BasaranKE, VillongcoM, HoB, EllisE, ZarndtR, AntonovJ, HopkinsSR, and PowellFL. (2016). Ibuprofen blunts ventilatory acclimatization to sustained hypoxia in humans. PLoS One, 11:e0146087.
3.
ChanCW, LinYC, ChiuYH, WengYM, LiWC, LinYJ, WangSH, HsuTY, HuangKF, and ChiuTF. (2016). Incidence and risk factors associated with acute mountain sickness in children trekking on Jade Mountain, Taiwan. J Travel Med, 2016; 23:10.
4.
ChangAJ, OrtegeaFE, RieglerJ, MadisonDV, and KrasnowMA. (2015). Oxygen regulation of breathing through an olfactory receptor activated by lactate. Nature, 527:240–244.
5.
DiPasqualeDM, StrangmanGE, HarrisNS, and MuzaSR. (2015). Hypoxia, hypobaria, and exercise duration affect acute mountain sickness. Aerosp Med Hum Perform, 86:614–619.
6.
HoffmannA, KunzeR, HelluyX, MilfordD, HeilandS, BendszusM, PhamM, and MartiHH. (2016). High-field MRI reveals a drastic increase of hypoxia-induced microhemorrhages upon tissue reoxygenation in the mouse brain with strong predominance in the olfactory bulb. PLoS One, 11:e0148441.
7.
LiaoWT, LiuB, ChenJ, CuiJH, GaoYX, LiuFY, XuG, SunBD, ZhangEL, YuanZB, et al. (2016). Metabolite modulation in human plasma in the early phase of acclimatization to hypobaric hypoxia. Sci Rep, 6:22589.
8.
LlapurCJ, MarinezMR, GrassinoPT, StokA, AltieriHH, BonillaF, CaramMM, KrowchukNM, KirbyM, CoxsonHO, and TepperRS. (2016). Chronic hypoxia accentuates dysanaptic lung growth. Am J Respir Crit Care Med (In Press).
9.
MahmoudAD, LewisS, JuricicL, UdohUA, hartmannS, JansenMA, OgunbayoOA, PuggioniP, HolmesAP, KumarP, Navarro-DoradoJ, ForetzM, ViolletB, DutiaMB, MarshallI, and EvansAM. (2016). AMPK deficiency blocks the hypoxic ventilatory response and thus precipitates hypoventilation and apnea. Am J Respir Crit Care Med, 193:1032–1043.
10.
NagaiH, KuwahiraI, SchwenkeDO, TsuchimochiiH, NaraA, OguraS, SonobeT, InagakiT, FujiiY, YamaguchiR, WingenfeldL, UmetaniK, ShimosawaT, YoshidaK, UemuraK, PearsonJT, and ShiraiM. (2015). Pulmonary macrophages attenuate hypoxic pulmonary vasoconstriction via beta-3AR/iNOS pathway in rats exposed to chronic intermittent hypoxia. PLoS One, 10:e0131923.
11.
RibonA, PialouxV, SaugyJJ, RuppT, FaissR, DebevecT, and MilletGP. (2016). Exposure to hypobaric hypoxia results in higher oxidative stress compared to normobaric hypoxia. Respir Physiol Neurobiol, 223:23–27.
12.
RoubikK, SiegerL, and SykoraK. (2015). Work of breathing into snow in the presence versus absence of an artificial air pocket affects hypoxia and hypercapnia of a victim covered with avalanche snow: a randomized double blind controlled study. PLoS One, 10:e0144332.
13.
SagooRS, HutchinsonCE, WrightA, HandfordC, ParsonsH, SherwoodV, WayteS, NagarajaS, Ng'AndweE, WilsonMH, et al. (2016). Magnetic Resonance investigation into the mechanisms involved in the development of high-altitude cerebral edema. J Cereb Blood Flow Metab (In Press).
14.
SaugyJJ, RuppT, FaissR, LamonA, BourdillonN, and MilletGP. (2016). Cycling time trial is more altered in hypobaric than normobaric hypoxia. Med Sci Sports Exerc, 48:680–688.
15.
SheaKM, LaddER, LipmanGS, BagleyP, PirrottaEA, VongsachangH, WangNE, and AuerbachPS. (2016). The 6-minute walk test as a predictor of summit success on Denali. Wilderness Environ Med, 27:19–24.
16.
SinghDP, NimkerC, PaliwalP, and BansalA. (2015). Ethyl 3,4-dihydroxybenzoate (EDHB): a prolyl hydroxylase inhibitor attenuates acute hypobaric hypoxia mediated vascular leakage in brain. J Physiol Sci (In Press).
17.
TalbotNP, SmithTG, Lakhal-LittletonS, GulseverC, Rivera-ChM, DorringtonKL, MoleDR, and RobbinsPA. (2016). Suppression of plasma hepcidin by venesection during steady state hypoxia. Blood, 127:1206–1207.
18.
TaylorBJ, CoffmanKE, SummerfeldDT, IssaAN, KasakAJ, and JohnsonBD. (2016). Pulmonary capillary reserve and exercise capacity at high altitude in healthy humans. Eur J Appl Physiol, 116:427–437.
