as first described by DeMorsier.
[29] Associated hypothalamic-pituitary dysfunction occurs in two thirds of patients. [76,102,103] Patients may have
hypopituitarism that ranges from panhypopituitarism to growth hormone deficiency, thyroid-stimulating hormone deficiency,
5. elevated prolactin, or ACTH or ADH deficiency. [51] Visual symptoms include nystagmus, amblyopia, or hemianopsia. This
syndrome may result from in utero injury or genetic abnormalities. [10] Environmental factors implicated are maternal
diabetes, quinidine ingestion, anticonvulsants, alcohol or drug abuse, and cytomegalovirus. [76] There may be associated
anomalies of neuronal migration, such as schizencephaly and gray matter heterotopias.
Figure 2. Septo-optic dysplasia associated with schizencephaly. Arrows in
A,B point to absent septum pellucidum, arrow in C, and black arrowhead in
D point to open lip schizencephaly, white arrow head point to
polymicrogyria in D
On imaging, there is absence or hypoplasia of the septum pellucidum resulting in a box- like appearance of the frontal horns.
[9,38,39] Hypoplasia of the optic disks is often diagnosed by an ophthalmologist; however, optic nerve, optic tract, or optic
chiasm hypoplasia may be seen in 50% of patients on imaging. [9] Other associated abnormalities include absence of the fornix
and callosal dysgenesis. [19] On MR imaging, two patterns of involvement have been described in septo-optic dysplasia. [9,19]
One group has neuronal migration anomalies such as schizencephaly and gray matter heterotopias, hypothalamic-pituitary
dysfunction, and partial absence of the septum pellucidum. The other group has complete absence of the septum pellucidum
with cerebral white matter hypoplasia. This group may be associated with hypoplasia of the genu of the corpus callosum or
hypoplasia of the anterior falx cerebri. Another group of these patients with ectopia of the posterior pituitary has also been
described. [19] Other anomalies that may be associated with complete or partial absence of the septum pellucidum include
holoprosencephaly, hydranencephaly, basilar cephaloceles, dysgenesis of the corpus callosum, chronic hydrocephalus, Chiari
II malformation, and schizencephaly. [3,11,48]
Kallmann's Syndrome
Kallmann's syndrome consists of agenesis of the olfactory lobes and bulbs associated with hypogonadotropic hypogonadism.
[54] The inheritance is autosomal dominant, recessive, or X-linked. It is the most common form of isolated gonadotropin
deficiency. [18] There is failure of normal neuronal migration of the olfactory cells and the cells that produce luteinizing
hormone-releasing hormone from the olfactory placed into the forebrain. The migration of these cells depends on neural cell
adhesion molecules (NCAMs), which are absent because the gene responsible for NCAM expression is missing. [40,96] The
clinical presentation includes anosmia or hyposmia, hypogonadism, and delayed puberty. [52] MR imaging may help to make
the diagnosis because the olfactory sulcus and olfactory apparatus are absent or hypoplastic on thin-section coronal Tl or T2
images. [111,119, 120]
6. Figure 3. Kallmann's syndrome in a child
with hypogonadotropic hypogonadism.
Normal olfactory sulcus and olfactory
apparatus (A). Coronal T2-weighted MR
image demonstrates absence of the olfactory
sulci bilaterally and hypoplasia of the
olfactory apparatus (B).
Empty Sella Syndrome
The empty sella syndrome results from a deficiency of the diaphragms sella, which allows the suprasellar cistern to herniate
into the sella. This herniation produces sellar expansion and flattening of the pituitary gland. This syndrome occurs more
commonly in adults but may occur in children. [26,77] It may be associated with hypothalamic-pituitary dysfunction in
children as well as visual symptoms and cerebrospinal fluid rhinorrhea. [52, 98] There is often an association with pituitary
hypotension, particularly multiple hormone deficiencies, although pituitary hyperfunction may occur. [21] On MR imaging,
the pituitary gland is flattened, the stalk is midline, and the sella is enlarged and filled with cerebrospinal fluid.
ACQUIRED ABNORMALITIES
Chiasmatic or Hypothalamic Gliomas
The most common neuroendocrine disorders associated with chiasmatic or hypothalamic gliomas are precocious puberty,
diencephalic syndrome, and hypopituitarism. These tumors constitute 10% to 15% of supratentorial tumors of childhood. [10]
These optic or hypothalamic tumors are often low-grade astrocytomas and pilocytic. They are rarely anaplastic. Often, it is
difficult to distinguish whether the tumor originates from the chiasm or the hypothalamus. Between 20% and 50% of patients
with chiasmatic or hypothalamic tumors have NF-1. Optic gliomas are the most common tumor of the central nervous system
seen in NF-I. [4] These gliomas may involve any portion of the optic pathway, including one or both optic nerves, the chiasm,
tracts, the lateral geniculate bodies, or the optic radiations. Other intracranial lesions that may be seen in NF-1 include NF-1
spots, plexiform neurofibromas, and other astrocytomas. The clinical presentation most often includes decreased visual acuity,
although visual field defects, optic atrophy, hydrocephalus, and hypothalamic dysfunction and papilledema may be seen. [13]
MR imaging is the modality of choice for evaluating these tumors. These lesions are usually T1 hypointense and T2
hyperintense with homogeneous gadolinium enhancement. Heterogeneous enhancement may be seen when the tumors are
large. With the use of fat suppression, MR imaging visualizes all portions of the optic pathways. [101] Computed tomography
(CT) may also be helpful in evaluating the intraorbital optic nerves. On CT, chiasmatic or hypothalamic tumors are usually
isodense or low density. [13] Calcification, cyst, hemorrhage, and tumor hyperdensity are rare.
