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1 onal-like exocytosis (testes, pituitary, and adrenal gland).
2 n human serum and epidermis, and the porcine adrenal gland.
3 ucing cells of the testis, the ovary and the adrenal gland.
4 ts, 90% of neuroblastomas are located in the adrenal gland.
5 n of the synthetic enzymes for PGE(2) in the adrenal gland.
6 tissue-specific manner, most commonly in the adrenal gland.
7 nism by which SF-1 exerts its actions in the adrenal gland.
8 ation to kidney but not to BAT, hindlimb, or adrenal gland.
9 inimally invasive approach to removal of the adrenal gland.
10 hetic nerve activity to kidney, hindlimb, or adrenal gland.
11 stion from the adrenal medulla of the bovine adrenal gland.
12 n C, such as the hippocampal neurons and the adrenal gland.
13 pinal mediastinum, retroperitoneum, neck and adrenal gland.
14 f pseudorabies virus (PRV) injected into the adrenal gland.
15 ndly perturbs cholesterol homeostasis in the adrenal gland.
16 rtant role in the functional zonation of the adrenal gland.
17 ntrast, decreased MIF protein content in the adrenal gland.
18 , liver, small intestine, kidney, ovary, and adrenal gland.
19 tal secretory events from thin slices of the adrenal gland.
20 inant (PRV-BaBlu) was injected into the left adrenal gland.
21 functioning and nonfunctioning tumors of the adrenal gland.
22 t subsequently metastasized to the liver and adrenal gland.
23 ably enterocytes), the pancreas and also the adrenal gland.
24 through a mechanism affecting primarily the adrenal gland.
25 synthesize cortisol from cholesterol in the adrenal gland.
26 transcript is present in brain, thymus, and adrenal gland.
27 corticosteroids and catecholamines from the adrenal gland.
28 t on medullary but not cortical cells in the adrenal gland.
29 essed genes in zona glomerulosa of the human adrenal gland.
30 atterns in different functional zones of the adrenal gland.
31 the 61 observed SFCs (82%) found in the left adrenal gland.
32 etagamma signaling in both the heart and the adrenal gland.
33 gnals that could affect transcription in the adrenal gland.
34 B) were seen in the lung, liver, kidney, and adrenal gland.
35 including the peripheral nervous system and adrenal gland.
36 cyclic GMP production in the kidney and the adrenal gland.
37 are controlled by CREM/ICER in the liver and adrenal gland.
38 d on 10 ACC, 6 benign adenomas, and 1 normal adrenal gland.
39 ive steroid hormones, mainly produced by the adrenal glands.
40 er food restriction were dependent on intact adrenal glands.
41 y have a role in ROS detoxification in human adrenal glands.
42 ng in the release of corticosterone from the adrenal glands.
43 and human brain and in the bovine liver and adrenal glands.
44 ons including the central nervous system and adrenal glands.
45 between adrenal glands with PHEO and normal adrenal glands.
46 omas, and one undetermined) and seven normal adrenal glands.
47 lowed by focal hemorrhaging of the ileum and adrenal glands.
48 rs agreed on visualization of 27 of 40 (68%) adrenal glands.
49 ting glucocorticoid hormone synthesis in the adrenal glands.
50 well as studies on metastatic disease to the adrenal glands.
51 s, indicating release of these steroids from adrenal glands.
52 tional tissue that replaces the animals' own adrenal glands.
53 findings of massively enlarged multinodular adrenal glands.
54 as, in their sympathetic nervous systems and adrenal glands.
55 enzymes, were severely reduced in postnatal adrenal glands.
56 nucleus of the amygdala, independent of the adrenal glands.
57 ects are dependent on both the pituitary and adrenal glands.
58 ates the production of catecholamines in the adrenal glands.
59 lipids in the different functional zones of adrenal glands.
60 ction of corticotropin in these hyperplastic adrenal glands.
61 med for reasons other than the evaluation of adrenal glands.
