ライフサイエンスコーパス: increase with age

1 to adolescence (ie, systematic decreases or increases with age).

2 also has ontogenetic components (morningness increases with age).

3 erstitial fibrosis, and tubular atrophy) all increase with age.

4 nd the number and size of simple renal cysts increase with age.

5 ibody with immunoglobulin, which is known to increase with age.

6 scence-associated CD4+ T cells that normally increase with age.

7 ageing in that its incidence and prevalence increase with age.

8 11.2 with a significant (P < 0.0001) linear increase with age.

9 lowing severe brain trauma has been shown to increase with age.

10 all time points, which did not significantly increase with age.

11 rate, and cholesterol crystals, all of which increase with age.

12 th IgG1/IgG3-dominated humoral immunity that increase with age.

13 wards females and predation risk appeared to increase with age.

14 0.87-1.24]; P = .69), did not significantly increase with age.

15 from 88 to 112 per 100 000 person-years and increase with age.

16 e as well as the severity of dry eye disease increase with age.

17 layed paternity reflect factors that may not increase with age.

18 he photoreceptor layers showed a logarithmic increase with age.

19 bunit expression in lungs of uninfected mice increased with age.

20 munoproteasome subunit mRNA and protein that increased with age.

21 om the life-course perspective, and the risk increased with age.

22 culosis cases, and additional adverse events increased with age.

23 Within-group cooperation increased with age.

24 e prevalence of MetS was higher in women and increased with age.

25 eas the minor-to-major splice variant ratios increased with age.

26 f controls and that the degree of activation increased with age.

27 In all locations, mortality increased with age.

28 difference existed throughout childhood but increased with age.

29 Periodontitis prevalence and severity increased with age.

30 CD36 and integrin alpha5beta1 significantly increased with age.

31 lpha-secreting) CD4(+) T cell responses also increased with age.

32 ain networks, and this positive relationship increased with age.

33 years and, with one exception, exponentially increased with age.

34 of alpha-syn persisted in the same cells and increased with age.

35 rface area were similar in men and women and increased with age.

36 infants exhibited fractal organization that increased with age.

37 Seropositivity to JC, MCV, and HPyV7 increased with age.

38 The density of cerebral LLC increased with age.

39 y of the cingulo-opercular/salience network, increased with age.

40 mong smokers, number of affected teeth/sites increased with age.

41 ductions than the other groups, and severity increased with age.

42 th age, and the apparent digestibility of CF increased with age.

43 Both bacterial abundance and diversity increased with age.

44 For each pathogen, the incidence increased with age.

45 nulosa cells), and their ovarian mRNA levels increased with age.

46 cycling (versus lactation), and this effect increased with age.

47 .06), but not children, and this association increased with age.

48 t structure, which started at 2 days old and increased with age.

49 res we identified parallel trajectories that increased with age.

50 men and women, and somatic symptom reporting increased with age.

51 ce interval: 47.0, 50.0) in 2017; prevalence increased with age.

52 ci-immune to malaria, risk of severe malaria increases with age.

53 of non-alcoholic fatty liver disease (NAFLD) increases with age.

54 cquired nasolacrimal duct obstruction (NLDO) increases with age.

55 Furthermore, overall incidence increases with age.

56 incidence and severity of herpes zoster (HZ) increases with age.

57 further since the prevalence of malnutrition increases with age.

58 e of neurodegenerative disease and arthritis increases with age.

59 Our results suggest that crowding increases with age.

60 PDI oxidation progressively increases with age.

61 emains possible instead that the optimum BMI increases with age.

62 ll as sites where the environmental variance increases with age.

63 In general, prevalence increases with age.

64 beta accumulation and plaque deposition that increases with age.

65 d susceptibility to new microbial infections increases with age.

66 power morcellation is low overall, but risk increases with age.

67 Its incidence increases with age.

68 he incidence of certain common human cancers increases with age.

69 Hepatitis A illness severity increases with age.

70 n overall mutation incidence of 15.7%, which increases with age.

71 xicity with anthracycline-based chemotherapy increases with age.

72 The rate of vesicle formation increases with age.

73 als in the United States, and its prevalence increases with age.

74 larger in the CMV seropositive and gradually increases with age.

75 dose versus standard-dose influenza vaccines increases with age.

76 age with the leakiness of all material types increasing with age.

77 ge of stone onset, first decreasing and then increasing with age.

78 tly, while water vapor permeability slightly increased with aging.

79 ell area and the variation in cell size were increased with aging.

80 Mouse fat tissue activin A increased with aging.

81 TRPV4 expression was increased with aging.

82 ny tissues, and the frequency of these cells increased with aging.

