178 related articles for article (PubMed ID: 31090115)
1. Responses of cerebral blood velocity and tissue oxygenation to low-frequency oscillations during simulated haemorrhagic stress in humans.
Anderson GK; Sprick JD; Park FS; Rosenberg AJ; Rickards CA
Exp Physiol; 2019 Aug; 104(8):1190-1201. PubMed ID: 31090115
[TBL] [Abstract][Full Text] [Related]
2. Coupling between arterial pressure, cerebral blood velocity, and cerebral tissue oxygenation with spontaneous and forced oscillations.
Rickards CA; Sprick JD; Colby HB; Kay VL; Tzeng YC
Physiol Meas; 2015 Apr; 36(4):785-801. PubMed ID: 25798890
[TBL] [Abstract][Full Text] [Related]
3. The effect of oscillatory hemodynamics on the cardiovascular responses to simulated hemorrhage during isocapnia.
Anderson GK; Davis KA; Bhuiyan N; Rusy R; Rosenberg AJ; Rickards CA
J Appl Physiol (1985); 2023 Dec; 135(6):1312-1322. PubMed ID: 37881852
[TBL] [Abstract][Full Text] [Related]
4. Peaks and valleys: oscillatory cerebral blood flow at high altitude protects cerebral tissue oxygenation.
Anderson GK; Rosenberg AJ; Barnes HJ; Bird J; Pentz B; Byman BRM; Jendzjowsky N; Wilson RJA; Day TA; Rickards CA
Physiol Meas; 2021 Jun; 42(6):. PubMed ID: 34038879
[No Abstract] [Full Text] [Related]
5. Tolerance to central hypovolemia: the influence of oscillations in arterial pressure and cerebral blood velocity.
Rickards CA; Ryan KL; Cooke WH; Convertino VA
J Appl Physiol (1985); 2011 Oct; 111(4):1048-58. PubMed ID: 21799129
[TBL] [Abstract][Full Text] [Related]
6. Changes in cerebral oxygen saturation and cerebral blood flow velocity under mild +Gz hypergravity.
Konishi T; Kurazumi T; Kato T; Takko C; Ogawa Y; Iwasaki KI
J Appl Physiol (1985); 2019 Jul; 127(1):190-197. PubMed ID: 31169473
[TBL] [Abstract][Full Text] [Related]
7. Cerebral blood velocity regulation during progressive blood loss compared with lower body negative pressure in humans.
Rickards CA; Johnson BD; Harvey RE; Convertino VA; Joyner MJ; Barnes JN
J Appl Physiol (1985); 2015 Sep; 119(6):677-85. PubMed ID: 26139213
[TBL] [Abstract][Full Text] [Related]
8. Slow breathing as a means to improve orthostatic tolerance: a randomized sham-controlled trial.
Lucas SJ; Lewis NC; Sikken EL; Thomas KN; Ainslie PN
J Appl Physiol (1985); 2013 Jul; 115(2):202-11. PubMed ID: 23681913
[TBL] [Abstract][Full Text] [Related]
9. Cerebral oxygenation and regional cerebral perfusion responses with resistance breathing during central hypovolemia.
Kay VL; Sprick JD; Rickards CA
Am J Physiol Regul Integr Comp Physiol; 2017 Aug; 313(2):R132-R139. PubMed ID: 28539354
[TBL] [Abstract][Full Text] [Related]
10. Haemodynamic and cerebrovascular effects of intermittent lower-leg compression as countermeasure to orthostatic stress.
Gibbons TD; Zuj KA; Prince CN; Kingston DC; Peterson SD; Hughson RL
Exp Physiol; 2019 Dec; 104(12):1790-1800. PubMed ID: 31578774
[TBL] [Abstract][Full Text] [Related]
11. Oscillatory lower body negative pressure impairs task related functional hyperemia in healthy volunteers.
Stewart JM; Balakrishnan K; Visintainer P; Del Pozzi AT; Messer ZR; Terilli C; Medow MS
Am J Physiol Heart Circ Physiol; 2016 Mar; 310(6):H775-84. PubMed ID: 26801310
[TBL] [Abstract][Full Text] [Related]
12. The role of cerebral oxygenation and regional cerebral blood flow on tolerance to central hypovolemia.
Kay VL; Rickards CA
Am J Physiol Regul Integr Comp Physiol; 2016 Feb; 310(4):R375-83. PubMed ID: 26676249
[TBL] [Abstract][Full Text] [Related]
13. Cerebral autoregulation is compromised during simulated fluctuations in gravitational stress.
Brown CM; Dütsch M; Ohring S; Neundörfer B; Hilz MJ
Eur J Appl Physiol; 2004 Mar; 91(2-3):279-86. PubMed ID: 14574578
[TBL] [Abstract][Full Text] [Related]
14. Oscillatory lower body negative pressure impairs working memory task-related functional hyperemia in healthy volunteers.
Merchant S; Medow MS; Visintainer P; Terilli C; Stewart JM
Am J Physiol Heart Circ Physiol; 2017 Apr; 312(4):H672-H680. PubMed ID: 28159806
[TBL] [Abstract][Full Text] [Related]
15. Methodological comparison of active- and passive-driven oscillations in blood pressure; implications for the assessment of cerebral pressure-flow relationships.
Smirl JD; Hoffman K; Tzeng YC; Hansen A; Ainslie PN
J Appl Physiol (1985); 2015 Sep; 119(5):487-501. PubMed ID: 26183476
[TBL] [Abstract][Full Text] [Related]
16. Ultrasound tagged near infrared spectroscopy does not detect hyperventilation-induced reduction in cerebral blood flow.
Lund A; Secher NH; Hirasawa A; Ogoh S; Hashimoto T; Schytz HW; Ashina M; Sørensen H
Scand J Clin Lab Invest; 2016; 76(1):82-7. PubMed ID: 26503121
[TBL] [Abstract][Full Text] [Related]
17. Acute volume expansion attenuates hyperthermia-induced reductions in cerebral perfusion during simulated hemorrhage.
Schlader ZJ; Seifert T; Wilson TE; Bundgaard-Nielsen M; Secher NH; Crandall CG
J Appl Physiol (1985); 2013 Jun; 114(12):1730-5. PubMed ID: 23580601
[TBL] [Abstract][Full Text] [Related]
18. Positive expiratory pressure improves arterial and cerebral oxygenation in acute normobaric and hypobaric hypoxia.
Rupp T; Saugy JJ; Bourdillon N; Verges S; Millet GP
Am J Physiol Regul Integr Comp Physiol; 2019 Nov; 317(5):R754-R762. PubMed ID: 31530174
[TBL] [Abstract][Full Text] [Related]
19. Cerebral autoregulation index at high altitude assessed by thigh-cuff and transfer function analysis techniques.
Subudhi AW; Grajzel K; Langolf RJ; Roach RC; Panerai RB; Davis JE
Exp Physiol; 2015 Feb; 100(2):173-81. PubMed ID: 25480158
[TBL] [Abstract][Full Text] [Related]
20. Cerebrovascular regulation is not blunted during mental stress.
Shoemaker LN; Wilson LC; Lucas SJE; Machado L; Cotter JD
Exp Physiol; 2019 Nov; 104(11):1678-1687. PubMed ID: 31465595
[TBL] [Abstract][Full Text] [Related]
[Next] [New Search]