63 697 (42.9%) in the liver, 138 (8.5%) in the adrenal glands, 38 (2.3%) in the pancreas, 109 (6.7%) in
69 FCs in the left adrenal gland than the right adrenal gland and 50 of the 61 observed SFCs (82%) found
71 -derived secosteroids in the skin, serum and adrenal gland and based on their concentrations and biol
75 holamines are produced in the medulla of the adrenal gland and may participate in the intraglandular
76 was imaged at 150-200 mum resolution in rat adrenal gland and mouse brain sections and confirmed wit
77 NB) is a childhood cancer that arises in the adrenal gland and often shows differentiated neuronal an
79 nance imaging excluded common lesions of the adrenal gland and showed lymphadenopathy around the majo
81 shed beta4, alpha3, and alpha5 expression in adrenal gland and to a lesser extent in the superior cer
83 g 2DG; 70.3% +/- 1.8% of SPN innervating the adrenal glands and 37.4% +/- 3% of SPN innervating celia
85 in the paraventricular nucleus, hypoplastic adrenal glands and decreased stress-induced corticostero
86 e determined with nonenhanced CT through the adrenal glands and does not substantially influence mana
87 In summary, GX sPLA(2) is expressed in mouse adrenal glands and functions to negatively regulate cort
89 ous system accounts for (a) primary sites in adrenal glands and in paraspinal locations from neck to
90 astatic spread of the tumor to the liver and adrenal glands and increased the median survival time of
91 oping genitourinary tract, heart, spleen and adrenal glands and is crucial for their development, how
92 curs in spontaneously hypertensive rat (SHR) adrenal glands and plasma, but central expression is une
93 253 (64%), 70 (18%), and 71 (18%) of the 394 adrenal glands and reader 2 classified 258 (65%), 45 (11
94 helical CT from the lung apices through the adrenal glands and then contrast-enhanced thoracic helic
96 crease in aldosterone synthase expression in adrenal gland, and a two-fold decrease in renin expressi
97 f corticosterone, as well as similar thymus, adrenal gland, and body weights, suggesting that variabl
99 in selected tissues, such as lens, brain and adrenal gland, and its degradation products can inflict
102 isseminated form usually involves the liver, adrenal gland, and lung, and resembles the clinical pict
103 brain (33.6% v 23.0%; P =.004), bone marrow, adrenal gland, and pericardium (24.7% v 15.9%; P =.004).
105 e exception of low concentrations in rectum, adrenal gland, and thymus from a single patient with vCJ
111 ncers and hypervascular tumors of the brain, adrenal glands, and pancreas as well as erythrocytosis.
113 It is expressed in the hypothalamus, the adrenal glands, and the testis, but sequences determinin
118 of Gbetagamma signaling in the heart and the adrenal gland as a novel therapeutic approach for heart
119 t viability and function, and we explore the adrenal gland as an alternative transplantation site for
120 classified the morphologic features of each adrenal gland as normal, smoothly enlarged, or nodular a
121 cer, smooth enlargement or nodularity of the adrenal glands at baseline CT is not associated with inc
122 ial for cholinergic synaptic transmission in adrenal gland, autonomic ganglia, pineal gland, and seve
124 in expression in heart, skeletal muscle, and adrenal gland but not in adult brain or spinal cord.
125 d high expression in the locus coeruleus and adrenal gland, but also in sympathetically innervated or
127 l root ganglion cells, sciatic nerve, and in adrenal glands, but its expression is greatly decreased
128 ctable in adult mouse atria, ventricles, and adrenal glands, but Kcne3(-/-) mice exhibited 2.3-fold e
129 tachycardia was evoked after removal of both adrenal glands, but was absent after beta-adrenergic rec
131 pression was detected in spleen, thymus, and adrenal gland by ribonuclease protection assay, and disc
132 ng accumulation of free cholesterol in mouse adrenal glands by controlling expression of genes involv
133 was to distinguish between PPGLs and normal adrenal glands by evaluating semiquantitative (123)I-MIB
134 ogenous lipids on tissue sections of porcine adrenal glands by MALDI-Fourier-transform ion cyclotron
135 d catecholamine production in isolated mouse adrenal glands by restoring adrenal alpha2-AR feedback i
141 ents with carcinomas of the salivary glands, adrenal gland, colon, parotid gland, kidney, thyroid gla
144 thyroid, parathyroids, pituitary, gonad, and adrenal glands, constitute a major health problem in all
145 in several subcortical regions; however, the adrenal glands contribute to 3alpha,5alpha-THP elevation
147 loss could sensitise PC cells and tumours to adrenal gland-derived androgens, which persist even afte