83 te pneumonia, a phenotype that is alarmingly increased with aging.

84 ities, the prevalence of periodontal disease increases with aging.

85 studies, that 1/f electrophysiological noise increases with aging.

86 atherosclerotic plaques, amyloid deposition increases with aging.

87 ghly prone to injury, the incidence of which increases with aging.

88 d may help to explain why the risk of injury increases with aging.

89 cific warming than TSFs, with the difference increasing with aging.

90 X mosaicism frequency increases with age (0.11% in 50-year olds; 0.45% in 75-y

91 (adjusted HR [aHR], 0.3; 95% CI, .1-.9) and increased with age (10-15 vs 0-4 years; aHR, 3.4; 95% CI

92 Prevalence increased with age (18-34 years: 2.7%; >/=75 years: 18.6

93 Across study periods, IPD and ACHP rates increased with age (2-27 times higher in persons >=75 vs

94 h COVID-19 has consistently been observed to increase with age(2,3).

95 ence of choroidal nevus was 4.7% overall and increased with age (4.7%, 3.1%, 5.4%, 6.6%, and 7.5% in

96 Arteriolar tortuosity increased with age (5.4%; 95% CI, 3.8%-7.1% per decade),

97 There is a high frequency of obesity, which increases with age (9.5% in children <2 y old, 18.8% in

98 In normal aging, the FD% increased with age across the central 5 mm of the macula

99 of overweight, obesity, and central obesity increased with age (all p<0.0001) and was higher in men

100 alpha1 and TRbeta1 in ovine fetal myocardium increases with age, although TRalpha1 levels always rema

101 of asymptomatic bacteriuria, although rates increase with age among both men and women.

102 vidual contributions to cooperative behavior increase with age and are higher in fast-growing individ

103 cells with a naive phenotype' (TMNP cells), increased with age and after severe acute infection and

104 Risk increased with age and any biomarker abnormality.

105 ated that the relative risk of adult obesity increased with age and BMI, from 1.17 (95% UI, 1.09 to 1

106 h no sex predilection; however, FHD severity increased with age and body mass.

107 Further, serum levels of IL-6 increased with age and contributed to elevated expressio

108 Corneal density increased with age and corneal thickness, but there was

109 ally, levels of IL-5, but no other cytokine, increased with age and correlated with eosinophil number

110 In addition, incidence increased with age and during the first 3 years followin

111 Peri-sinus IgA plasma cells increased with age and following a breach of the intesti

112 The mean measurement bias increased with age and height.

113 would correct the nonrepresentativeness that increased with age and ill health that I introduced into

114 Myelin fragmentation increased with age and led to the formation of insoluble

115 The need for care increased with age and neurologic disorders, intensive c

116 The prevalence of RPD in CAREDS2 increased with age and was associated with AMD severity.

117 cordingly, the relative genetic contribution increased with age and was greatest in adolescence (up t

118 The prevalence of NIU increased with age and was higher among adult females th

119 Antibody prevalence increased with age and was higher in one northwestern ar

120 Seroprevalence increased with age and was higher on private vs. communa

121 Early-life performance in all species increased with age and was predominantly influenced by w

122 The risks of infection increased with age and were higher in those with diabete

123 ichness (p = 0.013) of the eukaryotic virome increased with age and were higher than seen in age-matc

124 as well as adipose tissue, where repression increased with aging and high-fat diet-induced obesity.

125 Moreover, levels of FKBP51 are increased with aging and in Alzheimer disease, potential

126 , the percentage of PD-1 expressing NK cells increases with age and cumulative malaria exposure.

127 tations in cancer genes, the burden of which increases with age and decreases with parity.

128 RAN protein accumulation increases with age and disease, and TDP-43 inclusions ar

129 for diabetes diagnosis and care consistently increases with age and educational attainment, policy ma

130 In Caenorhabditis elegans, neural excitation increases with age and inhibition of excitation globally

131 Aortic stiffness increases with age and is a robust predictor of brain pa

132 The incidence of cardiovascular diseases increases with age and is also correlated with increased

133 atopoiesis of indeterminate potential (CHIP) increases with age and is associated with increased risk

134 The incidence of Alzheimer's disease (AD) increases with age and is becoming a significant cause o

135 vel measure to assess LA diastolic function, increases with age and is higher in persistent AF and in

136 The frequency of mLOY increases with age and may reflect poor genomic maintena

137 aged 65 years and older is 10% to 20%; risk increases with age and men appear to be at higher risk t

138 fic consensus is that collagen cross-linking increases with age and that this increase leads to tendo

