ライフサイエンスコーパス: energy demand

1 low-income countries exposed to increases in energy demand.

2 adapt to the metabolic challenges of altered energy demand.

3 to offset projected increases in residential energy demand.

4 for the treatment of disorders with altered energy demand.

5 neuronal dendrites and localize to sites of energy demand.

6 tivity of the matrix and the concomitant low energy demand.

7 ns yield desirable products with a decreased energy demand.

8 d fuels the tricarboxylic acid cycle to meet energy demand.

9 cristae were widened, suggesting a sustained energy demand.

10 ron allows for clustering at regions of high-energy demand.

11 singly rely on coal to satisfy their growing energy demand.

12 tial to meet the rapid worldwide increase in energy demand.

13 ing a stimulus paradigm that increased local energy demand.

14 olism is expected to meet the quickly rising energy demand.

15 l fuel resources, fresh water resources, and energy demand.

16 ty at the neuromuscular junction during high energy demand.

17 options through their impact on economy-wide energy demand.

18 ations on greenhouse gas (GHG) emissions and energy demand.

19 nto a global issue because of the increasing energy demand.

20 challenges encountered by the growing global energy demand.

21 achieve a substantial efficiency for future energy demand.

22 g to the inability to cope up with increased energy demands.

23 stem to meet the activity-driven increase in energy demands.

24 e to the cellular environment and changes in energy demands.

25 ally meet water quality goals while reducing energy demands.

26 ptake active normally in neurons to maintain energy demands.

27 and can charge and discharge quickly for low energy demands.

28 and act as slow, steady suppliers for large energy demands.

29 ycolysis are adapted to the different axonal energy demands.

30 mphis utilized oxidative metabolism to meet energy demands.

31 t of North American plans for meeting future energy demands.

32 pumping function in the context of changing energy demands.

33 The heart is a muscle with high energy demands.

34 help cells to produce more ATP to meet their energy demands.

35 pon endurance training to cope with enhanced energy demands.

36 can equally be used for different, competing energy demands.

37 o produce high quality effluent with minimal energy demands.

38 homes use solid fuel to meet their household energy demands.

39 e solutions to meet the increasing worldwide energy demands.

40 technologies to meet ever-increasing global energy demands.

41 hich requires metabolic changes to match the energy demands.

42 HSCs use glycolytic metabolism to meet their energy demands.

43 r cells undergo glutaminolysis to meet their energy demands.

44 d cell death, while meeting dynamic cellular energy demands.

45 nt regulatory role in lipid homeostasis upon energy demands.

46 drial oxidative phosphorylation according to energy demands.

47 active, relying on fatty acids to meet their energy demands.

48 ems that are largely driven by the metabolic energy demanded.

49 t the HR and associated processes are highly energy demanding.

50 Proximal tubular epithelial cells are highly energy demanding.

51 eneration of the alkaline solution is highly energy-demanding.

52 a significant contribution to N. norvegicus energy demand (0.21 to 10.7 times the energy required fo

53 t moment-to-moment changes in regional brain energy demand(1).

54 echanisms to tightly couple fuel supply with energy demand across a wide range of physiologic and pat

55 conserve metabolic stores and participate in energy-demanding activities that are critical for fitnes

56 ms are unclear but may involve alteration in energy-demanding activities, such as protein synthesis.

57 ndrial clusters are found at regions of high-energy demand, allowing cells to meet local metabolic re

58 This paradoxical combination of increased energy demands along with decreased masticatory and dige

59 Nickel hexacyanoferrate exhibited the lowest energy demand among all of the materials and exhibited t

60 h heart rate is a key determinant of cardiac energy demand, AMPK functions in an organ-specific manne

61 dition muscle mitochondria to meet increased energy demand-an adaptive response associated with impro

62 nt scenario is better in terms of cumulative energy demand and abiotic resource depletion potential ~

63 onsiderably according to the balance between energy demand and availability.

64 Parameters affecting operational energy demand and energy conversion are the most influen

65 tion probably exacerbates a mismatch between energy demand and energy production when myocardial oxyg

66 Global energy demand and environmental concerns have stimulated

67 ies, resulting in considerably lower primary energy demand and GHG emissions.

68 alysis is a potential solution to satisfying energy demand and its resulting environmental impact.

69 loping world faces dual crises of escalating energy demand and lack of urban sanitation infrastructur

70 ic phenotypes to meet the challenges of high energy demand and macromolecular synthesis.

