ライフサイエンスコーパス: rhythm

1 mammalian locomotor activity (LMA) circadian rhythm.

2 n may be more effective in maintaining sinus rhythm.

3 achmann bundle, and left atrium during sinus rhythm.

4 e characteristics, including initial cardiac rhythm.

5 d loss of phase coherence with the melatonin rhythm.

6 gical activities often adhere to a circadian rhythm.

7 ce (I(h)) contributes to the altered network rhythm.

8 he stem, and 10 STs responded to the diurnal rhythm.

9 rrhythmic drug therapy for maintaining sinus rhythm.

10 AF with the remaining 2289 maintaining sinus rhythm.

11 nd sinus rhythm including sinus irregularity rhythm.

12 ct as excitatory pacemakers for the V1 gamma rhythm.

13 ion, salt and glucose homeostasis, and heart rhythm.

14 chrony (SOA deviants) for given tones in the rhythm.

15 sociated with adiposity and robust circadian rhythms.

16 firing frequency in SCN neurons and circuit rhythms.

17 ical stabilization did not rapidly normalize rhythms.

18 otential mechanisms that regulate these 24-h rhythms.

19 ian clock to coordinate metabolic and stress rhythms.

20 including event related potentials and brain rhythms.

21 2018, including 75 with initially shockable rhythms.

22 vel places, and are modulated by local theta rhythms.

23 disorders associated with dampened circadian rhythms.

24 n and correction of such abnormal excitation rhythms.

25 rating delta/theta (ie, 2 to 6 Hz) and gamma rhythms.

26 no detectable phase coherence with melatonin rhythms.

27 ordinating their development with host daily rhythms.

28 gulation to create this subtype of circadian rhythms.

29 latable mutations exhibit altered behavioral rhythms.

30 e by which SCN(VIP) neurons may regulate LMA rhythms.

31 consistent pattern of DBT and HRV ultradian rhythm (2-5 h) power that uniquely enabled anticipation

32 R and electroanatomic mapping (EAM) in sinus rhythm (2960 electroanatomic mapping points analyzed).

33 ked to respiration, locomotion and circadian rhythm(4-10).

34 rinatal death: 9 (82%) showed signature LQTS rhythms, 6 (55%) showed TdP, 5 (45%) were stillborn, and

35 ts to convert gastric dysrhythmias to normal rhythms.(9) In a preregistered, randomized, double-blind

36 an increased interictal heart rate and heart rhythm abnormalities (i.e. sinus pause and sinus arrhyth

37 We quantified heart rhythm abnormalities and examined whether the frequency

38 ency in mice results in hypoplastic SANs and rhythm abnormalities.

39 ents present significant sleep and circadian rhythm abnormalities.

40 onitored participants for any hemodynamic or rhythm abnormalities.

41 Disruptions in circadian rhythms across an organism are associated with negative

42 Further, LAN significantly altered circadian rhythms (activity and temperature) and circadian gene ex

43 orders are linked to alteration of circadian rhythms, although the molecular and neuronal pathways im

44 further studies of CLOCK's role in circadian rhythm amplitude regulation and as a potential candidate

45 as associated with a blunting of the diurnal rhythm and a significant linear increase in cortisol, ev

46 Subgroups categorized by initial cardiac rhythm and EMS-witnessed cardiac arrests were analyzed.

47 x2-regulated genes associated with circadian rhythm and entrainment, glutamatergic/cholinergic/dopami

48 used to investigate the effects of circadian rhythm and food intake on several metabolite classes.

49 conduction are already present during sinus rhythm and may explain the higher vulnerability to atria

50 s and radiotelemetry units to record cardiac rhythm and nerve activity (NA) from the left stellate ga

51 for the regulation of daily phosphorylation rhythm and phase-specific transcriptional activity of CL

52 t that genetic factors controlling circadian rhythm and pigmentation are also involved in the develop

53 trategies to improve brain perfusion through rhythm and rate control approaches.

54 we found a novel regulation of the circadian rhythm and sleep by the miR-375-timeless interaction.

55 scribed and to the disturbances in circadian rhythm and sleep reported in PD patients.

56 urons, where miR-375 modulated the circadian rhythm and sleep via targeting timeless.

