ライフサイエンスコーパス: energy supply

1 or transcriptional repression of glucose and energy supply.

2 The network may control energy supply.

3 generation of ATP as a main source of their energy supply.

4 brium between RGC activity and the available energy supply.

5 chondria to enhance local Ca2+ buffering and energy supply.

6 key role in the realization of a sustainable energy supply.

7 cular perfusion and not scarcity in cellular energy supply.

8 e local regulation of Ca(2+) homeostasis and energy supply.

9 nal starving therapy by only cutting off the energy supply.

10 nable various wearable devices and auxiliary energy supply.

11 are required to provide a sustainable, green energy supply.

12 a new avenue of CO2 reduction for renewable energy supply.

13 ors of B-lymphoid restriction of glucose and energy supply.

14 g transport and country-specific impacts for energy supply.

15 ts of neuronal swelling in conditions of low energy supply.

16 local microenvironment to enable a constant energy supply.

17 rns observed in plants starved for carbon or energy supply.

18 policy to ensure security of fresh water and energy supply.

19 ermediates to DMADP was limited by reductive energy supply.

20 k of drinking water treatment facilities and energy supply.

21 erent glycolytic pathways depending on their energy supply.

22 esigned to perform a random walk without any energy supply.

23 rsued as a means of starving tumors of their energy supply.

24 evels compatible with signaling and reliable energy supply.

25 by affecting free-radical production and the energy supply.

26 e photosynthesis and respiration and deplete energy supplies.

27 und production (20-550 Hz) without exceeding energy supplies.

28 rentially adopt aerobic glycolysis for their energy supply, a phenomenon known as the Warburg effect.

29 levels of energy efficiency and decarbonized energy supply alone are not sufficient; widespread elect

30 sure that policy makers acknowledge risks to energy supplies and develop strategies or contingency pl

31 Among the greatest uncertainties in future energy supply and a subject of considerable environmenta

32 c reticulum (ER) is exquisitely sensitive to energy supply and amino acid sources because deficiencie

33 zyme Q biosynthesis, assuring an appropriate energy supply and antioxidant functions.

34 ular smooth muscle contractility and matches energy supply and demand by down-regulating energy-requi

35 udies have suggested that imbalances between energy supply and demand can result in "inflammatory hyp

36 The resultant shifts in energy supply and demand can result in metabolic acidosi

37 ity and thus play a pivotal role in matching energy supply and demand in cardiac muscle.

38 ity and thus play a pivotal role in matching energy supply and demand in cardiac muscle.

39 processes that contribute to the control of energy supply and demand in the heart.

40 Matching energy supply and demand is critical in the bioenergetic

41 tive phosphorylation and thus contributes to energy supply and demand matching in cardiac myocytes.

42 rial Ca2+ uptake, with consequent effects on energy supply and demand matching.

43 These shifts in energy supply and demand result in localized regions of

44 wing pacing, suggesting impaired matching of energy supply and demand.

45 es in order to adapt with diurnal changes in energy supply and demand.

46 homeostasis by preventing mismatches between energy supply and demand.

47 ced inotropic response with no compromise in energy supply and demand.

48 th related to the brain injury of inadequate energy supply and disrupted ion homeostasis.

49 Depressed cortical energy supply and impaired synaptic function are predomi

50 to mitochondrial dysfunction with decreased energy supply and increased hepatic injury.

51 els the direct and indirect CO2 emissions of energy supply and infrastructure technologies within a n

52 impaired physiological response to nutrient energy supply and insulin stimulation.

53 ior volumetric growth is linked to increased energy supply and is associated with an overall increase

54 dium falciparum rely on glycolysis for their energy supply and it is unclear whether they obtain ener

55 venting MPT onset and subsequent compromised energy supply and proapoptotic cytochrome c release.

56 of sustainably expanding and improving their energy supply and reliability while at the same time red

57 fatty acids and the role of mitochondria in energy supply and stress amelioration.

58 ma leptin concentrations to small changes in energy supply and suggest a basic role of substrate meta

59 t pathways for the decarbonization of global energy supply and the implementation of negative emissio

60 myocardial energy metabolism resides both in energy supply and utilization.

61 st maintain a continuous balance between its energy supply and work performed.

62 lure (CHF) may involve a relative deficit in energy supply and/or delivery.