7. Figure 4. Hypothalamic pilocytic astrocytoma
The diencephalic syndrome is a rare cause of failure to thrive in infancy as described earlier and is commonly associated with
hypothalamic or chiasmatic astrocytomas. The tumors associated with this syndrome are often larger in size, occur at a
younger age, and are more aggressive than those associated with other presentations. Despite low-grade histologic findings,
these tumors may seed throughout the cerebrospinal fluid pathways. [88]
Figure 5. A, Optic nerve glioma causing fusiform enlargement of the optic nerve, B, bilateral optic nerve gliomas
8. Figure 6. Bilateral optic nerve gliomas extending into the optic chiasma in the parasellar region. Notice the contrast
enhancement. Histopathology revealed a pilocytic astrocytomas of the optic pathways in a patient with neurofibromatosis I
Craniopharyngioma
The most common neuroendocrine presentation in craniopharyngioma is growth hormone deficiency. Panhypopituitarism or
diabetes insipidus is rare. Craniopharyngioma is a benign but aggressive neoplasm arising in the suprasellar or intrasellar
region. Generally thought to arise from remnants of Rathke's pouch (i.e., craniopharyngeal duct), the tumor is composed of
characteristic squamous epithelium. [90,92] These tumors represent 3% of all intracranial tumors and constitute 50% of
suprasellar tumors seen in childhood. [10] These tumors occur in childhood and adolescence and are more common in boys.
The clinical presentation includes headache, visual field defects, diplopia, and short stature. Hydrocephalus and papilledema
may be present. Although craniopharyngiomas may be solid, they are more characteristically cystic tumors, and the cysts are
typically filled with a cholesterol-rich fluid grossly resembling motor oil. Although histologically benign, craniopharyngiomas
tend to compress, envelop, or infiltrate adjacent structures and produce a reactive gliosis. As a result, surgical extirpation is
difficult and recurrence is likely. The tumors are usually intrasellar, suprasellar, or both.
Figure 7. A, Craniopharyngioma, compressing the optic chiasma, hypothalamus and extending upward into the lateral
ventricle. The tumour is partially cystic with calcified material. B, A sagittal section of the brain shows a large
craniopharyngioma below the cerebral ventricle. Note the stippled pattern of the tumor.
On CT, 90% of craniopharyngiomas are cystic and calcified. [59] On MR imaging, these tumors have variable signal
characteristics depending on the contents of the cyst and the presence of calcium. The solid component of the tumor may be
isodense or hypodense on CT and T1 isointense to hypointense with isointensity to hyperintensity on MR imaging. The
calcified component is of increased attenuation on CT and often T2 hypointense on MR imaging. The cystic component may be
of high or low Tl intensity and T2 hyperintense. After gadolinium administration, there is usually peripheral enhancement of
the cyst and heterogeneous enhancement of the solid component. [59,119] Craniopharyngioma is to be differentiated from a
cystic, calcified glioma or a teratoma.
9. Figure 8. Classic adamantinoma-like appearance of a craniopharyngioma. The pink region corresponds to brain tissue (BT) at
the interface with the tumor and is mainly composed of reactive astrocytes. The tumor itself is composed of epithelial cells
arranged around cystic spaces. The cells proximal to the spaces are cuboidal in shape and arranged in palisades, above this cell
layer the epithelium became squamous. Some cysts are empty but others contain keratin debris (K). B, Gross pathological
specimen of a craniopharyngioma
Figure 9. Epithelial lesion with peripheral palisading of basal
squamous epithelium surrounding loosely arranged epithelial cells,
the so-called quot;stellate reticulumquot; and nodules of keratin and
variable calcification are typical histologic features of a
craniopharyngioma.
10. Figure 10. CT scan precontrast A, and postcontrast B,C,D. A heavily calcified suprasellar cystic
craniopharyngioma, with subfrontal extension, the lesion also showed suprasellar extension to the
foramen of monro causing obstructive hydrocephalus. Dense contrast enhancement occurred in
some parts of the tumour.
Figure 11. Parasellar craniopharyngioma: A, Precontrast
CT scan (left) and postcontrast CT scan (right), B,
postcontrast MRI T1 image (left) and precontrast MRI T1
image (right). Notice the calcification, the mild postcontrast
enhancement, the MRI signal heterogeneity and the
associated hydrocephalus.
Rathke's Cleft Cyst
The most common neuroendocrine presentation in Rathke's cyst is hypopituitarism and delayed puberty. Rathke's pouch
represents an embryonic upward growth of ectoderm from the primitive oral cavity (stomodeum). It is the precursor of the
anterior and intermediate lobe of the pituitary as well as the pars tuberalis. Persistence of the intrasellar extremity of Rathke's
pouch occasionally results in formation of an epithelium-lined Rathke's cleft cyst. The cyst is usually located between the pars
distalis and the pars nervosa of the pituitary and, if large, may lead to compression of the pituitary or adjacent structures.
Although usually intrasellar and lined by cuboidal or columnar mucus-secreting epithelium, Rathke's cleft cysts may occur in
the suprasellar region, undergo squamous metaplasia or hemorrhage, and overlap pathologically with craniopharyngiomas.
[92]
11. Figure 12. Rathke's cleft cyst
Figure 13. T1-weighted sagittal image obtained before contrast enhancement depicts a well-marginated sellar mass, a Rathke
cleft cyst, extending into the suprasellar cistern. Note that the mass has homogeneous high signal intensity relative to the brain
parenchyma., T2-weighted axial image shows the mass, a Rathke cleft cyst, is isointense relative to the cortex., After contrast
enhancement, no significant enhancement is seen in the Rathke cleft cyst. Note the normally enhancing pituitary infundibulum
dorsal to the mass.
Figure 14. T1-weighted sagittal image obtained before contrast enhancement demonstrates a well-defined Rathke cleft cyst in
the sella that is isointense relative to the cerebrospinal fluid. Note the normal high signal intensity in the posterior pituitary,
which is draped over the dorsal aspect of the cyst., The Rathke cleft cyst is isointense relative to the cerebrospinal fluid, as
shown on this coronal proton density–weighted image obtained through the sellar region. The mass effect on the optic chiasm
is well depicted., T1-weighted coronal image shows a subcentimeter Rathke cleft cyst in the central part of the sella. The cyst is
slightly hyperintense relative to cerebrospinal fluid.
12. Figure 15. Coronal T1-weighted contrast-enhanced image shows a nonenhancing hypointense Rathke cleft cyst adjacent to the
homogeneously enhancing pituitary gland., On this T2-weighted coronal image, the Rathke cleft cyst is isointense relative to
cerebrospinal fluid., The variable appearance of Rathke cleft cyst is readily demonstrated on this image. A large, lobulated,
and well-marginated cystic mass is centered in the sella turcica, extending both in a suprasellar plane and into the sphenoid
and ethmoid sinus regions. This lesion is hyperintense relative to cerebrospinal fluid on this T1-weighted sagittal image; this
signal intensity likely reflects its high protein content.