57 relevance of glia for maintaining circadian rhythms and also for serving functions of sleep.

58 T(2) are involved in synchronizing circadian rhythms and are important targets for treating sleep and

59 icted inputs by inhibiting feedforward gamma rhythms and associated spiking.

60 ggesting reciprocal interaction of circadian rhythms and chemotherapy.

61 rhythmic deadenylation in regulating poly(A) rhythms and circadian gene expression.

62 mal1 severely disrupted circadian behavioral rhythms and compromised TTFL time-keeping in the corresp

63 es can learn to self-regulate specific brain rhythms and consequently improve their performances.

64 are selected based on corresponding activity rhythms and could be used to develop cerebellar stimulat

65 Altered circadian rhythms and CRY expression were also observed in human f

66 association between disrupted transcriptome rhythms and encephalopathy suggests a path for future wo

67 ift work has been shown to disrupt circadian rhythms and is associated with several adverse health ou

68 type-self-reported questionnaire); (b) sleep rhythms and light exposition; (c) 7-day-diaries of food

69 nce of circadian and ultradian rest-activity rhythms and loss of phase coherence with the melatonin r

70 ition, synchronization, and harmonization of rhythms and pitches, and summarize empirical evidence fo

71 ing of core clock genes, generates near 24-h rhythms and regulates the downstream rhythmic gene expre

72 romodulator melatonin synchronizes circadian rhythms and related physiological functions through the

73 nterpretability for how patients' behavioral rhythms and the rhythms of their environments influence

74 m for assaying Drosophila locomotor activity rhythms and thought that it might also be applicable to

75 llation (defined as no plan to restore sinus rhythm) and dyspnea classified as New York Heart Associa

76 hours in asthma, and its amplitude, percent rhythm, and acrophase were comparable to those of peak e

77 increased average levels, a blunted diurnal rhythm, and enhanced response to stressors.

78 chronic inflammation, cell cycle, circadian rhythm, and olfactory functions.

79 st may be in part regulated by annual immune rhythms, and dominated by the effects of temperature.

80 onal oscillations, mitochondrial respiration rhythms, and late evening activity are restored by NAD(+

81 alters dynamical features of theta and delta rhythms, and leads to significant reduction in theta-del

82 circadian rhythm (zeitgebers), rest-activity rhythms, and the central circadian rhythm-controlled mel

83 Night shift work, behavioral rhythms, and the common MTNR1B risk single nucleotide po

84 Rhythm- and location-control stimulation conditions had

85 Biological rhythms appear to be an elegant solution to the challeng

86 Disrupted sleep-wake and molecular circadian rhythms are a feature of aging associated with metabolic

87 e ways of organizing events in time, musical rhythms are almost always distributed categorically.

88 ipate daily environmental changes, circadian rhythms are also important for orchestrating complex bio

89 Diurnal rhythms are commonly found in behavioral responses to dr

90 Circadian rhythms are daily cycles in biological function that are

91 Circadian rhythms are endogenous 24-h oscillations which regulate

92 We show that parasite rhythms are flexible and lengthen to match the rhythms o

93 Circadian rhythms are generated by interlocked transcription-trans

94 Thus, we propose that parasite rhythms are generated by the parasite, possibly to antic

95 he ensuing interictal up states of slow wave rhythms are more intense in epileptic than control anima

96 Behavioral rhythms, such as sleep rhythm, are usually disrupted in people with schizophren

97 groups of initial shockable and nonshockable rhythms as well as EMS-witnessed and unwitnessed cardiac

98 ibes the generation and interaction of these rhythms, as well as their modulation by dopamine.

99 l or persistent atrial fibrillation in sinus rhythm at baseline were randomly assigned in a 1:1 ratio

100 o return of spontaneous circulation, cardiac rhythm at time of arrest, insurance status, Charlson Com

101 This ratio varied considerably according to rhythm (atrial fibrillation 8.03:1; no atrial fibrillati

102 higher tempos, with a threshold above which rhythm became highly stereotyped.

103 rrhythmic drug therapy for maintaining sinus rhythm, but its success varies depending on multiple fac

104 an Failure Assessment, and central circadian rhythm by melatonin profile.