148 tisol (because of various genetic defects in adrenal gland development or steroidogenesis) are not bo
150 ral nervous system (CNS), kidneys, pancreas, adrenal glands, epididymis, broad ligament, and the endo
151 In comparison with rat forebrain extracts, adrenal gland extracts exhibited TH hyperphosphorylation
153 e first undertook transcriptome profiling on adrenal glands from blood pressure extreme mouse strains
154 11B2) expression was evaluated in 127 normal adrenal glands from deceased kidney donors (age, 9 month
156 al in fetal development, T-cell function and adrenal gland growth homeostasis, and that the functions
158 erum corticosterone levels were measured and adrenal glands harvested for histologic evaluation of he
160 However, the function and structure of the adrenal glands have not been examined in inflammatory bo
162 at and was not detected in intestine, brain, adrenal gland, heart, skeletal muscle, liver, lung, sple
163 highest expression of CysLT(2) receptors in adrenal glands, heart, and placenta; moderate levels in
167 ing pituitary, testis, pancreas, kidney, and adrenal gland, hyperproliferative phenotypes associated
168 ed with controls, aged HCM females exhibited adrenal gland hypertrophy, reduced volume in mood-relate
169 the presence or absence of metastases to the adrenal glands (ie, any new focal adrenal mass) at final
175 ns (SFCs) (</=5 mm) were seen in one or both adrenal glands in 19 of the 38 patients with fCCM (50%),
176 the female, the testis in the male, and the adrenal glands in all pigs contain greater concentration
177 The mechanisms behind destruction of the adrenal glands in autoimmune Addison's disease remain un
179 steroid hormone cortisol is released by the adrenal glands in response to stress and serves as a mes
180 tially important novel target of SF-1 in the adrenal gland, indicating that regulation of angiogenesi
181 control the steroid hormone biosynthesis in adrenal glands, indicating their important roles in endo
182 (MyD88) in systemic and local activation of adrenal gland inflammation and glucocorticoid production
183 high-thoracic level (Th1) SCI disconnecting adrenal gland innervation, compared with low-thoracic le
186 c assistance, particularly in patients whose adrenal gland is located well superior to the 12th rib,
188 the AT(1b) angiotensin receptor gene in the adrenal gland is upregulated by the first week of life r
189 Finally, we show that the development of adrenal glands is also severely affected in partially re
190 identification of mediastinal structures and adrenal glands is still much lower than that in standard
192 ent lipid classes that play in the mammalian adrenal glands, it is necessary to comprehensively deter
193 no restoration was achieved in adult liver, adrenal gland, kidney medulla, spleen, peritoneal cavity
194 e, is produced in numerous tissues including adrenal gland, kidney, brain and pituitary gland, where
196 the treatment of solitary metastases to the adrenal gland, laparoscopic adrenalectomy provides equiv
198 evealed lesions in several tissues including adrenal glands, lymphoid organs, bone, bone marrow, gast
199 jor catalytic role in the adult human liver, adrenal glands, macrophages, and kidneys but not in the
201 l suggests that ischemia and necrosis of the adrenal glands may be responsible for the adrenal insuff
203 mutant embryos exhibit complete agenesis of adrenal glands, metanephric kidneys, gonads, and defects
207 to assess for associations between baseline adrenal gland morphologic features and subsequent develo
208 no significant association between baseline adrenal gland morphologic features and subsequent develo
209 actal profiles (D approximately 1.3) whereas adrenal gland mosaics show a less irregular radial patte
212 mistry confirmed that within adult and fetal adrenal gland NGFIB expression paralleled expression of
218 oduction, was approximately 2-fold higher in adrenal glands of GX KO mice compared with WT mice, wher
220 osterone and ACTH levels than males, whereas adrenal glands of MS animals weighed less than those of
222 ative trait locus (eQTL and pQTL) mapping in adrenal glands of the HXB/BXH recombinant inbred (RI) st
224 patients with lymphoma with normal-appearing adrenal glands on prior CT examination (less than a 5% p
226 that expressed PPE mRNA and projected to the adrenal glands or celiac ganglia were activated, suggest
228 ours of the central nervous system, kidneys, adrenal glands, pancreas, and reproductive adnexal organ
229 an +/- SD], 42.9 +/- 13.3 y) with unilateral adrenal gland PHEO and in 13 control subjects (5 men and
230 eting, resulting in effective imaging of the adrenal glands, pituitary gland, lymph nodes, pancreas,