71 itochondrial dynamics to the balance between energy demand and nutrient supply, suggesting that chang

72 l fission and fusion are highly regulated by energy demand and physiological conditions to control th

73 nction of axonal mitochondria and imbalanced energy demand and supply are implicated in degeneration

74 Current dogma holds that the heart balances energy demand and supply effectively and sustainably by

75 ultiobjective optimization model of building energy demand and supply for the case of a Swiss municip

76 nt cardiomyocytes exhibit a mismatch between energy demand and supply that facilitates their transiti

77 The rapid increase in global energy demand and the need to replace carbon dioxide (CO

78 position of a mammalian cell we quantify the energy demand and the OxPhos burden of cell biosynthesis

79 ies for accommodating increases in metabolic energy demand and their biological limitations can serve

80 d thermal simulation to quantify operational energy demand and to account for differences in thermal

81 The unit energy demand and unit flow information were adopted fro

82 nsitive to climate-driven variations in both energy demand and water availability, yet the combined e

83 as well as trade-off analysis between rising energy demand and water use sustainability.

84 e focal plane, existing techniques are slow, energy demanding and mainly relying on numerous acquisit

85 a-C(sp(3))-H bond activation relatively less energy demanding and opens the possibility for a competi

86 l window capable of engaging a wide range of energy demanding and synthetically relevant organic subs

87 Growing global energy demands and climate change motivate the developme

88 as a node coordinating liver growth with its energy demands and emphasize the need of lipids for rege

89 astewater carbonaceous substrates can offset energy demands and enable net power generation; yet, the

90 ogy considered, but had significantly higher energy demands and environmental emissions.

91 k the host cell metabolism to meet their own energy demands and how this may contribute to tumorigene

92 As coordinators of energy demands and nutritional supplies, the PGC-1 famil

93 at forms in vivo near synapses to meet local energy demands and support synaptic function in Caenorha

94 mperature is thought to increase maintenance energy demands and thereby decrease available resources

95 ic transmission is expensive in terms of its energy demands and was recently shown to decrease the AT

96 Eukaryotic ribosomal biogenesis is a high-energy-demanding and complex process that requires hundr

97 tt-induced neurotoxicity because neurons are energy-demanding and particularly susceptible to energy

98 lls replenish ATP poorly following surges in energy demand, and chronic ATP insufficiency endangers c

99 to quantify greenhouse gas emissions, fossil energy demand, and criteria air pollutant emissions for

100 related greenhouse-gas emissions, cumulative energy demand, and land occupation gradually decreased w

101 cators (greenhouse gas emissions, cumulative energy demand, and land occupation); 3) economic indicat

102 tivity is important under conditions of high energy demand, and that specific cell types are uniquely

103 ntial indicator, the nonrenewable cumulative energy demand, and the Swiss ecological scarcity indicat

104 onal strategies for coupling CO(2) R to less energy demanding, and value-added, oxidative chemistry.

105 ntegrated assessment of multiple feedstocks, energy demands, and system costs is critical for making

106 idal alternatives exist, but high cost, high energy demands, and/or formation of disinfection byprodu

107 of a smart synthesis of methane hydrates in energy-demanding applications (for example, transportati

108 Cellular energy demands are met by uptake and metabolism of nutri

109 bolic costs, the biochemical bases of actual energy demands are rarely quantified.

110 tive phosphorylation to neuronal presynaptic energy demands are unclear.

111 Because neurons, which have a high energy demand, are particularly dependent on the mitocho

112 e more glucose than normal cells to meet the energy demand arising due to their uncontrolled prolifer

113 addressing climate-change issues and global energy demands as part of a carbon-neutral energy cycle.

114 l bioenergetics to meet fluctuating neuronal energy demands as well as for neuronal information proce

115 -caused climate hazards and ever-increasing energy demands, as it can utilize CO(2) in the atmospher

116 tivity create local and transient changes in energy demands at synapses.

117 te) warming increases global climate-exposed energy demand before adaptation around 2050 by 25-58% (1

118 The retina has a very high energy demand but lacks an internal blood supply in most

119 al conversion is of great promise for future energy demands, but often limited by the kinetically slu

120 h swimming cycle, thereby reducing metabolic energy demand by swimming muscles.

121 port chain, with excess ATP going toward the energy-demanding Calvin-Benson-Bassham (CBB) pathway.

122 However, due to their high energy demands, cardiac cells are disproportionately tar

123 Other indicators, such as Cumulative Energy Demand (CED) and EcoIndicator99 H were calculated

124 parative life cycle assessment of cumulative energy demand (CED) and global warming potential (GWP) o

125 icity and provided higher GWP and cumulative energy demand (CED) reduction compared to only using SLB

126 HG) emissions, water consumption, cumulative energy demand (CED), and energy payback time (EPBT).

127 of energy sensing and production with highly energy-demanding cellular processes, such as cell divisi

128 esources in areas distant from the origin of energy demand complicate the design of policy to ensure

129 ntensive subsector of health care, with high energy demands, consumable throughput, and waste volumes

130 As world energy demand continues to rise and fossil fuel resource

131 h microbial carbon (MBC) demand, a proxy for energy demand (cost), during soil microbial response to

132 to environmental glucose depletion and other energy-demanding cues.