105 nces the amplitude of the cellular circadian rhythm by stabilizing the negative arm of the transcript

106 next induced severe disruption of circadian rhythms by exposing ApoE(-/-) mice to constant light for

107 human music finds compelling similarities in rhythm categories and the effects of tempo.

108 The number of rhythm categories decreased at higher tempos, with a thr

109 ents using small molecules can disrupt these rhythms, causing a phase shift, and we aim to determine

110 nile host matures, it develops complex daily rhythms characterized by profound changes in the associa

111 R cycles, hand position during compressions, rhythm check timing, feedback for CPR quality, alternati

112 vaccination clinic were offered a free heart rhythm check.

113 In conclusion, heart rhythm complexity appears to be a promising tool for the

114 to investigate the diagnostic value of heart rhythm complexity in HF patients.

115 ed in 4.9% of the patients assigned to early rhythm control and 1.4% of the patients assigned to usua

116 Early rhythm control included treatment with antiarrhythmic dr

117 ovascular conditions to receive either early rhythm control or usual care.

118 Usual care limited rhythm control to the management of atrial fibrillation-

119 Rate control, rhythm control, and stroke prophylaxis are the cornersto

120 enetics, including new optical therapies for rhythm control.

121 eive antiarrhythmic drug therapy for initial rhythm control.

122 he groups; serious adverse events related to rhythm-control therapy occurred in 4.9% of the patients

123 Early rhythm-control therapy was associated with a lower risk

124 n for which they had not previously received rhythm-control therapy were randomly assigned (1:1) to r

125 stroke, or serious adverse events related to rhythm-control therapy.

126 -activity rhythms, and the central circadian rhythm-controlled melatonin secretion profile.

127 up-regulates adropin expression and induces rhythms correlating with cellular stress-response pathwa

128 The rhythm data sets comprised 590 participants enduring a t

129 ring for >3 years, complete day-to-day heart rhythm data sets were reconstructed for every participan

130 therapeutic strategy to treat various heart rhythm diseases.

131 e & Dementia, Promoting Health & Prevention, Rhythm Disorders & Thromboembolism, Valvular Heart Disea

132 (including stroke, congenital heart disease, rhythm disorders, subclinical atherosclerosis, coronary

133 d to controls, mice that had their circadian rhythms disrupted (ECD) had higher Chlamydia loads, more

134 d to controls, mice that had their circadian rhythms disrupted in this ECD model will have a higher C

135 The brain responds to violations of expected rhythms, due to extraction- and prediction of the tempor

136 external defibrillator programs, analysis of rhythm during chest compressions, CPR before defibrillat

137 s, feedback for CPR quality, and analysis of rhythm during chest compressions.

138 odium) parasites which exhibit developmental rhythms during replication in the mammalian host's blood

139 tefact-free 60-second strips of normal sinus-rhythm ECGs were converted to binary strings using thres

140 mplexity analysis of apparently normal sinus-rhythm ECGs.

141 noncanonical genes have intrinsic circadian rhythms, especially within the liver and kidney.

142 rate that bursts in theta and delta cortical rhythms exhibit complex temporal organization, with long

143 nisms and fitness consequences of biological rhythms exhibited by parasites remain mysterious.

144 e features used in the previous studies, our rhythm features not only improved models' prediction acc

145 Circadian rest-activity rhythm fragmentation and attenuation and ultradian disor

146 lt zebrafish, a logic of the V2a interneuron rhythm-generating circuits involving recurrent and hiera

147 While it is widely accepted that inspiratory rhythm generation depends on the pre-Botzinger complex,

148 urons, which form the kernel for inspiratory rhythm generation, directly modulate cardiovascular acti

149 lt of complex interactions between different rhythm generators.

150 Circadian rhythms govern a large array of physiological and metabo

151 Circadian rhythms govern physiology and metabolism, leading to con

152 applied to electrocardiography during sinus rhythm has recently been shown to detect concurrent epis

153 Historically, fetal circadian rhythms have been considered irrelevant owing to lack of

154 While gamma rhythms have been extensively studied in the adult prefr

155 establish a regulatory link among circadian rhythms, hypoxia response, fatty acid uptake, and NAFLD.

156 have suggested distinct cortical layers, and rhythms implement predictive coding.

