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Query: UMLS:C0027819 (
neuroblastoma
)
27,800
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Adrenal imaging using radiopharmaceuticals is a functional test that can contribute significantly to surgical management and follow-up of patients with either benign or malignant conditions of the adrenal cortex and medulla. Imaging of the cortex is achieved by iodine-131-labeled iodomethyl nor-cholesterol (NP-59), while adrenal medulla imaging can be successfully accomplished by 131I-metaiodobenzylguanidine (MIBG), which localizes in the adrenergic nerve terminal with norepinephrine. Both tests carry high sensitivity and specificity for functional tumors and hyperplasia, and often better than CT scanning. This article reviews the current status and clinical utility of nuclear imaging of the adrenal cortex in congenital hyperplasia, low renin hypertension and
aldosteronism
, and Cushing's syndrome. Adrenal medulla imaging is reviewed in light of our experience at the University of Texas M.D. Anderson Cancer Center in pheochromocytoma,
neuroblastoma
, and other neuroectodermal tumors. Investigation of 131I-MIBG therapy of metastatic tumors of neuroectodermal origin potentially offers a means of at least controlling symptoms of hormonal secretion in these patients.
...
PMID:Role of adrenal imaging in surgical management. 217 29
Endocrine hypertension secondary to disorders of the adrenal glands is uncommon, but by no means rare. The importance of correct biochemical diagnosis and subsequent localization of the responsible lesion(s) lie in the fact that many of these syndromes occur in younger patients, may exhibit familial patterns of inheritance and are frequently amenable to surgical cure. The radiopharmaceuticals (131)1-6 beta-iodomethyl-19-norcholesterol (NP-59), a marker of adrenocortical cholesterol uptake, and (131)1- and (123)1-metaiodobenzylguanidine (MIBG), a norepinephrine (NE) analog and marker of energy-dependent NE storage vesicle accumulation, can be shown to accurately localize adrenal cortex and sympathoadrenal dysfunction, respectively. In Cushing's syndrome (CS) not only does the pattern of NP-59 uptake depict the adrenal dysfunction and its pathophysiologic basis, but the level of NP-59 accumulation reflects the degree of adrenocortical hyperfunction. Adrenocorticotrophin-independent CS is uniformly and accurately localized, especially in bilateral cortical nodular hyperplasia where even high resolution computed tomography (CT) may fail to depict the often subtle, asymmetric anatomic abnormalities. Dexamethasone suppression NP-59 adrenal scintigraphy has been shown to be highly sensitive and specific, and exceeds the efficacy of CT in the differentiation of adenoma and bilateral hyperplasia in primary
aldosteronism
. MIBG is useful as a sympathoadrenal imaging agent whose clinical utility has been demonstrated in the localization of pheochromocytoma, especially as a modality to screen the body for multiple and extraadrenal, recurrent, or metastatic lesions. Moreover, the extent of metastatic involvement from
neuroblastoma
can also be accurately depicted using MIBG. In this review we will examine the role of adrenal scintigraphy in the characterization of hypersecretory disorders of the adrenal cortex, medulla, and related conditions that produce hypertension as part of their symptom(s) complex. This approach, which is complementary to other anatomical modalities of imaging, can be used to advantage in the localization of functioning cortical and medulla adrenal diseases and other neoplasms of adrenergic origin.
...
PMID:Scintigraphic studies in adrenal hypertension. 265 11
To study the relation of normetanephrine (NM) and metanephrine (M) to norepinephrine (NE) and epinephrine (E), plasma free NM (f-NM), free M (f-M), total NM (t-NM) and total M (t-M) were measured in normal subjects and patients with pheochromocytoma (PHEO),
neuroblastoma
, Cushing's syndrome, primary
aldosteronism
and chronic renal failure (CRF) by radioimmunoassay. Plasma f-NE and E were measured by radioenzymatic assay. Both f- and t-NM were high in PHEO,
neuroblastoma
and CRF. f- and t-M were also high in some patients with PHEO and CRF. Positive correlation was observed not only in f-NE with f-NM and t-NM, but also in f-E with f-M and t-M except for CRF. Although upright posture induced an elevation in f-NE and f-NM, t-NM was unchanged in normal subjects. In patients with PHEO, metoclopramide induced a prompt elevation in f-NE and E but no-change in t-NM and M levels. f-NE, f-E, f-NM, t-NM, f-M and t-M decreased rapidly after the resection of PHEO and reached the normal level on the third day after the surgery. In CRF patients, f-NM, t-NM, f-M and t-M decreased after hemodialysis despite an increase of f-NE. From these results, it was suggested that plasma NM and M levels reflected plasma NE and E to a certain extent in normal subjects and patients with normal renal function, and that the impaired renal function provoked an elevation of plasma NM and M due to the accumulation of them.
