ライフサイエンスコーパス: internal organ

1 f vibrissae, mineral deposits in a number of internal organs.

2 the site of inoculation and dissemination to internal organs.

3 histochemical analysis of excised tumors and internal organs.

4 es a consistent left-right (LR) asymmetry of internal organs.

5 are comparable to the dimensions of luminal internal organs.

6 and are required for the proper function of internal organs.

7 y lesions and satellite lesions, and infects internal organs.

8 at, in humans, gives rise to the majority of internal organs.

9 se characterized by fibrosis of the skin and internal organs.

10 ity to clearly resolve and identify targeted internal organs.

11 plication, but pathology was observed in the internal organs.

12 eractions during epithelial morphogenesis of internal organs.

13 aging of tumors and gene expression in mouse internal organs.

14 nd excessive connective tissue deposition in internal organs.

15 vealed no apparent abnormality(ies) in vital internal organs.

16 establishes the L/R asymmetric placement of internal organs.

17 xcruciating reminder of the existence of our internal organs.

18 festing itself by fibrosis of skin and other internal organs.

19 ve dermal fibrosis with later progression to internal organs.

20 es the quantification of tumor growth within internal organs.

21 liver, and positive bacterial cultures from internal organs.

22 aberrima, has the capacity to regenerate its internal organs.

23 nd short persistence of the yaws pathogen in internal organs.

24 genetic disorders that affect both skin and internal organs.

25 ed by fibrosis of the skin, vasculature, and internal organs.

26 tumors without any apparent toxic effects on internal organs.

27 rmis, fascia, and the fibrous layers of many internal organs.

28 le, heart and blood with a decrease to other internal organs.

29 mpanied by severe fibrosis in skin and other internal organs.

30 ates with methylation and gene expression in internal organs.

31 customized delivery of payloads in targeted internal organs.

32 es and arteriovenous malformations (AVMs) in internal organs.

33 f clonal mast cells (MCs) in the skin and/or internal organs.

34 sensitivity reactions involving the skin and internal organs.

35 oportion of Se present as selenoneine in the internal organs.

36 e immune system and fibrosis in the skin and internal organs.

37 atrix, leading to fibrosis of skin and other internal organs.

38 widespread fibrosis in the skin and several internal organs.

39 mmune disease that affects skin and multiple internal organs.

40 unctional layers facilitate integration with internal organs.

41 the placement, morphogenesis and function of internal organs.

42 xternal material from accessing and damaging internal organs.

43 sus totalis (SIT), a mirrored positioning of internal organs.

44 o the body, with its impact on the brain and internal organs.

45 marily affect the skin, they can also affect internal organs.

46 inks cognition and affect to the function of internal organs.

47 ding fibrotic disease affecting the skin and internal organs.

48 mutation D816V in the bone marrow and other internal organs.

49 isease characterized by fibrosis of skin and internal organs.

50 respiratory tract and spreads by viremia to internal organs.

51 dations from American Society for Artificial Internal Organs.

52 metries in the structure and position of the internal organs.

53 autonomic and endocrine systems that control internal organs.

54 rooting selfhood in the neural monitoring of internal organs.

55 anged according to the pathological state of internal organs.

56 hood is grounded in the neural monitoring of internal organs.

57 mussel gut, with little penetration in their internal organs.

58 It affects the skin and various internal organs.

59 Nominal expression was detected in internal organs.

60 er characterized by fibrosis of the skin and internal organs.

61 of subjacent muscles and usually sparing the internal organs.

62 se dominated by the mechanics of pressurized internal organs.

63 er and line the surface of body cavities and internal organs.

64 forces contour the body and provide shape to internal organs.

65 of squamous cell carcinoma (SCC) in skin and internal organs.

66 n autoimmune disorder that involves skin and internal organs.

67 microscopes to minimally invasive imaging of internal organs.

68 SNA structures are virtually undetectable in internal organs.

69 origin of descending commands that influence internal organs?