Figure 16. The Rathke cleft cyst is hyperintense relative to cerebrospinal fluid on this axial proton density–weighted image.
Note expansion of the sella with lateral deviation of the mildly effaced but patent cavernous internal carotid arteries., T2-
weighed axial image demonstrates a large hyperintense Rathke cleft cyst., T1-weighted axial gadolinium-enhanced image
demonstrates no enhancement of the Rathke cleft cyst.
The majority of these lesions are asymptomatic. When symptomatic in children, there may be deficiencies of growth hormone
or prolactin. [112] These cysts may contain serous or mucoid material. They rarely contain calcification and usually do not
enhance. On CT, the cysts are similar to cerebrospinal fluid in attenuation. On MR imaging, the appearance of the cyst is
variable depending on its contents. T1 images often show isointensity to hyperintensity compared with cerebrospinal fluid and
isointensity to hypointensity or hyperintensity compared with cerebrospinal fluid on T2 images. [24,64,75] The differential
diagnoses for these lesions include craniopharyngioma, cystic or hemorrhagic pituitary adenoma, partially empty sella, and
arachnoid or pituitary cyst.
Hypothalamic Hamartoma
The most common neuroendocrine presentation with hypothalamic hamartoma is precocious puberty. These lesions represent
mature ganglionic tissue and are located between the pituitary stalk and mammary bodies involving the region of the tuber
cinereum. Often the patients are boys, and the presenting symptoms include precocious puberty, gelastic seizures,
hyperactivity, and developmental delay. [10] A subgroup of patients have hypothalamic hamartoma and associated congenital
anomalies, including hypoplasia of the olfactory bulbs, absence of the pituitary gland, cardiac and renal anomalies,
imperforate anus, craniofacial anomalies, syndactyly, and a short metacarpal (Pallister-Hall syndrome). [92] These patients
commonly have hypopituitarism related to hypothalamic deficiency. [99] The transmission of the disease has been linked to
chromosome 7 with autosomal dominance. [55]
13. Figure 17. Hypothalamic Hamartoma
On imaging, hypothalamic hamartomas do not show invasion, growth, or enhancement. [18,71] On CT, there is a suprasellar
mass, which is isodense with gray matter, noncalcified, and rarely cystic. On MR imaging, the lesion is well defined within or
adjacent to the tuber cinereum or mammary bodies. The hamartomas are Tl isointense and T2 isointense to slightly
hyperintense to gray matter. [15,18,20] The differential diagnosis includes hypothalamic glioma or ganglioglioma.
Pituitary Adenoma
Pituitary adenomas are uncommon in childhood and represent less than 3% of all intracranial tumors. [46,83] The clinical
presentation depends on tumor size, hormonal activity, and extrasellar extent. Clinical manifestations include delayed onset of
puberty, galactorrhea, primary or secondary amenorrhea, gigantism, and hypercortisolism. Symptoms such as headache or
visual symptoms related to mass effect also may occur.
Figure 18. Nonfunctioning pituitary adenomas with suprasellar extension
14. Figure 19. Sagittal view of the brain in a patient with acromegaly. Notice
the very large tumor that had grown above the sella turcica and had
extended into the third ventricle. Notice the presence of hemorrhage
within the tumor. This is what is known as quot;pituitary apoplexiaquot; a
devastating neurological catastrophy with the onset of sudden blindness
and frequently resulting in death
Pituitary adenomas are divided into hormonally active and inactive types. The majority of pituitary adenomas are hormonally
active and commonly prolactin secreting. Rarely, growth hormone-secreting or ACTH-secreting adenomas may occur.
Occasionally, mixed secretary tumors can occur. Approximately 25% of pituitary adenomas are nonfunctioning. [66] The
majority of pediatric pituitary adenomas occur in adolescence, are often microadenomas (<l cm), and are most often
prolactinomas. Adenomas associated with Cushing's syndrome, although rare in childhood, are usually small in size. On
occasion, patients with Cushing's syndrome may require petrosal venous sampling for localizing the source of ACTH secretion,
particularly when the MR imaging scan has been equivocal or negative. [32] Macroadenomas are greater than 1 cm in
diameter and are often prolactinomas. These patients may present with headache, visual field deficits, and neuroendocrine
symptoms. The majority of the macroadenomas in adolescence are hemorrhagic and often occur in boys. Hemorrhagic
macroadenomas may mimic other tumors, such as craniopharyngioma and Rathke's cleft cyst, on MR imaging because they
often have similar signal characteristics (i.e., Tl and T2 high intensity ). [87]
Pituitary apoplexy caused by sudden enlargement in a pituitary tumor secondary to hemorrhage and infarction is rarely
reported in childhood. [93,91] It is characterized by clinical findings of parasellar structural compression and meningeal
irritation after pituitary hemorrhage and infarction, including headache, ophthalmoplegia, and visual impairment. [22]
Imaging of pituitary adenomas is best done with high-resolution thin section MR imaging. [86] In the majority of cases, the
lesion is Tl hypointense. Less frequently, the adenomas are Tl isointense or hyperintense. [61] The Tl hyperintensity is often
related to the presence of intratumoral hemorrhage, which usually occurs in macroadenomas or in patients undergoing
bromocriptine therapy. [118] On T2- weighted MR imaging, the adenomas are often hyperintense or isointense, and
macroadenomas are usually hyperintense. [61] Occasionally, stalk deviation away from the adenoma or upward convexity of
the gland is seen. Macroadenomas may invade the cavernous sinuses or extend superiorly into the suprasellar cistern to
compress the optic chiasm. Gadolinium administration with a rapid bolus may improve lesion detection, particularly when the
conventional MR imaging scan is negative. [15,711] Immediately after gadolinium administration, the lesion is hypointense
compared with the normal gland.
Arachnoid Cyst
Arachnoid cysts are usually congenital arachnoid lesions. Those arising in the suprasellar region account for 10% to 15% of
all arachnoid cysts. [10,113] Suprasellar arachnoid cysts often arise from the membrane of Lilliquist. [63] Clinical findings
may include precocious puberty, hypopituitarism, headache, seizures, and symptoms related to compression of adjacent
structures or hydrocephalus. On CT and MR imaging, the cysts are of cerebrospinal fluid density and intensity, unless there is
associated hemorrhage. There is no calcification or enhancement. The differential diagnosis includes dermoid-epidermoid and
fibrillary astrocytoma. Differentiation is provided by MR imaging, including the use of FLAIR and diffusion imaging.