133 and we obtained full conversion for the very energy-demanding decomposition of a persistent ammonium

134 these specific anaplerotic steps can support energy demand despite HIFs degradation.

135 udy, we tested the hypothesis that increased energy demand during beta-AR stimulation plays an import

136 These data suggest that increased energy demand during sustained beta-AR stimulation weake

137 and chemokinesis and provided adaptation to energy demand during tracking and engulfment.

138 sary for meeting the increased metabolic and energy demands during organ recovery after acute injury,

139 Increasing energy demand, especially in the transportation sector,

140 particularly neurons, at risk of death when energy demands exceed cellular energy production.

141 , at risk of dysfunction and even death when energy demand exceeds cellular energy production.

142 changes for copper, we modeled and analyzed energy demand, expressed in fossil energy equivalents (F

143 ssors, such as predation, induce a rapid and energy-demanding fight-or-flight response, long-term env

144 which could satisfy up to 60% of the overall energy demand for biogas upgrading.

145 ergo metabolic changes to support their high energy demand for effector function and proliferation.

146 lows cells to sense and respond to increased energy demand for G2/M transition and, subsequently, to

147 ntal impacts (between 67 and 98%) except for energy demand for tilapia, contradicting previous findin

148 the methane in a biogas stream can meet the energy demands for aeration and agitation, and recovery

149 to supply the substrates needed to cover the energy demands for exercise, to ensure quick recovery be

150 a pro-oxidant environment and the increased energy demands for neonatal survival.

151 oteins in these pathways, to meet carbon and energy demands for siderophore precursors in accordance

152 ized in the case of food deprivation or high energy demands--for example, during certain developmenta

153 globally in 2070 or approximately 15% of the energy demand from transport.

154 n and Taf14 participate in the repression of energy-demanding gene expression.

155 six impact categories, including cumulative energy demand, global warming (IPCC 2007), acidification

156 bally problematic emissions and material and energy demands, have not been examined in detail.

157 is finely tuned for ATP delivery to sites of energy demand; however, emergent phenomena, such as mito

158 c shifts yield sufficient precursors to meet energy demand; however, this does not translate to enhan

159 on, cancer cells have increased anabolic and energy demands; however, different cancer cell types exh

160 to replenish brain ATP during times of high energy demand in BD.

161 Aeration accounts for the largest energy demand in conventional activated sludge wastewate

162 Energy demand in global climate scenarios is typically d

163 Cortical signaling requirements dominated energy demand in the awake state, whereas nonsignaling r

164 aeration, which currently incurs the highest energy demand in wastewater treatment.

165 ndicate that under energy stress conditions, energy demands in C. elegans synapses are met locally th

166 exposed to intense daylight and have higher energy demands in darkness.

167 one volume, minimal weight, and also minimal energy demands in maintenance.

168 w provides an overview of ATP production and energy demands in the kidney and summarizes preclinical

169 ly allocate cellulosic biomass feedstocks to energy demands in transportation, electricity, and resid

170 dria play critical roles in meeting cellular energy demand, in cell death, and in reactive oxygen spe

171 rrier to generate power for all of society's energy demands including grid, industrial, and transport

172 n may be significant to the chosen timing of energy demanding interventions to improve function and h

173 Indeed, T2 correlated with energy-demanding intracellular translocation of the inju

174 Dynamic coupling of blood supply with energy demand is a natural brain property that requires

175 Total cumulative energy demand is comparable.

176 Global energy demand is increasing as greenhouse gas driven cli

177 Future energy demand is likely to increase due to climate chang

178 Meeting the growing global energy demand is one of the important challenges of the

179 hway by which photoreceptors meet their high energy demands is not fully understood.

180 etwork reconfigurations and their underlying energy demands is poorly understood.

181 ce greenhouse gas (GHG) emissions and fossil energy demand, is increasingly seen as a threat to food

182 in hepatic metabolic adaptation to increased energy demands; it preserves tissue iron for vital activ

183 e freshwater eutrophication, climate change, energy demand, land use, and dependency on animal-source

184 E because photoreceptor cells have very high energy demands, largely satisfied by oxidative metabolis

185 This inability to meet the increased energy demand leads to activation of cell death.

186 goals, and show how the target depends upon energy demand levels.

