ライフサイエンスコーパス: oxygen response

1 retina, and how retinal diseases may affect oxygen response.

2 l powerfully attenuates heroin-induced brain oxygen responses.

3 d their combinations on brain and peripheral oxygen responses.

4 D enzymes are key regulators of hypoxia (low oxygen) response.

5 l data on the outcome impact of brain tissue oxygen response and asymmetric patterns of cerebral auto

6 The relationship between the negative oxygen response and neural activity is relatively consta

7 ies: cell proliferation, neural development, oxygen responses and muscle capacity.

8 ces in their mechanics, migration, adhesion, oxygen response, and proteomic profiles.

9 ution NO concentration, and effect on enzyme oxygen response (apparent KmO2).

10 involved in the very early activation of low-oxygen responses are insufficiently understood.

11 Secondary outcomes: oxygen-response, C o2 -response, ultrasonographic, and s

12 show that the negative but not the positive oxygen response changes in an approximately linear manne

13 Further analyses using low-oxygen response element (LORE)-CYC1-lacZ fusion reporter

14 hanism and P(III) is activated by a putative oxygen response element.

15 ctor could also explain a similar pattern of oxygen responses found in the substantia nigra reticulat

16 regulation is possible for its activity and oxygen response in biologic settings.

17 arousing stimuli and cocaine induced similar oxygen responses in the brain and SC space, heroin induc

18 cent studies show that a neural globin tunes oxygen responses in the nematode Caenorhabditis elegans.

19 is regulon capable of coordinating light and oxygen responses in the three major branches of the evol

20 w that the amplitude of the initial negative oxygen response increases with stimulus size but neural

21 to be peripherally restricted, affect brain oxygen responses induced by intravenous heroin at low, h

22 oupling between neural activity and negative oxygen responses is well described by a power law functi

23 ) protein plays a central role in the global oxygen response of a variety of bacteria.

24 Comparison of the low oxygen response of tissues characterized by different le

25 tion represents a mechanism by which the low oxygen response pathway has assimilated complex new func

26 oNOQP in R. capsulatus is not flanked by the oxygen response regulator fnr, which is located upstream

27 Moreover, both negative and positive oxygen responses saturate at high stimulus contrast leve

28 To recognize low-oxygen responses that are evolutionarily conserved versu

29 ity of the degree of hypoxemia, the arterial oxygen response to 100% oxygen administration, and the m

30 nit extracellular neural activity and tissue oxygen responses to visual stimuli of various durations