...
PMID:[Plasma normetanephrine and metanephrine levels and their relationship to norepinephrine and epinephrine]. 322 Jan 54
This article considers the various imaging modalities that can be used in the diagnosis of adrenal disorders and their relative role in the evaluation of specific adrenal disorders. Modalities discussed include abdominal radiography, nephrotomography, ultrasound, computed tomography, arteriography, venography, adrenal venous sampling, radioisotope scanning, and nuclear magnetic resonance. Disorders dealt with include Cushing's disease, pheochromocytoma, primary
aldosteronism
,
neuroblastoma
, ganglioneuroma, sympathogonioma, and nonfunctioning adrenal tumors.
...
PMID:Diagnosis of adrenal disorders. 637 39
Endocrine and neurological diseases are rare causes of arterial hypertension in childhood. They represent less than 5% of all cases of secondary hypertension. Inflammatory, traumatic, and tumorous disorders of the central nervous system rarely result in chronic hypertension but may frequently be associated with acute hypertensive crisis. The most important hypertensinogenic endocrine diseases are the catecholamine producing tumors pheochromocytoma and
neuroblastoma
and disorders of the adrenal cortex such as Cushing's syndrome,
hyperaldosteronism
, 11-hydroxylase deficiency and other mineralocorticoid excess syndromes. Renin producing tumors, hyperthyroidism and hyperparathyroidism are rare causes of hypertension in children. Neurogenic and endocrine forms of hypertension have contributed considerably to a better understanding of the pathophysiology of blood pressure regulation. They are of particular interest to the pediatrician since specific therapy may be available.
...
PMID:[Endocrine and neurogenic hypertension in childhood]. 666 53
Adrenal disease can be manifested by endocrine dysfunction or anatomic abnormalities detected by cross-sectional imaging modalities. With the advent of newer and more reliable in vitro assays and a better understanding of the spectrum of adrenal pathology, the physician can now adopt a more accurate and cost-effective approach to the diagnosis of adrenal disease. Both functional and anatomic imaging modalities can play an important role in the evaluation of the incidental adrenal mass, the early detection of adrenal metastases, differentiation of the various causes of Cushings's syndrome, selection of patients for potentially curative surgery in primary
aldosteronism
and adrenal hyperandrogenism, and localization of pheochromocytomas and neuroblastomas. The usefulness of the adrenal cortical radiopharmaceutical, 131I-6-beta-iodomethylnorcholesterol (NP-59), and the adrenal medullary radiopharmaceuticals, 131I and 123I-metaiodobenzylguanidine (MIBG), is detailed for these various clinical settings and the role of NP-59 and MIBG is contrasted to that of the cross-sectional modalities, computed tomography and magnetic resonance imaging (MRI). Incidental adrenal masses are common, but malignancies are few. Imaging studies select those patients who require a further evaluation by biopsy examination or adrenalectomy. In the hyperfunctioning endocrine states, such as Cushing's syndrome, primary
aldosteronism
, adrenal androgenism, and pheochromocytoma, correlation of biochemical findings with both functional and anatomic imaging is necessary to avoid inappropriate and ineffective surgical intervention, yet not miss an opportunity for curative resection. Lastly, MIBG and MRI are complementary in the detection and staging of
neuroblastoma
.
...