187 ty, typically necessitating the operation of energy-demanding low temperature fractional distillation

188 that seen in PD, and suggests that increased energy demand may contribute to the mechanism by which L

189 ning global mine production data resulted in energy demand median values of around 50 MJ/kg Cu irresp

190 To survive, cells must fine-tune energy-demanding metabolic processes in response to nutr

191 on to nutrient availability and supports the energy-demanding metabolism of cancer cells.

192 rast to their role in cell types with higher energy demands, mitochondria in endothelial cells primar

193 oducts per household) and impact (cumulative energy demand (MJ) and greenhouse gas emissions (MT CO2

194 The ever-increasing energy demand motivates the pursuit of inexpensive, safe

195 of BDNF, which is intimately associated with energy-demanding neuronal activity.

196 om the influent was 151 gN m(-2) d(-1) at an energy demand of 26.1 kJ gN(-1).

197 ed at a current density of 50 A m(-2) and an energy demand of 56.3 kJ gN(-1).

198 This study provides estimation tools for the energy demand of a representative set of food process un

199 rving the intricate balance between the high energy demand of active neurons and the supply of oxygen

200 eover, the model is utilized to quantify the energy demand of amino acid and enzyme de novo synthesis

201 has little impact on Trichodesmium, and the energy demand of anti-stress responses to OA has a moder

202 The brain has the highest mitochondrial energy demand of any organ.

203 n and chemical catalysis, while reducing the energy demand of the overall process.

204 The energy demand of the temperature-vacuum-swing adsorption

205 urons through glycolysis to satisfy the high energy demand of these cells.

206 Nonrenewable cumulative energy demand of wooden buildings is 18% lower, compared

207 vements, and we modeled the consequences for energy demands of adult females in the Beaufort and Chuk

208 The higher energy demands of brain communication that hinges upon h

209 lect, here we propose a simple model for the energy demands of brain functional connectivity, which w

210 up-regulation of respiration supporting the energy demands of cancer cells.

211 cose uptake and ATP accumulation to meet the energy demands of chemotaxis in activated T cells.

212 ted a comprehensive literature study for the energy demands of CO2 supply, and constructed a database

213 The energy demands of data centers (DCs) worldwide are rapid

214 observations have led to the hypothesis that energy demands of electrochemical desalination systems c

215 To meet the high-energy demands of embryogenesis, mature oocytes are furn

216 nd efficiency to best support the growth and energy demands of fetoplacental tissues during late gest

217 gy will be better suited to satisfy the high-energy demands of growing urban areas.

218 grated metabolic machinery to meet the large energy demands of growth, differentiation, and synaptic

219 es, this method will facilitate the study of energy demands of living systems with subcellular resolu

220 g glucose uptake and ATP production to match energy demands of migration.

221 cannot respond adequately to the increase in energy demands of neuronal activity.

222 the cortex that allows the brain to meet the energy demands of neuronal computations?

223 n maintenance of the synapse and meeting the energy demands of neurons.

224 ulates feeding behavior in response to local energy demands of peripheral tissues, which secrete orex

225 nsion balancing energy uptake with increased energy demands of pregnancy.

226 males accrue fitness benefits by timing peak energy demands of reproduction to coincide with maximum

227 l was able to capture variations in reported energy demands of selected mining sites (FEE: 0.07 to 0.

228 inct metabolic programs to meet the changing energy demands of self-renewing HSCs.

229 Astrocytes support the energy demands of synaptic transmission and plasticity.

230 The energy demands of the adult mammalian heart are met larg

231 systems mount adaptive responses to meet the energy demands of the cell and to compensate for dysfunc

232 ntiating stem cells is required to cover the energy demands of the different organ-specific cell type

233 nd capacity for ATP production with changing energy demands of the heart.

234 atteries have the potential to meet the high-energy demands of the next generation of batteries.

235 d therefore has the potential to support the energy demands of the pelagic aquatic food web.

236 eostasis during cold exposure, the increased energy demands of thermogenesis must be counterbalanced

237 and/or neurological symptoms due to the high-energy demands of these tissues.

238 activity of PV(+) interneurons imposes high-energy demands on their metabolism that must be supplied

239 r-limit of 5-30% of the current U.S. primary energy demand or 4-30% of the current U.S. liquid fuel d

240 llular energy homeostasis in periods of high-energy demand or energy supply fluctuations.

241 oxidation, the process required to fuel high energy-demanding pathways (e.g., gluconeogenesis and gly

242 ged fasting, making lactation a tremendously energy demanding period.

243 Under unfed or during energy-demanding phases of the circadian cycle, CREBH is

244 ls in the visual cortex during times of high energy demand (photic stimulation).