70 c nervous systems regulate the activities of internal organs(1), but the molecular and functional div

71 voked complex actions(4) and connectivity to internal organs(10) such as the adrenal medulla, suggest

72 itis (OR = 59.1; CI, 14.1-247.8; P < .0001), internal organ abscess (OR = 2.9; CI, 1.2-6.4; P = .02),

73 (P < 0.001), pyogenic arthritis (P < 0.001), internal organ abscess (P < 0.001), osteomyelitis (P < 0

74 , osteomyelitis, infected vascular catheter, internal organ abscess, and diabetic retinopathy showed

75 ial meningitis, lymphoma/leukemia, HIV/AIDS, internal organ abscess, diabetes with ophthalmic manifes

76 dhere to epithelial surfaces, disseminate to internal organs, affect the body weight of adult mice an

77 lanoma only develops from melanocytes lining internal organs, analogous to the location of patient MM

78 Culture of internal organs and 16S rDNA sequencing revealed TLR7-de

79 of the body to stabilize walking and support internal organs and a large-brained, broad-shouldered ba

80 by which embryonic tissues generate complex internal organs and a number of studies of epithelia hav

81 er characterized by fibrosis of the skin and internal organs and autoimmunity.

82 position of ossifications in relation to the internal organs and blood vessels, allowing to schedule

83 he body cavity, where it directly bathes the internal organs and epidermis.

84 acterial dissemination from the intestine to internal organs and for inhibition of phagocytosis.

85 Combined information about its eyes, internal organs and gut contents obtained by X-ray micro

86 brosis is caused by scar tissue formation in internal organs and is associated with 45% of deaths in

87 asymmetry in disposition and conformation of internal organs and is established during embryogenesis.

88 etail the procedures for visualizing in vivo internal organs and muscle sarcomeres in the mouse abdom

89 s were noted in post necropsy examination of internal organs and organ-to-body weight ratio.

90 is the study of the microbes colonizing the internal organs and orifices after death.

91 essed on the basis of the bacterial loads in internal organs and overall lethality.

92 We identified pathogens found in internal organs and placentas of deceased preterm infant

93 lethality and reduces viral dissemination in internal organs and poxvirus lesions.

94 of the extracellular matrix in a variety of internal organs and skin.

95 Skin is the interface between the internal organs and the environment, and as such plays a

96 Studying the microbial composition of internal organs and their associations with disease rema

97 se and widely applicable device suitable for internal organs and tissue illumination and associated d

98 omach, ileum, colon) or in a broad series of internal organs and tissues (e.g. liver, brain, heart, p

99 Diagnostic and therapeutic illumination on internal organs and tissues with high controllability an

100 ce were dissected to better visualize deeper internal organs and tissues.

101 These ganglia innervate internal organs and transmit information on heart rate,

102 s patches and mesenteric lymph nodes, to the internal organs and trigger the formation of abscesses;

103 is characterised by fibrosis of the skin and internal organs and vasculopathy.

104 immune activation, inflammation in skin and internal organs, and autoantibody generation.

105 ) mice develop severe pathology in colon and internal organs, and deteriorate rapidly during acute in

106 required for dissemination from the skin to internal organs, and the outer membrane protein OmpB con

107 ls greatly exceeding those in blood or other internal organs, and with nitrate being reduced to NO du

108 Internal organs are asymmetrically positioned inside the

109 ny species, changes in key energy-associated internal organs are common yet poorly characterised func

110 The asymmetries of internal organs are consistently oriented along the left

111 Besides skeletal dwarfism, internal organs are correspondingly smaller, indicating

112 The liver is engorged with lipid, and the internal organs are enlarged.

113 Neural inputs from internal organs are essential for normal autonomic funct

114 n enlarged umbilical ring, through which the internal organs are extruded.

115 ine the serous cavities and outer surface of internal organs are involved in inflammatory responses i

116 m laterality relates to the L/R asymmetry of internal organs are poorly understood.

117 Most internal organs are situated in a coelomic cavity and ar

118 h through skin infection and then spreads to internal organs as reported previously for the wild-type

119 During development, the placement of internal organs asymmetrically along the left-right axis

120 ion in the colony counts of H. capsulatum in internal organs at 14 days after infection.

121 vestigate the two-hit mutation mechanism for internal organ AVMs, the source of much of the morbidity

122 arasitoid wasp larva fed selectively on host internal organs, avoiding the heart (dorsal vessel) and

123 ng organs (skin) but is also observed within internal organs (brain and liver).

124 t a marker of parasympathetic denervation of internal organs, but further validation studies are need

125 nary edema and bacteria invasions throughout internal organs, but with no inflammatory response.