15. Figure 20. Arachnoid cyst in a 14-year-old boy with headache. Sagittal Tl -weighted MR image demonstrates a sellar and
suprasellar cyst that is isointense to CSF on all sequences and causes hydrocephalus.
Germinoma
The germinomas in the suprasellar region account for 35% of all intracranial germinomas. [10] Often, these patients present
with central diabetes insipidus, wasting, precocious puberty, or growth failure. As compared with other germ cell tumors, pure
germinomas are rarely associated with elevated cerebrospinal fluid or serum a fetoprotein or human chorionic gonadotropin.
On imaging, a mass may be seen involving the suprasellar region, or there may be thickening of the infundibulum. On CT,
these lesions are well defined and slightly hyperdense. On MR imaging, they are Tl hypointense, T2 hypointense, and
markedly enhancing. There is usually no associated cyst or calcification. Cerebrospinal fluid seeding is not uncommon. On
occasion, there may be an associated pineal region germinoma. It is often unclear whether this represents metastatic disease or
a synchronous lesion.
Suprasellar germinomas often present with central diabetes insipidus. On MR imaging, the normally seen posterior pituitary
bright spot is absent. [25,105] Central diabetes insipidus and the absence of the posterior bright spot may precede other
clinical and imaging features of hypothalamic tumor by months or years. Therefore follow- up MR imaging with gadolinium is
recommended in all of these patients. [5]
The normal posterior pituitary hyperintensity may be absent in patients with central diabetes insipidus, nephrogenic diabetes
insipidus, pituitary dwarfism (ectopic posterior pituitary), and sellar or parasellar tumors. [5,34,44,45,56,94] The mechanism
of central diabetes insipidus is thought to be the interruption of transport of the vasopressin neurosecretory granules along the
hypothalamic-neurohypophyseal pathway. The mechanism in nephrogenic diabetes insipidus is the exhaustion of the ADH
stores from oversecretion as a result of end-organ failure from renal tubular disease.
Teratomas and Other Germ Cell Tumors
Teratomas are rare in the suprasellar region when compared with germinomas. They more commonly occur in the pineal
region. They contain components of all three germ cell layers. When in the suprasellar region, they often occur in boys and
may present with hypothalamic symptoms, including precocious puberty. [57] These tumors may produce u-fetoprotein and
human chorionic gonadotropin. They are classified as mature or immature depending on whether the tissue components
resemble mature adult tissues or immature embryonic tissues. On CT and MR imaging, the mass often contains fat, bone, or
cartilage with heterogeneous density and intensity characteristics. [12] Other nongerminomatous germ cell tumors that may
arise in the hypothalamic region include choriocarcinoma, embryonal carcinoma, and endodermal sinus tumor.
16. Figure 21. Parasellar teratoma A, T1
weighted sagital MRI reveals a mixed
signal mass in the suprasellar region, with
extension into the sella, interpeduncular
cystern and inferior third ventricle. B, T1
weighted axial MRI after gadolinium
reveals heterogeneous enhancement. C,
T2 weighted axial MRI shows
heterogeneous high signalin the tumor.
Dermoid and Epidermoid Cysts
Epidermoid cysts in the suprasellar or parasellar region are rare. [53] The majority occur in the middle cranial fossa, calvaria,
or cerebellopontine angle cistern. They are of ectodermal origin, are lined with stratified squamous epithelium, and often
contain cellular debris and keratinous material. A slowly expanding mass results from progressive exfoliation of keratinized
cholesterol-rich material into the interior of the cyst. Clinical symptoms result from mass effect and may include visual
symptoms. Endocrinologic symptoms are rare. [117] On CT, epidermoid cysts appear similar to cerebrospinal fluid. On MR
imaging, the cysts are Tl isointense or mildly hyperintense to cerebrospinal fluid. Fine linear septations may be present. In
some cases, the cysts may be hyperintense to cerebrospinal fluid on the proton density images, although they may follow
cerebrospinal fluid on all MR imaging sequences and mimic arachnoid cyst. [63] They are differentiated by FLAIR or
diffusion imaging.
Dermoid cysts are also of ectodermal origin and contain elements derived from skin appendages, such as hair, sebaceous
glands, and sweat glands. They may contain teeth or calcification. Although commonly found in the posterior fossa or spine,
they may also occur in the suprasellar region. Symptoms result from local mass effect. On CT and MR imaging, the dermoid
cyst is heterogeneous in appearance depending on the presence of gland secretions and calcification. Contrast enhancement is
unusual, unless there is an inflammatory reaction or a complicating infection, such as dermal sinus with dermoid and abscess.
As with epidermoid cysts, if a dermoid cyst ruptures, a chemical meningitis may occur, and Tl hyperintense droplets may be
seen within the basal cisterns or ventricles. [79]
17. Figure 22. Epidermoid cyst in a 12-year-
old girl. Axial unenhanced CT image (A)
demonstrates a low density suprasellar
mass. Sagittal Tl -weighted MR image
(B) demonstrates a low intensity cyst that
is slightly hyperintense to CSF.
Langerhans' Cell Histiocytosis
Patients with systemic Langerhans' cell histiocytosis may have involvement of the pituitary stalk and hypothalamus. [73] These
patients often present with diabetes insipidus, and MR imaging shows loss of the normal posterior pituitary bright Spot.
[105,108] MR imaging may demonstrate a solitary mass in the region of the median eminence of the pituitary stalk or
thickening of the infundibulum. On CT, the mass is often isodense, and on MR imaging, the lesion is T1 isointense and T2
hyperintense. After gadolinium administration, there is marked enhancement.
Figure 23. Langerhans' Cell Histiocytosis, Sagittal section, T1-weighted: inhomogenously thickened pituitary stalk with
impingement of the optic chiasm (arrow), small anterior pituitary lobe, missing bright spot, cystic pineal gland change, and
atrophy of the upper vermis.
18. Figure 24. Langerhans' cell histiocytosis in a young woman with diabetes
insipidus. Sagittal Tl-weighted MR image after gadolinium demonstrates
enhancing suprasellar mass. There is absence of the posterior pituitary
bright spot.
Figure 25. Hypothalamic histiocytosis.
INFECTIOUS AND INFLAMMATORY DISORDERS
The most common infectious process associated with a neuroendocrine disorder in childhood is meningitis, which may be
bacterial, viral, or granulomatous. Rarely, pituitary- hypothalamic dysfunction results from other inflammatory processes,
such as lymphocytic hypophysitis, tuberculosis, or sarcoidosis.