139 The sAHP amplitude increases with aging and may underlie age related memory

140 prevalence of most cardiovascular disorders increase with age, and cardiovascular disease is the lea

141 The frequency of mtDNA defects in iPSCs increased with age, and many mutations were non-synonymo

142 The magnitude of these associations increased with age, and the pattern was prominent for PM

143 ic T cells in the peripheral lymphoid tissue increased with age, and their numbers correlated with in

144 Male AMS increased with age, and there was no significant reprodu

145 ghest among men who have sex with men (MSM), increased with age, and was higher in people with AIDS t

146 e mostly deleterious, clustered in hotspots, increased with age, and were more abundant in women with

147 Cancer incidence increases with age, and as life expectancy increases, th

148 uals, the likelihood of cognitive impairment increases with age, and duration of infection.

149 Prevalence is higher among women than men, increases with age, and is notable among those aged 18-3

150 ssociated with AMD presence and severity and increases with age, and its retinal topography including

151 a melanogaster, for instance, male fertility increases with age, and older males are known to have a

152 tenosis (AS) and of cardiac amyloidosis (CA) increases with age, and their association is not uncommo

153 hronic disability in TMJ osteoarthritis (OA) increases with aging, and the main goal is to diagnosis

154 ot previously identified in human platelets, increases with aging ( approximately 9-fold versus young

155 The underlying mechanisms, of why LOH rates increase with age, are not well understood.

156 following acute febrile malaria but did not increase with age as humoral immunity is acquired or cor

157 Indeed, the prevalence of AF increases with age as does oxidative stress.

158 d c-Myc, both of whose tissue concentrations increase with age, as possible major causes for age-depe

159 r, H3K9me3 decreased with age at IN2GHRE and increased with age at 5URGHRE.

160 Seroconversion increased with age at administration.

161 Risk of developing multiple melanomas increased with age at diagnosis of first melanoma (hazar

162 The prevalence of cardiac conditions increased with age at evaluation, ranging from 3% to 24%

163 y cohort during follow-up and mortality risk increased with age: below 50 (5.8%), 50 to 59 (14.2%), 6

164 higher in children with glomerulopathies and increased with age, blood pressure, proteinuria, and low

165 ver, uptake in the frontal lobe continued to increase with age but it decreased in the parietal and o

166 JTc and JTpc were moderately increasing with age but Tpe/Tpec were not.

167 Disease incidences increase with age, but the molecular characteristics of

168 matory mediators in circulation are known to increase with age, but the underlying cause of this age-

169 e HCM, the incidence rate for ESRD gradually increased with age, but an initial peak and subsequent p

170 Extent of BL and PD >/=4 mm also increased with age, but more rapidly and to a greater ex

171 Cytokine responses generally increased with age, but responses at birth were poorly p

172 l post-ICU discharge, and hospital mortality increased with age, but the majority of patients survivi

173 Major bleeding risk increased with age, but there were no differences betwee

174 Seroprevalence increases with age, but it is not clear if it is increas

175 empirical work suggests that allocation may increase with age due to constraint (increases with expe

176 Stiffness increases with age during normal development and approac

177 (CT)-assessed functional small airway would increase with age, even among asymptomatic individuals.

178 l maternal effects can evolve when fertility increases with age faster than cumulative survival decli

179 CSF Abeta increased with aging followed by a decrease of both Abet

180 30-day mortality increased with age for both patients with breast cancer

181 lly declined; in contrast, RUEs continuously increased with age for mature deciduous forests.

182 Likelihood of total periodontitis (TP) increased with age for overall and NSP relative to non-p

183 ergic sensitization in young children, which increases with age for food sensitization.

184 We find that maternal allocation increases with age for young mothers during both the pre

185 The risk of symptomatic infection increased with age (for example, at ~4% per year among a

186 iciaries, 2.96% among male beneficiaries and increased with age from 0.20% for ages 2-17 years, to 11

187 Mean CHA2DS2-VASc scores (n = 1,369) increased with age from 1.1 (<60 years) to 3.9 (>=85 yea

188 ion of benzodiazepine use that was long term increased with age from 14.7% (18-35 years) to 31.4% (65

189 The percentage who used benzodiazepines increased with age from 2.6% (18-35 years) to 5.4% (36-5

190 The 8-year incidence increased with age from 3.1% in those 40 to 49 years old

191 Permanent atrial arrhythmias increased with age from 3.1% to 22.6% in patients <20 ye

192 Prevalence increased with age, from 33.3% to 57.7% in PWCF younger

193 Cumulative incidence of AMD increased with age (>/=80 years old vs 50-59 years old:

194 om multivariable analysis, the odds of death increased with age (>=60 yrs.), admission from a nursing