126 oxin from the gastrointestinal tracts to the internal organs by in vivo imaging of whole animals over

127 ft/right (L/R) anatomical asymmetries of the internal organs can be traced to molecular events initia

128 dent changes in the thanatomicrobiome within internal organs can estimate the time of death as a huma

129 biomarkers at locations adjacent to targeted internal organs can provide actionable information about

130 leishmaniasis (VL) is a fatal disease of the internal organs caused by the eukaryotic parasite Leishm

131 ved anatomical co-registration with infected internal organs compared with the lux signal in a mouse

132 naware of the orchestrated function that our internal organs conduct.

133 The pathological evaluation of internal organs confirmed the long-term biocompatibility

134 athetic drive for controlling physiology and internal organs (connectivity to adrenal medulla), and a

135 ion, bacteria proliferate extensively in the internal organs despite the massive infiltration of neut

136 Our results suggest a role for CPE-R in internal organ development and function during pre- and

137 dence was observed for endocrine and related internal organ diseases, musculoskeletal diseases, and d

138 ype 2 to replication in cultured cells or in internal organs during neonatal disseminated disease res

139 isrupted by the extensive damage observed in internal organs during the course of certain diseases.

140 ings in this subgroup may be associated with internal organ dysfunction.

141 xpression of vascularity markers in skin and internal organs, early immune activation, inflammation i

142 sease is the gradual accumulation of iron in internal organs, especially the liver, heart, and pancre

143 sed by skin fibrosis that often also affects internal organs, eventually resulting in mortality.

144 r masks, automated segmentations of multiple internal organs, extracted radiomics features, and corre

145 onsible for unresolving synchronous skin and internal organ fibrosis in SSc, but the drivers of susta

146 They can replace complex internal organs following injury or autotomy.

147 atfish by the immersion route and persist in internal organs for at least 48 h.

148 sarcoma (KS) is a cancer affecting skin and internal organs for which the Kaposi's sarcoma associate

149 metabolous insects, the adult appendages and internal organs form anew from larval progenitor cells d

150 cordance and (2) that neuronal and visceral (internal organs) forms of bilateral asymmetry are coded

151 tispectral imaging of the zebrafish body and internal organs from different viewing perspectives.

152 nsity focused ultrasound has been applied to internal organs from outside the body to ablate tissue.

153 Internal organ function improved (lung) or remained stab

154 cing physiological performance and buffering internal organ function while foraging in the cold, nutr

155 nd demonstrate the possibility of regulating internal organ function, leading to new bioelectronic th

156 ty and quality of life, and stabilization of internal organ function.

157 tonomic reflex responses that ensure optimal internal organ function.

158 Overall, internal organ functions were stable to slightly worse a

159 This model of vascular development in an internal organ has a direct impact on the current dogma

160 uding thrombocytopenia, leukopenia, skin and internal organ hemorrhages, high viral replication, sple

161 Betaine has been shown to protect internal organs, improve vascular risk factors, and enha

162 e door to longitudinal studies of Drosophila internal organs in their native context.

163 mode endoscopy and show its ability to image internal organs in vivo, thus illustrating its potential

164 M formation in postnatal retinal vessels and internal organs including the gastrointestinal (GI) trac

165 looped hearts and randomized localization of internal organs including the pancreas, features typical

166 es 48 hours of continuous imaging of diverse internal organs, including blood vessels, muscle, heart,

167 iciencies that cause defects in formation of internal organs, including circularization of the intest

168 onditions by modifying the function of their internal organs, including the brain.

169 that encapsulate the epithelial primordia of internal organs, including the kidney and lung, as well

170 IR-1 genetic pathways in murine versus human internal organs, including the lung and brain.

171 stasis by inducing a high nutrient demand in internal organs, indicating that reducing nutrient avail

172 late mesoderm and randomize the placement of internal organs, indicating that the activity of Na,K-AT

173 ary motility, KV fluid flow and placement of internal organs induced by their knockdown could be supp

174 Non-lethal ischemia of internal organs induces local (ischemic preconditioning)

175 tion of barrier tissues, whereas its role in internal organ inflammation remains less clear.

176 ole of vasculitic, as opposed to synovial or internal organ inflammation, may be release of secondary

177 erious brain injuries, spinal cord injuries, internal organ injuries, extremity fractures, and facial

178 The small bowel is the most common internal organ involved, resulting in considerable morbi

179 SSc-associated antibodies for diagnosis and internal organ involvement are becoming increasingly acc

180 the relationship between the skin score and internal organ involvement in dcSSc is more complex than

181 Improvement in internal organ involvement is also observed.

182 Mortality in severe diffuse disease with internal organ involvement is elevated.

183 dnan skin scores (mRSS) of more than 14, and internal organ involvement or restricted skin involvemen

184 ostic features (such as high skin scores and internal organ involvement).