Lymphocytic Hypophysitis
Lymphocytic hypophysitis is a rare inflammatory disorder of the pituitary gland often found in women during late pregnancy
or the postpartum period. [7,104] This disorder, which is thought to be autoimmune, has been described in children, often
adolescents. [23,50] It is characterized by destruction and lymphocytic infiltration of the pituitary gland. Clinical symptoms
include anterior pituitary dysfunction, elevated prolactin, and diabetes insipidus. [95] On CT and MR imaging, there is diffuse
enlargement of the pituitary gland, thickening of the infundibulum, or a pituitary mass. [95] There may be involvement of the
cavernous sinuses as well as absence of the posterior pituitary bright spot. On MR imaging, the lesions are T1 isointense with
mild heterogeneity, are T2 hypointense, and enhance heterogeneously. [95] Dynamic MR imaging may show a delay in
hypophyseal vascular enhancement because of secondary inflammatory changes. [95]
19. Figure 26. Lymphocytic hypophysitis in a 10-year-old girl with diabetes insipidus and growth hormone deficiency. Sagittal Tl-
weighted MR image before (A) and after (B) gadolinium demonstrates diffuse enlargement of the pituitary gland, thickening of
the infundibulum, absence of posterior pituitary bright spot, and heterogeneous enhancement.
Tuberculosis
Tuberculosis as a cause of a neuroendocrine disorder is rare. Tuberculous meningitis may result in extensive involvement of
the basilar cisterns, which can lead to a basal arteritis and subsequent infarction. On both CT and MR imaging, there is
marked enhancement of the basilar cisterns, including the suprasellar cistern. Parenchymal lesions may be single or multiple
and often involve the cortical, subcortical, or basal ganglia structures. With contrast material, these lesions may show ring or
nodular enhancement.
Figure 27. A, Postmortem case of hypothalamic tuberculoma. B, Tuberculous infection of the hypothalamus (arrow)
Sarcoidosis
Sarcoidosis is rare in childhood. In 5% of patients with sarcoidosis, there may be central nervous system involvement,
including involvement of the hypothalamus, infundibular stalk, pituitary gland, meninges, and cranial nerves as well as the
brain parenchyma. Patients may present with cranial nerve deficits.
20. Twenty percent of the patients with neurologic disease may have diabetes insipidus, aseptic meningitis, or anterior pituitary
deficiencies. [33,63,69] On CT, the lesions are often hyperdense and enhance. There may be associated hydrocephalus. On MR
imaging, the lesions are Tl isointense, are T2 hypointense, and homogeneously enhance. [49]
Figure 28. Parasellar neurosarcoidosis. A patient presented with right-sided visual loss, panhypopituitarism, polydipsia, and
polyuria (with normal ADH). A and B, T1-weighted contrast-enhanced MR image (400/15/2) (A) shows basal meningeal
enhancement and an enhancing pituitary mass involving both lobes, the infundibulum, and the right optic nerve (not shown).
Pituitary and meningeal biopsy revealed noncaseating granulomas with negative AFB and fungal stains. The visual symptoms
resolved with steroid treatment; however, 21 months later she returned with a left abducens palsy. A T1-weighted image
(400/12/2) shows resolution of the pituitary lesion but new involvement of the left cavernous sinus (arrows, B).
References
1. Abrahams jj, Trefelnar E, Boulware S: Idiopathic growth hormone deficiency: MR findings in 35 patients. AJNR Am j
Neuroradiol 12:155-160,1991
2. Addy DP, Hudson FP: Diencephalic syndrome of infantile emaciation: Analysis of literature and report of further 3 cases.
Arch Dis Child 47:338-343, 1972
3. Aicardi J, Goutieres F: The syndrome of absence of the septum pellucidum with porencephalies and other developmental
defects. Neuropediatrics 12:319-329, 1981
4. Aoki S, Barkovich Aj, Nishimura K, et al: Neurofibromatosis types 1 and 2: Cranial MR findings. Radiology 172:527-
534,1989
5. Appignani B, Landy H, Barnes P: MR in idiopathic central diabetes insipidus of childhood. AJNR Am J Neuroradiol
14:1407-1410,1993
6. Argyropoulou M, Perignon F, Brunelle F, et al: Height of normal pituitary gland as a function of age evaluated by magnetic
resonance imaging in children. Pediatr Radiol 21:247-249, 1991
7. Asa SL, Bilbao JM, Kovacs K, et al: Lymphocytic hypophysitis of pregnancy resulting in hypopituitarism: A distinct
clinicopathologic entity. Ann Intem Med 95:166-171, 1981
21. 8. Asa SL, Kovacs K: Functional morphology of the human fetal pituitary. Pathol Ann 19(pt 1):275-315, 1984
9. Barkovich A, Fram E, Norman D: Septooptic dysplasia: MR imaging. Radiology 171:189-192,1989
10. Barkovich AJ: Pediatric Neuroimaging, ed 2. New York, Raven Press, 1995, pp 236-237
11, Barkovich Aj, Norman D: Absence of the septum pellucidum: A useful sign in the diagnosis of congenital brain
malformations. AJR Am j Roentgenol 152:353- 360,1989
12. Barnes P, Kupsky W, Strand R: Cranial and intracranial tumors. In Wolpert S, Barnes P (eds): MRI in Pediatric
Neuroradiology. St. Louis, Mosby-Year book, 1992, pp 243-246
13. Barnes P, Robson C, Robertson R, et al: Pediatric orbital and visual pathway lesions. Neuroimaging Clin North Am 6:179-
198,1996
14. Barnes P, Urion D, Share J: Clinical principles of pediatric neuroradiology. In Wolpert S, Barnes P (eds): MRI in Pediatric
Neuroradiology. St. Louis, Mosby- Year Book, 1992, pp 78-80
15. Barral V, Brunelle F, Brauner R, et al: MRI of hypothalamic hamartomas in children. Pediatr Radiol 18:449-452,1988
16. Blethen S: Hypopituitarism. In Lifshitz F (ed): Pediatric Endocrinology: A Clinical Guide. New York, Marcel Dekker,
1996, pp 19-32
17. Bode H, Crawford J, Danon M: Disorders of antidiuretic hormone homeostasis: Diabetes insipidus and SIADH. In Lifshitz
F (ed): Pediatric Endocrinology: A Clinical Guide. New York, Marcel Dekker, 1996, pp 731-751
18. Boyko OB, Curnes JT, Oakes Wj, et al: Hamartomas of the tuber cinereum: CT, MR, and pathologic findings. AJNR Am j
Neuroradiol 12:309-314,1991
19. Brodsky M, Glasier C: Optic nerve hypoplasia: Clinical significance of associated central nervous system abnormalities on
magnetic resonance imaging. Arch Ophthalmol 111:66-74,1993
20. Burton EM, Ball WS Jr, Crone K, et al: Hamartoma of the tuber cinereum: A comparison of MR and CT findings in four
cases. AJNR Am j Neuroradiol 10:497-501, 1989
21. Cacciari E, Zucchini S, Ambrosetto P, et al: Empty sella in children and adolescents with possible hypothalamic-pituitary
disorders. j Clin Endocrinol Metab 78:767-771, 1994
22. Cardoso ER Peterson EW: Pituitary apoplexy: A review. Neurosurgery 14:363-373,1984
23. Cemeroglu AP, Blaivas M, Muraszko KM, et al: Lymphocytic hypophysitis presenting with diabetes insipidus in a 14-year-
old girl: Case report and review of the literature. Eur j Pediatr 156:684-688, 1997
24. Christophe C, Flamant-Durand J, Hanquinet S, et al: MRI in seven cases of Rathke's cleft cyst in infants and children.