PMID:Adrenal cortical and medullary imaging. 757 43
In the past decade there have been considerable advances in basic knowledge of the renin-angiotensin system (RAS). The most important new development has been the appreciation of a tissue based RAS that can be independently regulated from the renal and vascular RAS. Greater insight into the mechanism by which angiotension-II (AII) exerts its action has been achieved through the study of molecular biology and pharmacological characterization of multiple receptor subtypes. This review summarises the features and distribution of several binding subtypes that may mediate the diverse functions of AII. Of these AT1 subtype is the most well known receptor which preferentially binds AII and AIII. The AT1 receptor site appears to mediate the classic angiotensin responses concerned with the body water balance and the maintenance of blood pressure. Less is known about the AT2 sites which also bind AII and AIII and may play a role in vascular growth. Recently, an AT3 has been discovered in cultured
neuroblastoma
cells and an AT4 site which preferentially binds AIV. It has been implicated in memory aquisition and retrieval and in the regulation of blood flow. Another important aspect covered is the primary and secondary messengers involved during the signal transduction after the binding of AII with receptors. A stress has also been given on the regulation of density and affinity of AII receptors by various physiological parametres as they affect the responses of RAS. Autoregulation by RAS, salt intake, development and aging and some of the hormones are important variables which could affect the AII receptors. Interactions of AII with various neuroeffector transmission involved in the regulation of water-electrolyte balance and BP regulation play an important role in the maintenance of the homeostasis. AII has been suggested to increase the NAergic transmission by enhancing synthesis, release, inhibiting reuptake by the presynaptic nerve terminals as well as enhancing cell responsiveness to the transmitter. The finding of existence of AII receptors in vagal afferent nerve terminals suggests that its baroreflex inhibitory effect is mediated by inhibiting neurotransmitter release at NTS in the baroreflex arc. Moreover, AII acts on the central receptors to stimulate AVP and ACTH secretion, drinking and peripherally increase synthesis and secretion of aldosterone. Interactions of RAS with kallikrein-kinin system and prostaglandins strongly support the existence of a balance between renal depressor and pressor substances. AII is now considered a growth promotor in cardiovascular tissues and the resultant vascular hypertrophy could contribute in the maintenance of hypertension. AII also plays a role in the kidney, not only as a regulator of hemodynamics but also in the structural changes occurring in a variety of renal disorders. In addition to the more well studied functions of RAS in RVH the review also highlights the potential contribution by the RAS to other clinically relevant syndromes such as aortoarterities induced RVH,
hyperaldosteronism
, heavy metal induced cardiovascular effects, diabetes mellitus and thyroid dysfunction. Although the receptor subtypes involved in these pathological states have not been definitely identified, research efforts in this direction are ongoing.
...
PMID:Angiotensin II--receptor subtypes characterization and pathophysiological implications. 864 21
The historical background at the University of Michigan laid a foundation for the innovative development of radionuclides in diagnosis and treatment of endocrine diseases. From that background, Dr. William Beierwaltes, the chief of Nuclear Medicine, inspired two talented young chemists to synthesize unique radiopharmaceuticals that transformed diagnostic approaches to certain endocrine disorders. Dr. Raymond Counsell's 131-I-radiocholesterol, enabled imaging that defined function in the adrenal cortex, and thereby distinguished the different forms of Cushing's syndrome and of primary
aldosteronism
; in addition, this new technique differentiated benign adrenal cortical adenomas from other adrenal cortical tumors. Dr. Donald Wieland created metaiodobenzlylguanidine (MIBG), a compound that can be tagged with either 131-I or 123-I, and led to the scintigraphic depiction of adrenergic tumors, particularly pheochromocytomas and
neuroblastoma
, anywhere in the body of a patient. Treatments with large doses of MIBG have reduced the malignant forms of pheochromocytomas and brought remissions to children with neuroblastomas. MIBG also concentrated in the autonomic neurons and so the nerves of the heart were also portrayed. Subsequent novel syntheses included positron-emitting nuclides that, through positron emission tomography, have revealed the physiology and altered physiology of the human heart. These men and their discoveries exemplify the creative endeavors that compel us to seek further the wonders of nuclear science.
...
PMID:Radiopharmaceuticals for nuclear endocrinology at the University of Michigan. 1104 Oct 15