245 o fix atmospheric N2 to NH3 through the less energy-demanding photochemical process.

246 electron-transporting catalyst to carry out energy-demanding photochemical reactions.

247 s by which ASD cells try to adapt to altered energy demand, possibly resulting from a chronic oxinfla

248 Since eukaryotic gene expression is an energy demanding process, differences in the energy budg

249 d suggest that cell division is not a highly energy demanding process.

250 Because cancer progression is an energy-demanding process and PTEN is known to regulate m

251 T cell activation is an energy-demanding process fueled by increased glucose con

252 Nitrogen fixation is an energy-demanding process requiring tight control of meta

253 Ribosome biogenesis is a complex and energy-demanding process requiring tight coordination of

254 Neuronal regeneration is a highly energy-demanding process that greatly relies on axonal m

255 Adaptive thermogenesis is an energy-demanding process that is mediated by cold-activa

256 enesis (RiBi) is one of the most complex and energy demanding processes in human cells, critical for

257 eparation of hydrocarbons is one of the most energy demanding processes.

258 mbryonic tissues develop to support the more energy-demanding processes of cell division and organoge

259 apacity, making them more vulnerable to high energy-demanding processes such as ischemia.

260 Symbiotic rhizobia-legume interactions are energy-demanding processes, and the carbon supply from h

261 Based on future world energy demand projections, we estimate that if growth of

262 ission reductions and greater variability in energy demand projections.

263 memory, a cognitive function reliant on the energy-demanding recurrent excitation of neurons within

264 The relative impact of energy demand reduction measures compared to decarboniza

265 As body condition is a 'barometer' of energy demands relative to energy intake, we explored th

266 Lastly, the thermal energy demand required for the case of active temperatur

267 By 2100 transport energy demand rises >1000% in Asia, while flattening in

268 We find broad agreement among ESMs that energy demand rises by more than 25% in the tropics and

269 ental under multiple-stressors exposures and energy-demanding scenarios, which remains to be validate

270 rial membrane potential varies, depending on energy demand, subcellular location, and morphology and

271 very of a tandem catalytic process to reduce energy demanding substrates, using the [Ir(ppy)(2)(dtb-b

272 al function is required in tissues with high energy demand such as the heart, and mitochondrial dysfu

273 lectron transfer (SPLET) mechanisms are less energy demanding than the first ones indicating 2H(+)/2e

274 to cope with changes in nutrient supply and energy demand that naturally occur throughout the day.

275 Nutrient enrichment might offset some of the energy demands that warming can exert on organisms by st

276 es in regards to the nonrenewable cumulative energy demand, the ecological scarcity indicator, and li

277 Under high glucose and increased energy demand, the metabolic/fluxomic redirection leadin

278 Under low energy demand, the mitochondrial electron transport syst

279 Besides satisfying annual final energy demand, the model constraints comprise availabili

280 from adenylate kinase during states of high energy demand, the ornithine cycle enzyme argininosuccin

281 respiration increases to adapt for increased energy demands; the underlying mechanisms are still not

282 e a range of pathologies, commonly affecting energy-demanding tissues such as muscle and brain.

283 , we report that COX7AR is expressed in high energy-demanding tissues, such as brain, heart, liver, a

284 s distinct functions in energy-producing vs. energy-demanding tissues.

285 The brain regulates blood flow to match energy demand to nutrient supply.

286 sorption of hexoses to support the increased energy demand to trigger plant defense reactions and to

287 bservations indicate that AMPK couples local energy demands to subcellular targeting of mitochondria

288 is crucial to cover the increasing cellular energy demand under growth conditions.

289 o modeled ATP/NADPH demand, CEF responded to energy demand under high light but not low light.

290 is in white adipose tissue (WAT) to adapt to energy demands under stress, whereas superfluous lipolys

291 hemical flow cell with respect to volumetric energy demands (W.h.L(-1)) and thermodynamic efficiencie

292 antly higher in every perturbation where the energy demand was either higher or uncompromised.

293 ditions, which enables the body to cope with energy demand when oxygen supply is insufficient.

294 igher temperatures increased community-level energy demand, which was presumably satisfied by higher

295 d firing of axons, with consequent increased energy demands, which may lead to neuroaxonal degenerati

296 To meet the growing energy demand while mitigating the environmental concern

297 Due to population growth, food and energy demands will soon surpass supply capabilities.

298 m that allows muscle to integrate autonomous energy demand with systemic energy storage and turnover.

299 within minutes as they cannot meet cellular energy demands with anaerobic metabolism.

300 Global energy demand would be offset by solar production if eve