Pediatr Radiol 23:79-82, 1993
25. Colombo N, Berry I, Kucharczyk J, et al: Posterior pituitary gland: Appearance on MR images in normal and pathologic
states. Radiology 165:481-485, 1987
26. Costigan DC, Daneman D, Harwood-Nash D, et al: The quot;empty sellaquot; in childhood. Chn Pediatr (Phila) 23:437-440,1984
27. Cox TD, Elster AD: Normal pituitary gland: Changes in shape, size and signal intensity during the I st year of life at MR
imaging. Radiology 179:721-724,1991
28. Danziger J, Bloch 5: Hypothalamic tumours presenting as the diencephahc syndrome. C Radiol 25:153-156,1974
29. DeMorsier G: Etudes sur les dysraphics cranio-encephaliques 111. Agenese du septum lucidum avec malformation du
tractus optique. La dysplasie septo- optic. Schweiz Arch Neurol Neurochir Psychiatry 77:267-292,1956
22. 30. DeSousa AL, Kalsbeck JE, Mealey J, et al: Diencephalic syndrome and its relation to opticochiasmatic glioma: Review of
twelve cases. Neurosurgery 4:207- 209,1979
31. Dietrich RB, Lis LE, Grgensite FS, et al: Normal MR appearance of the pituitary gland in the first 2 years of life. AJNR
Am j Neuroradiol 16:1413 -1419, 1995
32. Doppman J, Oldfield E, Krudy A, et al: Petrosal sinus sampling for Cushing syndrome: Anatomical and technical
considerations. Radiology 150:99-153,1984
33. Egeloff J: Infections of the central nervous system. In Ball W (ed): Pediatric Neuroradiology. Philadelphia, Lippincott-
Raven, 1997, pp 273-318
34. el Gammal T, Brooks BS, Hoffman WH: MR imaging of the ectopic bright signal of posterior pituitary regeneration.
AJNR Am j Neuroradiol 10:323-328, 1989
35. Elster A: Modem imaging of the pituitary. Radiology 187:1-14,1993
36. Elster AD, Chen MYM, Williams DWI, et al: Pituitary gland: MR imaging of physiologic hypertrophy in adolescence.
Radiology 174:681 -685, 1990
37. Falcone S, Sanchez J, Quencer R: Lack of normal MR enhancement of the pituitary gland: Findings in three siblings with
combined pituitary hormone deficiency. AJNR Am j Neuroradiol 19:287-289,1998
38. Fitz C: Holoprosencephaly and related entities. Neuroradiology 25:3-238, 1983
39. Fitz CR: Holoprosencephaly and septo-optic dysplasia. Neuroimaging Clin North Am 4:263-281, 1994
40. Franco B, Guioli S, Pragliola A, et al: A gene deleted in Kallmann's syndrome shares homology with neural cell adhesion
and axonal path-finding molecules. Nature 353:529-536,1991
41. Frasier SD: Tall stature and excessive growth syndromes. In Lifshitz F (ed): Pediatric Endocrinology: A Clinical Guide.