157 a reliable measure of the central circadian rhythm in critically ill patients.

158 ust.(11) However, the causal role of gastric rhythm in disgust avoidance is unknown.

159 these dissociative agents elicited a 1-3-Hz rhythm in layer 5 neurons of the retrosplenial cortex.

160 PD), but the molecular role of the circadian rhythm in PD is unclear.

161 oss the brain revealed a similarly localized rhythm in the homologous deep posteromedial cortex that

162 itory factor (MIF) in regulating a metabolic rhythm in the model light-organ symbiosis between Euprym

163 id system, real-time monitoring of circadian rhythm in U2OS cells, and various biochemical assays, we

164 CRFH consists of antiphasic rhythms in activating and repressive modifications gener

165 laboratory studies indicate that these daily rhythms in adverse cardiovascular events are at least pa

166 E(-/-) mice that were indistinguishable from rhythms in ApoE(+/+) mice.

167 Mosquitoes have daily rhythms in behaviors and show a wide range of activity p

168 her lithium differentially impacts circadian rhythms in bipolar patient cell lines and crucially if l

169 SPN networks produce beta rhythms in both conditions, but under high dopaminergic

170 at L-type calcium channels exhibit circadian rhythms in both expression and function in guinea pig ve

171 Daily rhythms in cardiovascular function ensure that increased

172 characterize acute alterations of circadian rhythms in critically ill patients and to evaluate assoc

173 We observed strong circadian reporter rhythms in DRG neurons which are highly entrainable by e

174 dian clocks have evolved to anticipate 24 hr rhythms in environmental demands.

175 There are rhythms in histone H3 lysine 9 and 27 acetylation (H3K9a

176 requires a deeper understanding of seasonal rhythms in host-pathogen interactions.

177 n in the respiratory system, where circadian rhythms in inflammatory lung disease have been appreciat

178 CN) of the hypothalamus, which governs daily rhythms in physiology and behaviour.

179 sodic memory and highlight the role of alpha rhythms in revealing when and where different types of m

180 the circadian period of bioluminescent TTFL rhythms in SCN slices recorded ex vivo Abrogation of cir

181 visualize molecular rhythms in subtypes of master clock neurons to test prin

182 e common and chronic disruption of circadian rhythms in the general population than shift work.

183 reward circuit, exhibits disturbed circadian rhythms in the postmortem brains of depressed patients.

184 of disgusting stimuli disrupts myoelectrical rhythms in the stomach,(9-13) inducing gastric dysrhythm

185 upon Cre recombination, we assess circadian rhythms in two of the major classes of peptidergic neuro

186 ere was a clear dissociation between the two rhythms in V4 that became apparent when the major feedfo

187 lar tachycardia, sinus bradycardia and sinus rhythm including sinus irregularity rhythm.

188 pes displayed lower amplitude in temperature rhythms, increased physical activity in the evening, del

189 behavior in sleep- and wake-related cortical rhythms indicates a mechanism essential for the micro-ar

190 ity (SWA) fluctuated with a 29-min ultradian rhythm, indicating a tendency to move systematically thr

191 ial behavior.SIGNIFICANCE STATEMENT Seasonal rhythms influence emotion and sociability.

192 Circadian rhythms influence many of these phenomena.

193 bove exogenous or stimulus-driven timing and rhythm information.SIGNIFICANCE STATEMENT Biological sys

194 ams, electromyograms, alpha, beta, and theta rhythms, instantaneous heart rates, respiratory rates, a

195 tentially treatable pathologies, assist with rhythm interpretation, and provide prognostic informatio

196 ations occurred independent of the locomotor rhythm, intralimb coordination, and speed-dependent (or

197 d outperform physicians in detecting certain rhythm irregularities(1).

198 One such rhythm is a diurnal shift in symbiont metabolism trigger

199 Rhythm is a prominent feature of music.

200 Dysfunction of the circadian rhythm is one of most common nonmotor symptoms in Parkin

201 activity and highlight that the theta-burst rhythm is relatively privileged in its ability to influe

202 ion between central and peripheral circadian rhythms is a core feature of nearly every genetic, dieta

203 e examine how emerging research on circadian rhythms is being applied to the study of fundamental lun

204 the clock, but how this contributes to overt rhythms is unclear.