231 lective clearance of HDL CE by the liver and adrenal gland, possibly by facilitating the presentation
232 etyrapone may produce effects outside of the adrenal gland, presumably in the central nervous system,
238 e 28 tumors were located in the liver, lung, adrenal gland, retroperitoneum, gluteal muscle, inguinal
241 st to the testis and ovary, the mutant adult adrenal gland showed a lack of Sf1-deleted cells and our
243 However, with scheme B, no overlap in the adrenal gland SI-to-liver SI ratio between adenomas and
244 expressed in most tissues, including heart, adrenal gland, skeletal muscle, stomach, fat, brain, spi
245 Because of the limited availability of human adrenal glands, sources of xenogeneic chromaffin cells w
248 were made in functionally different targets: adrenal gland, stellate ganglion which regulates the hea
249 f familial cases and the involvement of both adrenal glands suggest a genetic origin of this conditio
250 anol also increased DBH mRNA levels in mouse adrenal gland, suggesting in vivo functional consequence
251 ne case, SKNBE(2)C iCSCs metastasized to the adrenal gland, suggesting their increased metastatic pot
252 observation of low S6K2 levels in the human adrenal gland supports the development of S6K1 inhibitor
254 Northern blot demonstrated that while the adrenal gland synthesized IL-18 mRNA of 1.1 kb, spleen a
255 the mouse Acsvl3 mRNA is highly expressed in adrenal gland, testis, and ovary, with lower expression
257 of 19 patients having more SFCs in the left adrenal gland than the right adrenal gland and 50 of the
259 ing adenomas (APAs) are benign tumors of the adrenal gland that constitutively produce the salt-retai
260 holamine biosynthesis and secretion from the adrenal gland that results in early embryonic lethality.
261 acrophages, the glucocorticoid production in adrenal glands, the leukocyte recruitment to peritoneum
262 ation of fresh frozen mouse liver and rabbit adrenal gland tissue sections with a range of higher spa
263 d in neuroblastoma cells compared to healthy adrenal gland tissue, consistent with a posttranscriptio
265 mized mice were transplanted with denervated adrenal glands to restore physiologic glucocorticoid lev
267 is substantial alpha2AR dysregulation in the adrenal gland, triggered by increased expression and act
269 zation with trans-synaptic labeling from the adrenal gland using pseudorabies virus identified presym
270 l progenitor cells from digestions of murine adrenal glands utilizing hydrodynamic inertial lift forc
271 of 2 readers, and uptake of (18)F-FDG in the adrenal gland was compared with liver activity and score
273 Ability to confirm visualization of the adrenal glands was determined for (18)F-FDG PET alone an
274 ino acid sequence of the peptide from bovine adrenal glands was HSSYEDELSEVL EKPNDQAE PKEVTEEVSSKDAAE
275 y delete GRK2 in the chromaffin cells of the adrenal gland, we crossed PNMTCre mice, expressing Cre r
276 nit of PP2A is expressed in brain but not in adrenal glands, we tested the hypothesis that PP2A/B'bet
279 between adrenal glands with PHEO and normal adrenal glands were 7.3 (100% sensitivity) and 10.1 (100
281 killed 6 hours after the injection, and the adrenal glands were collected for measurement of steroid
282 n CRPC, and indicated that steroids from the adrenal glands were contributing to this AR activity.
283 d beta-catenin and elevated Igf2 expression, adrenal glands were larger, displayed earlier onset of h
284 transcriptomes of 19 ACC tumors and 4 normal adrenal glands were profiled on Affymetrix U133 Plus2 ex
285 netic resonance (MR) imaging findings in the adrenal glands were reviewed retrospectively in 12 patie
286 evels as a basal protective mechanism in the adrenal gland, where cholesterol is under constant flux.
287 l motor nerve to the vicinity of the forming adrenal gland, where they detach from the nerve and form
288 nduces a strong inflammatory response in the adrenal glands, which is accompanied by cell death and h
289 ed XPLAC is expressed mostly in placenta and adrenal gland while XTES is exclusively expressed in pri
292 The 2 readers agreed on visualization of the adrenal glands with PET alone for 2 of 40 (5%) glands.
294 (18)F-FDA accumulation was observed in all adrenal glands with PHEO and in 6 of 13 control adrenal
296 F-FDA PET facilitate the distinction between adrenal glands with PHEO and normal adrenal glands.
297 d uptake values (SUVs) were compared between adrenal glands with PHEO and normal left adrenal glands
299 induced a local inflammatory response in the adrenal gland within 4 hours of administration, coupled
300 1.0 mg/kg per day) inhibits AT(1) binding in adrenal gland zona glomerulosa and kidney glomeruli.
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