63 nvolved in cellular defense, fat metabolism, energy supply, and chaperones were identified as being o

64 l resources, climate protection, security of energy supply, and workplace collaborations are all exam

65 lity of PDGF-BB to be a vasoconstrictor when energy supplies are ample and to be a vasodilator under

66 These data support the hypothesis that energy supplied as carbohydrate is more effective than e

67 t storage) of a controlled excess of dietary energy supplied as different carbohydrate sources or as

68 plied as carbohydrate is more effective than energy supplied as fat in sparing protein oxidation in e

69 consortium provides the host with an optimal energy supply as it shuttles between the upper oxic and

70 with mannitol used As(III) as a supplemental energy supply as reflected by enhanced growth and increa

71 erlying cytotoxic edema in conditions of low energy supply, as observed in cerebral ischemia.

72 Advection of gas and ice transports energy, supplied at depth as latent heat of clathrate de

73 d membrane vesicles accumulated Sb(III) with energy supplied by NADH oxidation, reflecting efflux fro

74 e cells accumulated MAs(III) > Rox(III) with energy supplied by NADH oxidation, reflecting efflux fro

75 d with ion pumps; neurons may increase their energy supply by activating glycolysis in astrocytes to

76 feeds get converted into a benign metabolic energy supply by an interplay between the membrane's spa

77 e cell's energy needs, and it also regulates energy supply by controlling the number, quality, and dy

78 Active neurons increase their energy supply by dilating nearby arterioles and capillar

79 en the crucial roles for mitochondria in ATP energy supply, Ca(2+) handling and cell death, mitochond

80 ochondria to basic cellular function such as energy supply, calcium homeostasis and, more recently, p

81 A diminished energy supply can be rationed based on the relative ATP

82 ombined capacity of current agricultural and energy supply chains, including grain, petroleum, and co

83 in CQR lines is not directly coupled to the energy supply, consistent with a model in which mutant P

84 As limitations in energy supply constrain neural function, high-probabilit

85 ate on Drosophila locomotion, perhaps due to energy supply constraints.

86 optimal case, greenhouse gas emissions from energy supply could be reduced by more than 75% and part

87 e show that, after transient blockade of the energy supply, cytotoxic edema may be reversed by tempor

88 oupling, modulation of contractile function, energy supply-demand balance (including mitochondrial fu

89 By uncoupling energy supply-demand balance, glycolytic oscillations ma

90 mitochondrial metabolism to daily changes in energy supply/demand and thereby, serve as a rheostat fo

91 llular functions are powered by a continuous energy supply derived from cellular metabolism.

92 To conserve energy supplies during fasting, A-ZIP/F-1 (but not contr

93 T3 represents a novel pathway for control of energy supply during neuronal activity that is critical

94 medium were required as building blocks and energy supply during wri1-1 seedling establishment.

95 ecosystems suggest that FCL is determined by energy supply, environmental stability, and/or ecosystem

96 neuron, we show that a tipping point of the energy supply exists, below which the cell volume rapidl

97 eostasis in periods of high-energy demand or energy supply fluctuations.

98 ant for plant survival because it guarantees energy supplies for growth and development during plant

99 of early mortality while ensuring sufficient energy supply for both it and the vector.

100 erhaps partly due to a substantially reduced energy supply for excitation-contraction coupling result

101 coactivator 1-alpha (PGC1alpha) to maintain energy supply for locomotion and survival.

102 evolution reaction may provide a sustainable energy supply for the future, but its commercial applica

103 pre-condition can effectively reduce ocean's energy supply for typhoon intensification during typhoon

104 e-induced withdrawal) in planarians requires energy supplied from glucose metabolism.

105 with, or larger than, the entire present-day energy supply from all sources combined.

106 contribution of nuclear power to the global energy supply has become somewhat uncertain.

107 Lack of an appropriate energy supply has been thought to induce cell death in a

108 to low oxygen conditions, which ensure basic energy supply, have been well characterized, adaptation

109 Consequently, the brain's limited energy supply imposes constraints on its information pro

110 min B1) is ubiquitous and essential for cell energy supply in all organisms as a vital metabolic cofa

111 ctivated fetal gene expression, and restored energy supply in failing cardiomyocytes.

112 Glucocorticoids (GCs) regulate energy supply in response to stress by increasing hepati

113 physical endurance that indicates diminished energy supply in the body.