New York, Marcel Dekker, 1996, pp 163-174
42. Fujisawa I, Asato R, Nishimura K, et al: Anterior and posterior lobes of the pituitary gland: Assessment by 1.5 T MR
imaging. J Comput Assist Tomogr 11:214- 220,1987
43. Fujisawa 1, Kikuchi K, Nishimura K, et al: Transection of the pituitary stalk: Development of an ectopic posterior lobe
assessed with MR imaging. Radiology 165:487-489,1987
44. Fujisawa I, Nishimura K, Asato R, et al: Posterior lobe of the pituitary in diabetes insipidus: MR findings. J Comput Assist
Tomogr 11:221-225,1987
45. Gudinchet F, Brunelle F, Barth MO, et al: MR imaging of the posterior hypophysis in children. AJR Am J Roentgenol
153:351-354,1989
46. Haddad S, VanGilder J, Menezes A: Pediatric pituitary tumors. Neurosurgery 29:509-514, 1991
47. Hale BR, Rice P: Septo-optic dysplasia: Clinical and embryological aspects. Dev Med Child Neurol 16: 812-817,1974
48. Harwood-Nash D, Fitz C: Neuroradiology in Infants and Children. St. Louis, CV Mosby, 1976, pp 484-486
49. Hayes W, Sherman J, Stern B, et al: MR and CT evaluation of intracranial sarcoidosis. AJR Am j Roentgenol 149:1043-
1049, 1987
50. Heze Hj, Bercu BB: Acquired hypophysitis in adolescence. j Pediatr Endocrinol Metab 10:315-321, 1997
51. Izenberg N, Rosenblum M, Parks JS: The endocrine spectrum of septo-optic dysplasia. Clin Pediatr (Phila) 23:632-636,
1984
23. 52. Jacobson R, Abrams G: Disorders of the hypothalamus and pituitary gland in adolescence and childhood. In Swaiman K
(ed): Pediatric Neurology. St. Louis, Mosby, 1994, pp 749-786
53. Jones B, Patterson R: Supratentorial tumors. Iii Ball W (ed): Pediatric Neuroradiology. Philadelphia, Lippincott-Raven,
1997, pp 369-442
54. Kallmann F, Schoenfeld WI Barrera S: The genetic aspects of primary eunuchoidism. Am j Ment Defic 48:203-236,1944
55. Kang S, Allen J, Graham JM Jr, et al: Linkage mapping and phenotypic analysis of autosomal dominant Pallister-Hall
syndrome. J Med Genet 34:441-446, 1997 -
56. Kelly WM, Kucharczyk W, Kucharczyk J, et al: Posterior pituitary ectopia: An MR feature of pituitary dwarfism. AJNR
Am j Neuroradiol 9:453-460,1988
57. Kitanaka C, Matsutani M, Sora S, et al: Precocious puberty in a girl with an hCG-secreting suprasellar immature
teratoma: Case report. J Neurosurg 81:601 - 604,1994
58. Kollias S, Ball W: Congenital malformations of the brain. In Ball W (ed): Pediatric Neuroradiology. Philadelphia,
Lippincott-Raven, 1997, pp 91-174
59. Kollias S, Barkovich A, Edwards M: Magnetic resonance analysis of suprasellar tumors of childhood. Pediatr Neurosurg
17:284-303, 1991-1992
60. Kucharczyk J, Kucharczyk W, Berry 1, et al: Histochemical characterization and functional significance of the
hyperintense signal on MR images of the posterior pituitary. AJR Am J Roentgenol 152:153-157, 1989
61. Kucharczyk W, Davis D, Kelly W, et al: Pituitary adenoma: High resolution MRI at 1.5 T. Radiology 161:761-765,1986
62. Kucharczyk W, Lenkinski RE, Kucharczyk J, et al: The effect of phospholipid vesicles on the NMR relaxation of water: An
explanation for the MR appearance of the neurohypophysis? AJNR Am j Neuroradiol 11:693-700, 1990
63. Kucharczyk W, Montanera W, Becker L: The sella turcica and parasellar region. In Atlas S (ed): Magnetic Resonance
Imaging of the Brain and Spine. Philadelphia, Lippincott-Raven, 1996, pp 872-930
64. Kucharczyk W, Peck W, Kelly W, et al: Rathke cleft cysts: CT, MR imaging and pathologic features. Radiology 165:491-
496,1987
65. Kuroiwa T, Okabe Y, Hasuo K, et al: MR imaging of pituitary dwarfism. AJNR Am J Neuroradiol 12:161 - 164,1991
66. Laws E, Sheithauer B, Groover R: Pituitary adenomas in childhood and adolescence. Prog Exp Tumor Res 30:359-361,
1987
67. Lee P: Normal ages of pubertal events among American males and females. j Adolesc Health Care 1:26- 29, 1980
68. Lee P: Disorders of puberty. In Lifshitz F (ed): Pediatric Endocrinology: A Clinical Guide. New York, Marcel Dekker,
1996, pp 175-195
69. Lewis R Wilson J, Smith F; Diabetes insipidus secondary to intracranial sarcoidosis confirmed by lowfield MRI. Magn Res
Med 5:466-470,1987
70. Lifshitz F, Cervantes C: Short stature. In Lifshitz F (ed): Pediatric Endocrinology: A Clinical Guide. New York, Marcel
Dekker, 1996, pp 1-18
71. Lin S-R, Bryson M, Goblen R, et al; Radiologic findings of hamartomas of the tuber cinereum and hypothalamus.
Radiology 127:697- 703, 1978
72. Loes DJ, Barloon Tj, Yuh WT, et al: MR anatomy and pathology of the hypothalamus. AJR Am J Roentgenol 156:579-585,
1991
24. 73. Maghnic M, Arico M, Villa A, et al: MR of the hypothalamic-pituitary axis in Langerhans cell histiocytosis. AJNR Am j
Neuroradiol 13:1365-1371, 1992
74. Miki Y, Asato R, Okumura R, et al: Anterior pituitary gland in pregnancy: Hyperintensity at MR. Radiology 187:229-231,
1993
75. Mize W, Ball WS Jr, Towbin RB, et al: Atypical CT and MR appearance of a Rathke cleft cyst. AJNR Am j Neuroradiol 10
(5 suppl):S83-84,1989
76. Morishima A, Aranoff G: Syndrome of septooptic- pituitary dysplasia: The clinical spectrum. Brain Dev 8:233-239,1986
77. Nass R, Engel M, Stoner E, et al: Empty sella syndrome in childhood. Pediatr Neurol 2:224-229, 1986
78. Newton D, Dillon W, Norman D, et al: GD-DTPA- enhanced MR imaging of pituitary adenomas. AJNR Am j Neuroradiol
10:949-954,1989
79. Newton D, Larson T1, Dillon W, et al: Magnetic resonance characteristics of cranial epidermoid and teratomatous tumors.