195 Incidence increased with age (hazard ratio [HR]: 1.73; 95% confide

196 Genomic aberrations increase with age, highlighting the infant population as

197 entia, stroke, fractures, and breast cancer, increase with age; however, the excess risk for these co

198 Prevalence of calcific mitral stenosis (MS) increases with age; however, its natural history and rel

199 More so, sensitivity to hepatic IRI increases with age; however, no strategies have been dev

200 noncanonical antibody responses appeared to increase with age.IMPORTANCE This study dissected the sp

201 vegetables, and daily servings of vegetables increased with age, improving intake of whole fruit, who

202 GFAP expression does not increase with age in chimpanzees, possibly indicative of

203 y Egerman et al reported that GDF11/8 levels increase with age in mouse serum.

204 Visual field size and sensitivity increase with age in patterns that are specific to the p

205 cells have an effector memory phenotype and increase with age in systemic and mucosal lymphoid tissu

206 d, somatic single-nucleotide variants (SNVs) increase with age in the human brain, in a somewhat stoc

207 We find a rapid increase with age in the number of random insertions and

208 enzymes in the tyrosine degradation pathway increase with age in wild-type flies.

209 We report that PTGES1 and COX2 progressively increase with aging in sun-protected human skin.

210 ss was significantly co/BM complex thickness increased with age in a healthy White population.

211 Plasma NfL measurements increased with age in both groups (p<0.0001), and began

212 d (IL17A and IL20; P < .05 for IL20) markers increased with age in both patients with AD and control

213 C and medial prefrontal cortex; connectivity increased with age in controls, but decreased in individ

214 n type 2 mediators, whereas type 3 mediators increased with age in ENP.

215 es native to heterochromatic regions and TEs increased with age in fly heads and fat bodies.

216 Symptomatic Alzheimer's disease prevalence increased with age in individuals with Down syndrome, re

217 olites that changed, levels of tyrosine were increased with age in long-lived flies.

218 Lysosomal GL-3 inclusions increased with age in multiple cell types, including ren

219 Threat-related amygdala reactivity increased with age in participants with a positive famil

220 A decreased and orientation dispersion index increased with age in patients, but not control subjects

221 Whereas the central macular thickness increased with age in the control group, in the albinism

222 Risk of CSC increased with age in years (hazard ratio [HR] = 1.030,

223 Results showed that delay discounting increases with age in a quadratic fashion, with greatest

224 XCI skew increases with age in blood, but not other tissues, and

225 ons; (2) the amplitude of responses to faces increases with age in both face-selective and object-sel

226 Relative HDAC expression increases with age in cerebral white matter, and correla

227 ngs: (1) neural sensitivity to face identity increases with age in face-selective but not object-sele

228 ources, the tissue content of this biopterin increases with age in GTP cyclohydrolase 1-deficient hyp

229 novel B-cell subset expressing 4-1BBL, which increases with age in humans, rhesus macaques, and mice,

230 nt (increases with experience) or restraint (increases with age in the face of declining residual rep

231 reased with age in patients with AD, despite increasing with age in control subjects.

232 Additionally, the prevalence increased with age, in men, and in countries with low tu

233 Importantly, attenuation increases with age, in proportion to reduced sensory sen

234 In falciparum malaria, angiopoietin-2 increased with age, independent of parasite biomass (his

235 ndividuals and that ribosomal RNA production increases with age, indicating that nucleolar size and a

236 clinical findings (particularly arthralgia) increased with age, irrespective of previous dengue viru

237 The prevalence increases with age, is highest among whites (5.6%), is l

238 s of the world, affecting all age groups and increasing with age. It is primarily due to a low intake

239 For this cohort, LOI increased with age; LOI occurred in 1386 of 2780 patient

240 MM prevalence was high and increased with age, low CD4/CD8 ratio and nadir CD4 cell

241 MM prevalence was high and increased with age, low CD4/CD8 ratio, and nadir CD4 cou

242 The risk for cancer increases with age, male sex, and the presence of coexis

243 ations in the deep regions of the brain that increase with age, mimicking the pathology observed in h

244 Total DCIS detection rates increase with age, mostly because of an increase in high

245 dverse events and study drug discontinuation increased with age, neither was significantly more commo

246 PAAT increased with age (neonates: median: 81 ms, range: 53-1

247 in the National Health Interview Study that increased with age, obesity, and ill health.