185 r major form of recessive ichthyosis without internal organ involvement, lamellar ichthyosis, which i

186 Secondary outcomes included change in internal organ involvement, molecular parameters, and sa

187 der characterized by loose skin and variable internal organ involvement, resulting from paucity of el

188 of memory T cell subsets, which may reflect internal organ involvement.

189 ted with high mortality resulting from early internal-organ involvement.

190 had no significant differences in individual internal organ involvements, laboratory features, serum

191 She had neither erythema nor internal organ involvements.

192 Formation of numerous internal organs involves reciprocal epithelial-mesenchym

193 Fibrosis of the skin and internal organs is a hallmark of systemic sclerosis (SSc

194 g physiological tolerance against self-Ag of internal organs is not yet defined.

195 in 25% to 68% of patients, dissemination to internal organs is rare.

196 ogy is that the final size of appendages and internal organs is regulated autonomously, within the st

197 in deep-seated structures of the brain or of internal organs is the limited penetration of photons in

198 examining microbial communities in different internal organs is to address the paucity of empirical d

199 bacteria disseminate from the epithelium to internal organs is unclear.

200 that initiates in the skin and progresses to internal organs, leading to a poor prognosis.

201 s administration of [1-(11)C]-glucose for 24 internal organs, lens, blood and total body were calcula

202 ce of C. neoformans from the lungs and other internal organs, less is known about the protective mech

203 he skin, extremities, oral cavity and in the internal organs (lung, liver, intestine, spleen and brai

204 ellectual disability, increased frequency of internal organ malformations (including those of the hea

205 Degos-like lesions were not associated with internal organ manifestations, such as scleroderma renal

206 sults suggest that acupoints associated with internal organs may be identical to neurogenic inflammat

207 Intracranial bleeds and bleeds into internal organs may be life-threatening.

208 few vegetative forms could be recovered from internal organs of animals infected with the bslA mutant

209 concentrations in the mucosa that cover the internal organs of animals.

210 A novel X-ray technique shows that the internal organs of crawling caterpillars slide past the

211 bundance and gene expression patterns in the internal organs of deceased humans.

212 The assumption that amongst internal organs of early arthropods only the digestive s

213 al fins and tailstocks, from lungs and other internal organs of eight harbour porpoises.

214 The study was conducted on various internal organs of giant petrels (Macronectes spp.), enc

215 e, bacteria are recovered from the blood and internal organs of healthy teleosts.

216 placenta and was found more commonly in the internal organs of neonates who died later in the neonat

217 Fibroblasts and myofibroblasts in skin and internal organs of patients with systemic sclerosis and

218 n a second type of autogenic photophore, the internal organs of Pesta, found in deep-sea sergestid sh

219 liminary insights into the fate of Se in key internal organs of seabirds, including the liver, the ki

220 accessibility to various tissue sites in the internal organs of small animals.

221 rocal neuronal connections exist between the internal organs of the body and the nervous system.

222 nt role for TLR11 in preventing infection of internal organs of the urogenital system.

223 For example, the internal organs of vertebrates are left-right (L-R) asym

224 Laterality of the internal organs of vertebrates is determined by asymmetr

225 ing embryonic development and innervates the internal organs of vertebrates to modulate their stress

226 cute direct therapeutic interventions within internal organs, offering transformative potential in th

227 ient positioning and involuntary movement of internal organs, often necessitating labor-intensive non

228 osing processes affecting the skin, selected internal organs, or both in a characteristic pattern are

229 Continuous imaging of internal organs over days could provide crucial informat

230 infection is characterized by the growth in internal organ parenchymae of fluid-filled structures (h

231 rate bodies appears bilaterally symmetrical, internal organ positioning and morphology frequently exh

232 s, there are differences in body habitus and internal organ positioning that necessitate a deviation

233 We propose that peripheral tolerance for internal organs relies on the control of autoreactive ef

234 on calcium imaging preparation to understand internal organ representations in the nucleus of the sol

235 bicans to translocate and disseminate to the internal organs, resulting in an uncontrolled immune res

236 ood biochemistry and morphometric studies of internal organs revealed no pronounced toxicity of u-oli

237 x vivo metabolic capacity analyses of murine internal organs revealed that exercise induces catabolic

238 and a general molecular/genetic roadmap for internal organ sensation by the vagus nerve.