AJNR Am j Neuroradiol 8:945, 1987
80. Nishi Y. Hereditary growth hormone deficiency and growth hormone insensitivity syndrome. In Lifshitz F (ed): Pediatric
Endocrinology. New York, Marcel Dekker, 1996, pp 33-44
81. Ohta K, Nobukuni Y, Mitsubuchi H, et al: Mutations in the Pit-I gene in children with combined pituitary hormone
deficiency. Biochem Biophys Res Commun 189:851-855, 1992
82. Osborn A: Diagnostic Neuroradiology. St. Louis: Mosby, 1994, pp 465-467
83. Partington M, Davis D, Laws J, et al: Pituitary adenomas in childhood and adolescence: Results of transsphenoidal
surgery. J Neurosurg 80:209-216, 1994
84. Pelc S: The diencephalic syndrome in infants. Eur Neurol 7:321-334,1972
85. Pele S, Flament-Durand J: Histological evidence of optic chiasma glioma in the quot;Diencephalic Syndrome.quot; Arch Neurol
28:139-140,1973
86. Pojunas KW, Daniels DL, Williams AL, et al: MR imaging of prolactin-secreting microadenomas. AJNR Am j Neuroradiol
7:209 -213, 1986
87. Poussaint TY, Barnes P, Anthony D, et al: Hemorrhagic pituitary adenomas of adolescence. AJNR Am j Neuroradiol
17:1907-1912, 1996
88. Poussaint TY, Barnes P, Nichols K, et al: Diencephalic syndrome: Clinical features and imaging findings. AJNR Am j
Neuroradiol 18:1499-1505,1997
89. Pusey E, Kortman KE, Flannigan BD, et al: MR of craniopharyngiomas: Tumor delineation and characterization. AJNR
Am J Neuroradiol 8:439-444, 1987
90. Rorke LB, Gilles FH, Davis RL, et al: Revision of the World Health Organization classification of brain tumors for
childhood brain tumors- Cancer 56(7 suppl):1869-1886,1985
91. Russell A: A diencephalic syndrome of emaciation in infancy and childhood. Arch Dis Child 26:274,1951
92. Russell D, Rubinstein L: Pathology of Tumours of the Nervous System, ed 5. Baltimore, Williams & Wilkins, 1989
93. Sakalas R, David RB, Vines PS, et al: Pituitary apoplexy in a child: Case report. J Neurosurg 39:519-522, 1973
94. Sato N, Ishizaka H, Yagi H, et al: Posterior lobe of the pituitary in diabetes insipidus: Dynamic MR imaging. Radiology
186:357-360, 1993
25. 95. Sato N, Sze G, Endo K: Hypophysitis: Endocrinologic and dynamic MR findings. AJNR Am J Neuroradiol 19:439-
444,1998
96. Schwanzel-Fukuda M, Bick D, Pfaff DW: Luteinizing hormone-releasing hormone (LHRH)-expressing cells do not migrate
normally in an inherited hypegonadal (Kallmann) syndrome. Brain Res Mol Brain Res 6:311 -326, 1989
97. Shah S, Pereira J, Becker C, et at: Pituitary apoplexy in adolescence: Case report. Pediatr Radiol 25:S26- S27, 1995
98. Shulman DI, Martinez CR, Bercu BB, et al: Hypothalamic-pituitary dysfunction in primary empty sella syndrome in
childhood. j Pediatr 108:540-544,1986
99. Sills IN, Rapaport R, Robinson LP, et al: Familial Pallister-Hall syndrome: Case report and hormonal evaluation. Am j
Med Genet 47:321-325, 1993
100. Simmons GE, Suchnicki JE, Rak KM, et al: MR imaging of the pituitary stalk: Size, shape, and enhancement pattern.
AJR Am J Roentgenol 159:375-377, 1992
101. Simon J, Szumowski J, Totterman S, et al: Fat suppression MR imaging of the orbit. AJNR Am j Neuroradiol 9:961-968,
1988
102. Skarf B, Hoyt C: Optic nerve hypoplasia in children: Association with anomalies of the endocrine and CNS. Arch
Ophthalmol 102:62-67,1984
103. Stanhope R, Preece M, Brook C: Hypoplastic optic nerves and pituitary dysfunction: A spectrum of anatomical and
endocrine abnormalities. Arch Dis Child 59:111-114,1984
104. Thodou E, Asa SL, Kontogeorgos G, et al: Clinical case seminar: Lymphocytic hypophysitis: Clinico- pathological
findings. J Clin Endocrinol Metab 80:2302-2311, 1995
105. Tien R, Kucharczyk J, Kucharczyk W: MR imaging of the brain in patients with diabetes insipidus. AJNR Am j
Neuroradiol 12:533-542, 1991
106. Tien RD: Sequence of enhancement of various portions of the pituitary gland on gadolinium-enhanced MR images:
Correlation with regional blood supply. AJR Am J Roentgenol 158:651-654,1992
107. Tien RD, Kucharczyk J, Bessette J, et al: MR imaging of the pituitary gland in infants and children: Changes in size,
shape, and MR signal with growth and development. AJR Am J Roentgenol 158:1151- 1154,1992
108. Tien RD, Newton TH, McDermott MW, et al: Thickened pituitary stalk on MR images in patients with diabetes insipidus
and Langerhans cell histiocytosis. AJNR Am j Neuroradiol 11:703-708,1990
109. Trandafir T, Sipot C, Froicu P: On a possible neural ridge origin of the adenohypophysis. Endocrinologie 28:67-72,1990
110. Triulzi F, Scotti G, di Natale B, et al: Evidence of a congenital midline brain anomaly in pituitary dwarfs: An MR study in
101 patients. Pediatrics 93:409-416,1994
111. Truwit CL, Barkovich Aj, Grumbach MM, et al: MR imaging of Kallmann syndrome, a genetic disorder of neuronal
migration affecting the olfactory and genital systems. AJNR Am J Neuroradiol 14:827-838, 1993
112. Voelker JL, Campbell RL, Muller J: Clinical, radiographic, and pathological features of symptomatic Rathke's cleft cysts.
J Neurosurg 74:535-544, 1991
113. Wiener S, Pearlstein A, Eiber A: MR imaging of intracranial arachnoid cysts. J Comput Assist Tomogr 11:236-241, 1987
114. Williams P, Warwick R, Dyson M, et al: Gray's Anatomy, ed 37. New York, Churchill Livingstone, 1989
115. Wolpert S: Developmental disorders of the pituitary gland. In Wolpert S, Barnes P (eds): MRI in Pediatric
Neuroradiology. St. Louis, Mosby-Year Book, 1992, pp 119-120
26. 116. Wolpert S, Osborne M, Anderson M, et al: The bright pituitary gland: A normal MR appearance in infancy AJNR Am j
Neuroradiol 9:1-13,1988
117. Yamakawa K, Shitara N, Genka S, et al: Clinical course and surgical prognosis of 33 cases of intracranial epidermoid
tumors. Neurosurgery 24:568-573, 1989
118. Yousem D, Arrington J, Zinreich S, et al: Pituitary adenomas: Possible role of bromocriptine in intratumoral
hemorrhage. Radiology 170:239 - 243, 1989
119. Yousem DM, Geckle Rj, Bilker W, et al: MR evaluation of patients with congenital hyposmia or anosmia. AJR Am J
Roentgenol 166:439-443,1996
120. Yousem DM, Turner Wj, Li C, et al: Kallmann syndrome: MR evaluation of olfactory system. AJNR Am j Neuroradiol
14:839- 843, 1993
I am professor Yasser Metwally, Professor of neurology, Ain Shams university Cairo, Egypt.
Visit my web site at: www.yassermetwally.com
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