114 body consumption as an alternative source of energy supply in the heart.

115 imitation of nutrient availability and light energy supply in wild-type Arabidopsis produced phenotyp

116 failing heart is hypothesized to suffer from energy supply inadequate for supporting normal cardiac f

117 c MFA of the associated steel, aluminum, and energy supply industries.

118 velopment are the consequences of diminished energy supply: inhibition of beta-oxidation, leptin resi

119 sors is integrating transport functions with energy supply into the device.

120 is that can be recovered by ion pumps if the energy supply is adequate.

121 able energy, while its use for an industrial energy supply is impaired by low efficiency.

122 g circuits, which promote energy intake when energy supply is limited.

123 Thus, Miro1 is a key determinant of how energy supply is matched to energy usage in neurons.

124 Consequently, if the external energy supply is removed, the amplitude of oscillations

125 rates to neurons particularly when exogenous energy supply is restricted.

126 mitigating all emissions associated with UK energy supply is roughly double that of mitigating only

127 s to adapt to life under conditions of short energy supply is to use the by-product pyrophosphate to

128 enced by several factors, including maternal energy supply, maternal stature, disease status, smoking

129 Our results suggest that energy supply may be a limiting factor for the benefit o

130 lls, suggesting that deprivation of cellular energy supply may be an effective way to overcome multid

131 lusion, a HIF-mediated shift toward improved energy supply may protect against acute tubular injury i

132 our results imply that a diminished cerebral energy supply may underlie the decline in brain areas as

133 ed generation of these forces may require an energy supply mediated by the guanidino kinases, creatin

134 l recovery (biogenesis) that may restore the energy supply needed to fuel restorative metabolic proce

135 ting that energy needs for recovery exceeded energy supply of compromised blood flow.

136 to guarantee a flexible, stable, and secure energy supply operation.

137 This allows the assessment of novel energy supply options, but is insufficient for understan

138 ontribute to alterations in cell signalling, energy supply or the onset of proliferation.

139 advantageous under conditions of diminished energy supply, or of reduced temperature, turning faster

140 on the metabolic state of the cell, yet the energy-supply pathways to the nuclear compartment are un

141 lectricity would become the dominant form of energy supply, posing challenges and opportunities for e

142 M 2-deoxyglucose in the absence of exogenous energy supply produced widespread cell death throughout

143 However, there are energy supply-related differences between vertebrates in

144 analytical elements: scenario projection of energy supply systems, temporally explicit life cycle mo

145 ion models based on a variety of alternative energy supply technologies are considered the best way t

146 e present a simple, new model for evaluating energy-supply technologies and their improvement traject

147 nthetic active matter have access to a local energy supply that serves to keep the system out of ther

148 te change without adversely affecting global energy supply, there is growing interest in the possibil

149 ng archaea, which thrive at a constantly low energy supply, thus offering a biochemical explanation f

150 very efficient spraying and the low internal energy supplied to the ions.

151 on and cell-cycle progression, thus allowing energy supply to be matched by energy demands.

152 xcitation energy transfer (EET) to fit light energy supply to biochemical demands.

153 pathways to increase ATP synthesis, matching energy supply to demand.

154 erosis and indicate that manipulation of the energy supply to motoneurons as well as inhibition of p7

155 of cerebral blood flow to adequately couple energy supply to neural function.

156 Interruption of energy supply to peripheral axons is a cause of axon los

157 nergy use, and explain how disruption of the energy supply to synapses leads to neuropathology.

158 and neuronal proteins necessary for optimal energy supply to the brain and for the reuptake and recy

159 f intracellular calcium homeostasis, loss of energy supply to the cell, increased activity of oxidisi

160 ries, which may partly be due to a decreased energy supply to the heart resulting from low fatty acid

161 change, global warming, urban air pollution, energy supply uncertainty and depletion, and rising cost

162 embles communities within the constraints of energy supply via regional exchange of species that diff

163 f the body and thereby fosters intracellular energy supply, we hypothesized that intranasal insulin r

164 x Ca(2+) plays an important role in matching energy supply with demand in cardiac myocytes.

165 network of reactions is involved in matching energy supply with demand in the heart.

166 Precise matching of energy supply with demand requires delicately balanced c

167 mass would help to significantly decarbonize energy supply with regionally sourced feedstock, while a