248 Cholera risk increased with age, occupation, and recent history of di

249 ate for high-grade DCIS showed a significant increase with age (odds ratio, 1.18 per 5-year age group

250 evalence of calcific aortic valve disease is increasing with aging of the population.

251 Visual field area increased with age on testing with Goldmann isopters III

252 Fat infiltration and adipocyte size increased with age ( P < 0.001) and in recuperated thymi

253 The values of qAF also positively increased with age (P < 0.0001).

254 Although UIE and 24-h urinary volumes increased with age (P < 0.001), a progressive decrease i

255 The benefit also modestly increased with age (P = .023 for interaction), but this

256 icipants younger than 20 years and gradually increased with age (p for trend <0.0001).

257 NCP volume increased with age (P<0.001) and was higher in men than

258 rscore that the rate of detectable mosaicism increases with age (p value = 5.5 x 10(-31)) and is high

259 17.2% [12.5-23.4]; this probability did not increase with age [P = 0.8]).

260 Serum MMA concentrations increased with age, particularly in persons aged >=70 y.

261 as observed in 7% of men, and its prevalence increased with age (per-year odds ratio (OR) = 1.13, 95%

262 mean RPE/BM complex thickness significantly increased with age (r = 0.33, P = 0.0006).

263 atios seen in the data into the ("unbiased") increasing-with-age ratios that they computed?

264 Prevalence increased with age, reaching 50% before ages 68, 84, and

265 e population of CD161(+) cells at birth that increased with age, reaching more than 30% of the spleno

266 At 56 and 84 Hz, liver stiffness increased with age (Spearman correlation, r = 0.38 [P =

267 MUAC increased with age steadily throughout the growing perio

268 Because susceptibility to diseases increases with age, studying aging gains importance.

269 served over time, in many this estimate also increased with age, suggesting samples for research stud

270 The incidence of pancreatic cancer increases with age, suggesting that chronological aging

271 because women live longer and AF prevalence increases with age, the absolute number of women with AF

272 PA) and arachidonic acid (AA) concentrations increase with age.The aim of this study was to evaluate

273 .001), ERMs (P < 0.001), and VMT (P = 0.005) increased with age; the prevalence of PVCs (P = 0.05) de

274 patient aged 75 years or older taking DOACs increased with age; the risk was greatest among persons

275 ties and the prevalence of insomnia tends to increase with age, therefore this group warrants particu

276 The risk of developing glaucoma increases with age; therefore, understanding mechanisms

277 s an expectation that, on average, pain will increase with age, through accumulated injury, physical

278 59]) than in heterosexuals (3.79 [3.36]) and increased with age to a larger extent.

279 icators of MU remodelling also progressively increased with age to a similar extent in both sexes (P

280 Atrial fibrillation increased with age to surpass IART as the most common ar

281 (95% confidence interval [CI], 14.1%-17.1%), increasing with age to 41.2% (95% CI, 30.0%-52.4%) in pe

282 (95% CI: 1.0, 1.1)) was lived with dementia, increasing with age to 42.1% (1.0 year, 95% CI: 0.9, 1.0

283 CI = 1.8-15.6) to 47.6% (95% CI = 35.1-60.1) increased with age until adulthood (>6) and varied by lo

284 rtion of podocyte cytoplasm occupied by GL3) increased with age up to about age 27, suggesting that i

285 MATS coverage increased with age, varied by geographical region, and w

286 3.54%, 1.17-10.24, at 40-44 years), but the increase with age was greater in HICs than LMICs, leadin

287 her among those older than 60 years, but the increase with age was steeper for those younger than 60

288 The one exception to an exponential increase with age was the transition rate from A(-)N(-)

289 IgG, IgG1, and IgG3 responses generally increased with age, were higher in children with active

290 5-9, and 10-14 years) because concentrations increase with age when chloroquine is prescribed accordi

291 that matrix metalloproteinase 1 mRNA, MMP1, increased with aging, whereas in dermal sheath cells, hy

292 the proportion of EV-A71 infection generally increased with age which showed rapid growth in severe c

293 ve complex influenza exposure histories that increase with age, which may lead to different postvacci

294 ow afterhyperpolarization (sAHP) exhibits an increase with aging, which correlates with memory impair

295 d ages because reproductive output typically increases with age, which may lead to the evolution of s

296 Type 2 diabetes incidence increases with age, while beta-cell replication declines

297 found that plasma Abeta(1-42) concentration increases with age, while the concentration of Abeta(1-4

298 , aortic ascending and bifurcation diameters increased with age, with an unchanged aortic taper.

299 Bioaccumulation of POPs increased with age, with the exception of presumed nulli

300 Impairments in DA increased with age, worse visual acuity, presence of RPD