205 not involved in the generation of the sleep rhythm itself.

206 neous alpha band activity, a prominent brain rhythm known to influence perceptual reports in general.

207 ting patterns relative to internal circadian rhythms limits the extent of these findings.

208 age is associated with defects in circadian rhythm, loss of circadian regulation is thought to be pa

209 ern of wrist temperature (internal circadian rhythm marker).

210 ective and self-reported sleep and circadian rhythm measures.

211 tients underwent extended outpatient cardiac rhythm monitoring within 12 months of BS and at least 1

212 th recent innovations in diagnostics, remote rhythm monitoring, and big data capabilities, we anticip

213 g therapy, as assessed by continuous cardiac rhythm monitoring.

214 lmonary resuscitation in ICUs had an initial rhythm of bradycardia and poor perfusion.

215 e skin circadian clock, reverses the diurnal rhythm of IMQ-induced ISG expression in the skin.

216 thmia constitutes a problem with the rate or rhythm of the heartbeat, and an early diagnosis is essen

217 g and nonfiring cells slows down the overall rhythm of the SAN.

218 ations in energy state can disrupt circadian rhythms of behavior and physiology, creating a vicious c

219 We first characterized circadian rhythms of behavior, light responsiveness, and molecular

220 intake associated with disrupted transcript rhythms of clock and appetite-regulating genes in the MB

221 Moreover, the typical top-down alpha-band rhythms of closed-eyes rest were significantly decreased

222 rony of parasites are connected to the daily rhythms of hosts and vectors may make treatment more eff

223 ythms are flexible and lengthen to match the rhythms of hosts with long circadian periods.

224 the critical environmental cue synchronizing rhythms of life in seasonal habitats.

225 We compared rhythms of live performances of music to rhythms of wild

226 tly contributes to the establishment of 12-h rhythms of mRNA expression in a manner dependent on Spli

227 alized multilevel dynamic representations of rhythms of multiple homeostatic regulatory systems.

228 sites dictates XBP1s's ability to drive 12-h rhythms of nascent mRNA transcription at dawn and dusk,

229 However, its links to rhythms of nutrient intake, energy balance, and metaboli

230 Growing evidence demonstrates circadian rhythms of pain hypersensitivity in various chronic diso

231 Circadian (approximately daily) rhythms of physiology and behaviour adapt organisms to t

232 smodium chabaudi underlies the 24-hour-based rhythms of RBC bursting in mice.

233 ents were: (a) Chronotype objectively (7-day-rhythms of TAP) and subjectively measured (Munich-chrono

234 for how patients' behavioral rhythms and the rhythms of their environments influence their symptom co

235 red rhythms of live performances of music to rhythms of wild thrush nightingale and domestic zebra fi

236 ating the effects of disruption of circadian rhythms on human health.

237 is an intrinsic oscillator that imparts 24 h rhythms on immunity.

238 We discuss the impact of circadian rhythms on society and the challenges for the imminent f

239 ad a dose-dependent impact on cochlear clock rhythms only after treatment at nighttime suggesting tha

240 ping was performed pre-ablation during sinus rhythm or LA pacing, and electrogram locations were core

241 he preBotzinger Complex, where the breathing rhythm originates, and use genetic tools to reveal that

242 song and are structurally similar to fusion rhythms (ornaments) in music.

243 rom fibroblast cell lines have heterogeneous rhythms, oscillating independently and with different pe

244 In sinus rhythm patients undergoing cardiac surgery, histopatholo

245 and clearance exhibit endogenous, circadian rhythms peaking during the mid-rest phase of mice.

246 We also show that malaria rhythms persist even when host food intake is evenly spr

247 Circadian (approximately daily) rhythms pervade mammalian behavior.

248 This alternating EEG rhythm phase is likely to underlie the dissociative acti

249 ants, were strongly associated with a severe rhythm phenotype and perinatal death: 9 (82%) showed sig

250 hy to characterize the electrophysiology and rhythm phenotypes of fetuses with de novo and inherited

251 ity of rhythm violations affects the overall rhythm predictability.

