Autonomic neural control of cerebral hemodynamics

Mitsis, Georgios D.; Zhang, Rong; Levine, Benjamin D.; Tzanalaridou, Efthalia; Katritsis, D.; Marmarelis, Vasilis Z.

doi:10.1109/memb.2009.934908

Cited by 41 publications

(43 citation statements)

References 28 publications

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“…It must be appreciated that factors other than arterial blood gas tensions are known to modulate the effectiveness of dCA, these include: (i) sympathetic activity; (ii) metabolite production; and (iii) perivascular innervation [35][36][37][38][39][40]. Our data do not allow us to comment on the role that these factors played in disrupting autoregulatory processes during maximal apnoea.…”

Section: Discussionmentioning

confidence: 70%

Dynamic Cerebral Autoregulation Is Acutely Impaired During Maximal Apnoea In Trained Divers

Cross¹,

Kavanagh²,

Brešković³

et al. 2014

Medicine & Science in Sports & Exercise

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Aims: To examine whether dynamic cerebral autoregulation is acutely impaired during maximal voluntary apnoea in trained divers.Methods: Mean arterial pressure (MAP), cerebral blood flow-velocity (CBFV) and end-tidal partial pressures of O 2 and CO 2 (PETO 2 and PETCO 2 ) were measured in eleven trained, male apnoea divers (2862 yr; 18262 cm, 7667 kg) during maximal ''dry'' breath holding. Dynamic cerebral autoregulation was assessed by determining the strength of phase synchronisation between MAP and CBFV during maximal apnoea.Results: The strength of phase synchronisation between MAP and CBFV increased from rest until the end of maximal voluntary apnoea (P,0.05), suggesting that dynamic cerebral autoregulation had weakened by the apnoea breakpoint. The magnitude of impairment in dynamic cerebral autoregulation was strongly, and positively related to the rise in PETCO 2 observed during maximal breath holding (R 2 = 0.67, P,0.05). Interestingly, the impairment in dynamic cerebral autoregulation was not related to the fall in PETO 2 induced by apnoea (R 2 = 0.01, P = 0.75).Conclusions: This study is the first to report that dynamic cerebral autoregulation is acutely impaired in trained divers performing maximal voluntary apnoea. Furthermore, our data suggest that the impaired autoregulatory response is related to the change in PETCO 2 , but not PETO 2 , during maximal apnoea in trained divers.

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Section: Discussionmentioning

confidence: 70%

Dynamic Cerebral Autoregulation Is Acutely Impaired During Maximal Apnoea In Trained Divers

Cross¹,

Kavanagh²,

Brešković³

et al. 2014

Medicine & Science in Sports & Exercise

View full text Add to dashboard Cite

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“…These models include implicitly the effects of the myogenic mechanism [21], [22], flow-mediated endothelial mechanisms [23] and perivascular innervation [24]–[26] without yet being able to draw a direct correspondence between physiological mechanisms and specific model characteristics. Such input-output models often incorporate end-tidal CO2 measurements to account for the known effects of blood CO2 tension on this physiological process, especially in the low-frequency range from 0.02 to 0.08 Hz [8], [10], [12], [27]–[31]. Previous studies have shown that the characteristics of CFA and CVR are altered by orthostatic stress, hypertension, hypoxia, hypercapnia, head injury, stroke, early Alzheimer’s disease and pharmaceutical interventions that affect the autonomic nervous system or vascular tone [11], [12], [28], [32]–[38].…”

Section: Introductionmentioning

confidence: 99%

“…Such input-output models often incorporate end-tidal CO2 measurements to account for the known effects of blood CO2 tension on this physiological process, especially in the low-frequency range from 0.02 to 0.08 Hz [8], [10], [12], [27]–[31]. Previous studies have shown that the characteristics of CFA and CVR are altered by orthostatic stress, hypertension, hypoxia, hypercapnia, head injury, stroke, early Alzheimer’s disease and pharmaceutical interventions that affect the autonomic nervous system or vascular tone [11], [12], [28], [32]–[38]. Some of the recent findings were made possible by Volterra-type nonlinear modeling with two inputs (arterial blood pressure and end-tidal CO2) [10]–[12].…”

Section: Introductionmentioning

confidence: 99%

Time-Varying Modeling of Cerebral Hemodynamics

Marmarelis

Shin

Orme

et al. 2014

IEEE Trans. Biomed. Eng.

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The scientific and clinical importance of cerebral hemodynamics has generated considerable interest in their quantitative understanding via computational modeling. In particular, two aspects of cerebral hemodynamics, Cerebral Flow Autoregulation (CFA) and CO2 Vasomotor Reactivity (CVR), have attracted much attention because they are implicated in many important clinical conditions and pathologies (orthostatic intolerance, syncope, hypertension, stroke, vascular dementia, MCI, Alzheimer’s disease and other neurodegenerative diseases with cerebrovascular components). Both CFA and CVR are dynamic physiological processes by which cerebral blood flow is regulated in response to fluctuations in cerebral perfusion pressure and blood CO2 tension. Several modeling studies to date have analyzed beat-to-beat hemodynamic data in order to advance our quantitative understanding of CFA-CVR dynamics. A confounding factor in these studies is the fact that the dynamics of the CFA-CVR processes appear to vary with time (i.e. changes in cerebrovascular characteristics) due to neural, endocrine and metabolic effects. This paper seeks to address this issue by tracking the changes in linear time-invariant models obtained from short successive segments of data from 10 healthy human subjects. The results suggest that systemic variations exist but have stationary statistics and, therefore, the use of time-invariant modeling yields “time-averaged models” of physiological and clinical utility.

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“…Состо-яние мозгового кровотока модулируется не только церебральной ауторегуляцией, но и вегетативной нервной системой и артериальным барорефлектор-но-опосредованным контролем в большом круге кровообращения [41]. В ответ на симпатическую ак-тивацию наблюдается вазоконстрикция [42,43]. Це-ребральные механизмы ауторегуляции способны компенсировать потребление кислорода [44], одна-ко повторные эпизоды гипоперфузии приводят к истощению компенсаторных возможностей.…”

Section: патогенез ог при дтлunclassified

Orthostatic hypotension in dementia with Lewy bodies

Чимагомедова¹,

Левин²

2016

Z. nevrol. psikhiatr. im. S.S. Korsakova

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ГБОУ ДПО «Российская медицинская академия последипломного образования», Москва, Россия В обзоре рассматриваются особенности проявления ортостатической гипотензии при деменции с тельцами Леви и методы ее диагностики. Ранняя диагностика данных нарушений позволит предотвратить такие нежелательные последствия, как падения и обмороки, улучшить повседневную деятельность и повысить качество жизни пациентов. анализируются современные подходы к коррекции данного состояния. The features of orthostatic hypotension in patients with dementia with Lewy bodies are considered. The early diagnosis of these disorders could prevent adverse conditions (falls and syncopes), improve activities of daily living and quality-of-life. Current approaches to treatment of orthostatic hypotension are analyzed.

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Autonomic neural control of cerebral hemodynamics

Cited by 41 publications

References 28 publications

Dynamic Cerebral Autoregulation Is Acutely Impaired During Maximal Apnoea In Trained Divers

Dynamic Cerebral Autoregulation Is Acutely Impaired During Maximal Apnoea In Trained Divers

Time-Varying Modeling of Cerebral Hemodynamics

Orthostatic hypotension in dementia with Lewy bodies

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