239 talis, the complete mirror image reversal of internal organ situs (positioning).

240 t chemical matrices throughout the body, the internal organ-specific radiation dose due to inhaled ra

241 R) asymmetry in the anatomy and placement of internal organs such as the heart.

242 blood may result from CPE pore formation in internal organs such as the liver.

243 to affect the colon but are not effective in internal organs such as the lungs.

244 processing associated with signals from the internal organs (such as the heart and the lung) plays a

245 mediator between nutrition and the growth of internal organs, such as imaginal disks, and is required

246 hood is grounded in the neural monitoring of internal organs, such as the heart.

247 lity of FRaeppli for live imaging of complex internal organs, such as the liver, and have tailored hy

248 These pathways enhance protection in internal organs, such as the nervous system, and in the

249 e elucidated, the presence of fetal cells in internal organs suggests that they could play a role in

250 disease features, frequency and severity of internal organ system involvement, and survival in Afric

251 tocytosis in the skin: MIS) and/or involving internal organs (systemic mastocytosis: SM).

252 get fibrosis and other diseases across other internal organ systems.

253 lesions, and higher viral loads in skin and internal organs than mice inoculated in saline-exposed s

254 rcise induces the metabolic reprogramming of internal organs that increases nutrient demand and prote

255 om, anterior differentiation, appendages, or internal organs that would suggest a bilateral body plan

256 g aging and age-related dysfunction in those internal organs that youthful skin was designed to envel

257 nt (the epidermis and cornea) and in certain internal organs (the epithelium of the tongue, esophagus

258 bsorbed into the circulation to target other internal organs), the ability of isogenic agrB or luxS m

259 ing reliably estimates muscle quantity in an internal organ, the heart, and can longitudinally follow

260 nerves and nerve plexuses, and may grow into internal organs, the spinal canal, and middle ear, defor

261 ovirus (Ad) vector-mediated gene transfer to internal organs, this study evaluated the consequences o

262 challenge and reduces viral dissemination to internal organs, thus providing a shield for the develop

263 The prostate gland is among the last internal organs to deteriorate during human decompositio

264 ion, followed by the binding of the toxin to internal organs to induce potassium leakage, which can c

265 hanical forces from both the environment and internal organs to regulate physiology.

266 al sensory neurons (VSNs) relay signals from internal organs to the brainstem via the vagus nerve.

267 orm for the targeted delivery of payloads to internal organs to treat various diseases and to uncover

268 The targeted delivery of therapeutics to internal organs to, for example, promote healing or apop

269 se concomitant fractures usually also damage internal organs; together, these injuries are hypothesiz

270 6 mice to study the efficacy, stability, and internal organ toxicity of (212)Bi-MAA.

271 rain AVMs, confirming that mucocutaneous and internal organ vascular malformations undergo the same m

272 in the extremities, progressive fibrosis of internal organs, vasoconstriction and altered expression

273 The organization of the epidermis and internal organs was also analyzed using a monoclonal ant

274 -deficient cells to the formation of various internal organs was analyzed.

275 enhanced, and recruitment of macrophages to internal organs was increased in septic PHD3-deficient m

276 However, while spread to other internal organs was rapid and efficient in CAST/EiJ mice

277 ite its name (visceral means associated with internal organs) was only thought to give rise to extrae

278 rotection against chemical carcinogenesis in internal organs, we treated XPC mutant (XPC-/-) mice wit

279 be seen through the skin of shaved mice, and internal organs were easily discernible.

280 Droppings, cecal tonsils and 5 internal organs were sampled and cultured at 6, 13 and 2

281 that nutrient status is sensed by different internal organs, which in turn regulate production of in

282 e co-registered anatomical maps of a mouse's internal organs, while also acquiring in vivo molecular

283 esothelium lines body cavities and surrounds internal organs, widely contributing to homeostasis and

284 the mechanism that coordinates the growth of internal organs with overall somatic growth.

285 brates display a characteristic asymmetry of internal organs with the cardiac apex, stomach and splee

286 ensory neuron types that innervate different internal organs, with many cell types remaining poorly u

287 o a lesser extent, the intestinal tracts and internal organs; with limited histopathological changes

288 deling and fibrosis of the skin and multiple internal organs, yet the fundamental pathological defect

289 avelengths are received in both external and internal organs, zebrafish were exposed to specific 50 n