252 gan Failure Assessment score), and circadian rhythms (profiles of serum melatonin and its urinary met

253 scoveries of the interplay between circadian rhythms, proliferative metabolism and cancer, highlighti

254 ional alterations in the circadian molecular rhythms, providing a mechanistic link to the behavioral

255 The central circadian rhythm rapidly dampens with onset of critical illness, b

256 Gene expression rhythms rapidly become abnormal during critical illness.

257 In both species, preferred rhythms remained invariant over extended ranges of tempo

258 ism control circadian behavioral and genomic rhythms remains unknown.

259 % (2.9%-4.5%) in patients with pAF and sinus rhythm, respectively.

260 As such, behavioral rhythm sensing with smartphones and machine learning can

261 cellular location with the fastest intrinsic rhythm should act as a pacemaker for the process.

262 ng hippocampal function, as this stimulation rhythm should resonate with the endogenous theta-nested-

263 Rest-activity rhythms showed no detectable phase coherence with melato

264 nt article from representatives of the Heart Rhythm Society, the American College of Cardiology, and

265 imposed on an AFL substrate (AF+AFLs); sinus rhythm (SR) with an AFL substrate (SR+AFLs; control grou

266 Angina, initial shockable rhythm, ST-segment elevation, and absence of known coron

267 Measures of daily rhythm strength were blunted, and sleep drive increased.

268 of at least 30 seconds duration confirmed by rhythm strip or 12-lead ECG.

269 Analysis of the rhythm structure of the songs of two songbird species an

270 Behavioral rhythms, such as sleep rhythm, are usually disrupted in

271 BS (altDBS) could entrain patients' stepping rhythm, suggesting a causal role of the STN in dynamic g

272 of sleep and biological (diurnal, circadian) rhythms, suggesting common pathophysiologies across spec

273 gation via the theta oscillation, a ~4-10 Hz rhythm that coordinates brain-wide neural activity.

274 ct the regular and rapidly alternating sleep rhythm that is characteristic of sleep in this species(3

275 e implemented via lower-frequency alpha/beta rhythms that "prepare" pathways processing-predicted inp

276 where they generate circadian (about a day) rhythms that allow organisms to anticipate regular envir

277 This review highlights rhythms that underpin cardiac physiology.

278 Compared to those with initial pulseless rhythms, these children were younger (0.4 vs 1.4 yr; p =

279 st kidney-related functions, follow specific rhythms tied to a 24-h cycle.

280 h no AF (mean age, 54 years +/- 16) in sinus rhythm to establish control values and convert these val

281 ificantly increased from patients with sinus rhythm to paroxysmal AF and persistent AF, respectively.

282 diovascular system exhibits strong circadian rhythms to maintain normal functioning.

283 This was not true for diurnal rhythms under pentobarbital and avertin, but both still

284 We manipulated gastric rhythm using domperidone, a peripheral dopamine D2/D3 an

285 Yet, it is unknown how probability of rhythm violations affects the overall rhythm predictabil

286 uncover ion channels with roles in circadian rhythms, we have identified the I(h) channel as an impor

287 pathways involving metabolism and circadian rhythm were noted in insulin-responsive tissues.

288 High-ratio rhythms were abundant in the nightingale song and are st

289 e changes due to menstruation, and circadian rhythms were controlled for in the experimental design.

290 Isochronous 1:1 rhythms were similarly common.

291 hronize the central and peripheral circadian rhythms, which in turn can prevent or even treat the met

292 exposure to drugs of abuse alters circadian rhythms, which may contribute to subsequent SU.

293 se-related AF) and from 39 patients in sinus rhythm with mitral valve regurgitation (group 2; 32 male

294 Rhythms with changing amplitudes identified from publish

295 HO outperforms existing methods in detecting rhythms with decreasing oscillation amplitudes and in re

296 e temporal organization of dominant cortical rhythms with empirical observations across scales.

297 GLP-1 also exhibits a circadian rhythm, with highest release at the onset of the feeding

298 red to control individuals with normal heart rhythm, with loss of calcitonin receptors in the fibrobl

299 r adjustment for age, gender, cardiac arrest rhythm, witnessed status, bystander cardiopulmonary resu

300 ronmental stimuli that entrain the circadian rhythm (zeitgebers), rest-activity rhythms, and the cent