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The Response of Macrophages and Neutrophils to Hypoxia in the Context of Cancer and Other Inflammatory DiseasesHypoxia Induced NF-κBSubcellular Energetics and Metabolism: A Cross-Species Framework.Subcellular Energetics and Metabolism: Potential Therapeutic Applications.Is plasticity within the retrotrapezoid nucleus responsible for the recovery of the PCO2 set-point after carotid body denervation in rats?Modulation of sensory information processing by a neuroglobin in Caenorhabditis elegans.HIF2α Is an Essential Molecular Brake for Postprandial Hepatic Glucagon Response Independent of Insulin Signaling.Hypoxia: from basic mechanisms to therapeutics - a meeting report on the Keystone and HypoxiaNet Symposium.Hypoxia Induced Myocardial Regeneration.Intracranial mechanisms for preserving brain blood flow in health and disease.Carotid body chemoreflex: a driver of autonomic abnormalities in sleep apnoea.The impact of inflammation on respiratory plasticity.Systems biology of oxygen homeostasis.Maintenance of redox homeostasis by hypoxia-inducible factors.KDM2 Family Members are Regulated by HIF-1 in HypoxiaPhysiology in Perspective: The Air We Breathe: Providing O2 for Survival.Interdependent feedback regulation of breathing by the carotid bodies and the retrotrapezoid nucleus.Tet1 facilitates hypoxia tolerance by stabilizing the HIF-α proteins independent of its methylcytosine dioxygenase activity.The effect of within-instar development on tracheal diameter and hypoxia-inducible factors α and β in the tobacco hornworm, Manduca sexta.Endurance training attenuates the increase in peripheral chemoreflex sensitivity with intermittent hypoxia.Prolyl-4-hydroxylase 2 and 3 coregulate murine erythropoietin in brain pericytes.The PHD1 oxygen sensor in health and disease.Physioxia: a more effective approach for culturing human adipose-derived stem cells for cell transplantation.Trichostatin a Protects Dendritic Cells Against Oxygen-Glucose Deprivation via the SRSF3/PKM2/Glycolytic Pathway.Paper-based Invasion Assays for Quantifying Cellular Movement in Three-dimensional Tissue-like Structures
P2860
Q26749138-28D95004-6A7D-49B3-8128-92DAD33C6E90Q26752556-A3D6F0CC-5359-4FAF-9F78-DED9785A3800Q30252373-772FE745-001D-43E2-A9E4-FF8B7DBC94EFQ30253000-D32C6D17-64A3-4243-8717-11FD62B3AB22Q30277614-51FBBE00-54ED-4DD2-9D09-A3CF16065BF0Q33790893-394DF72B-E3F9-4353-9BDB-21495494D9A0Q36669733-87E60B93-4C2E-49FC-8214-7498E9E5618DQ37301120-58774C8F-57E3-4765-A265-E2A9D1EDDC79Q38640560-A7530300-63FA-448A-ACBA-57E18B6F1816Q38832964-8D702748-409E-4F25-8355-195E8D6FC39FQ38913121-F12819E3-9F7F-4720-9A32-5D779582D85DQ38913890-7A479DBB-DDA4-4C52-9C9B-0F51BAD49E7CQ39145122-056D3FEE-8643-4026-9309-31363275AAB3Q39380299-F84A0F45-237A-4AC6-81CF-025E0331E126Q42074689-830BA457-3D62-4886-BB15-0C196E0343B8Q43752873-F5FFD9D7-F930-4DD3-9C67-0CF826C4F114Q45073758-52D34FCC-F8F4-43AE-B340-9E54A5D09F7BQ46284307-A6BE83BF-3C7E-4A87-AEFF-EC2958AD819DQ47288079-8E6A4294-59F0-4FBC-B18C-BA6D9C382F25Q47779275-63CCEA73-B038-4EDB-A5FF-44522EA770A6Q48040213-27FE04F8-B27E-46A6-A76D-0725AB3557B0Q50050250-F3F92996-7FCC-40A8-8EA4-521BA87EEB27Q55110887-3F10F667-C387-4351-ADF2-0631E1C22865Q55411477-895F61F3-A2E6-4189-882E-233F0B1136B1Q58483807-5AFD9284-E0D7-41EC-BAE8-FAF9F101A2C2
P2860
description
2015 nî lūn-bûn
@nan
2015 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
2015 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
name
Oxygen Sensing and Homeostasis
@ast
Oxygen Sensing and Homeostasis
@en
Oxygen Sensing and Homeostasis
@nl
type
label
Oxygen Sensing and Homeostasis
@ast
Oxygen Sensing and Homeostasis
@en
Oxygen Sensing and Homeostasis
@nl
prefLabel
Oxygen Sensing and Homeostasis
@ast
Oxygen Sensing and Homeostasis
@en
Oxygen Sensing and Homeostasis
@nl
P2860
P1433
P1476
Oxygen Sensing and Homeostasis
@en
P2093
Nanduri R Prabhakar
P2860
P356
10.1152/PHYSIOL.00022.2015
P407
P577
2015-09-01T00:00:00Z