Reflex control of the vasculature in healthy humans, type 2 diabetic subjects and cardiac transplant recipients

Weisbrod, Cara Jane

January 2004

[Truncated abstract] Cardiovascular reflex control of the vasculature is important in maintaining adequate tissue oxygenation in the face of disturbances in physiological homeostasis. Alterations in blood oxygen levels and blood distribution evoke integrated neural, mechanical and humoral responses which modulate peripheral vasomotor tone to maintain systemic cardiovascular integrity. The balance between the local effects of hypoxia and changes in chemoreflex control of vascular tone during hypoxia determine whether net vasoconstriction or vasodilatation is evident in the peripheral vasculature. The mechanisms contributing to hypoxic vasodilatation per se have not previously been defined in healthy humans. Study 1 of this thesis (Chapter 3) investigated the mechanisms contributing to vasomotor responses to chemoreflex activation in the human forearm ... Study 2 (Chapter 4a) investigated the mechanisms controlling vasomotor responses to isocapnic hypoxia in subjects with type 2 diabetes ... Study 3 (Chapter 5) compared the vascular responses to decreased venous return in individuals with and without right atrial afferent innervation ... The results of this thesis indicate that in healthy humans isocapnic hypoxia induces sympathetic vasoconstriction, which masks underlying β-adrenoceptor mediated vasodilatation. The normal vasomotor response to isocapnic hypoxia is impaired in subjects with type 2 diabetes. Despite intact vasoconstrictor responses, subjects with type 2 diabetes exhibited attenuated adrenaline-mediated vasodilatation compared to healthy control subjects, suggesting that the chemoreflex in these subjects is ill-equipped to respond to hypoxic stress. In clinical terms, impaired reflex vasomotor

Cardiovascular system -- Physiology

Vasomotor system -- Physiology

Diabetic angiopathies

Anoxemia

Baroreflexes

Phenotypically different cells in the nucleus of the solitary tract expression of group I metabotropic glutamate receptors and activation by baroreflexes /

Austgen, James R.

January 2008

Thesis (Ph. D.)--University of Missouri-Columbia, 2008. / The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Vita. "June 2008" Includes bibliographical references.

Régulations cardiovasculaires au repos et à l’exercice chez l’Homme : nouvelles perspectives de la variabilité de fréquence cardiaque et de la sensibilité du baroréflexe en boucle ouverte / Human cardiovascular regulations at rest and during exercise : new insights from heart rate variability and open loop baroreflex sensitivity

Fontolliet, Thimothée

12 June 2017

Le système nerveux autonome (SNA) contribue de façon importante aux régulations des fonctions cardiovasculaires. Pendant des décennies, les chercheurs ont essayé de comprendre comment la variabilité de la fréquence cardiaque (VFC) et le gain du baroréflexe cardiaque pouvaient être utilisés comme marqueurs significatifs du contrôle neurovégétatif cardiaque, et parfois de son altération. L'objectif général de cette thèse est de mieux comprendre le rôle du SNA dans la modulation et les adaptations des fonctions cardiaques et vasculaires. Le projet comprenait quatre études.Dans la première étude, nous avons analysé les effets de l'accélération gravitationnelle graduées sur la régulation neurovégétative de la fréquence cardiaque et de la vasomotricité artériolaire. Dans ces expositions expérimentales des variables cardiovasculaires et respiratoires ont été modifiées de façon spécifique. Nos résultats ne sont pas compatibles avec la mise en jeu d’une régulation sympathique au niveau cardiaque en situation d’hypergravité brève. Nous avons supposé que seule la branche sympathique du SNA était active durant une exposition à une accélération de gravité élevée. La réponse adaptative de la vasomotricité artérielle vasculaire est observée en condition de grande décharge des barorécepteurs. Notre deuxième travail eu pour objet l'effet de la dénervation pulmonaire sur la VFC, et a donc été conduit chez des patients ayant subi une greffe pulmonaire complète. Le greffon n'étant plus relié au SNA, il s'agit d'un excellent modèle expérimental pour l'étude de la régulation cardiovasculaire en l’absence de modulation de l'activité cardiaque par des afférences nerveuses pulmonaires parasympathiques et/ou sympathiques. Puisque la VFC dans les hautes fréquences est reconnue comme largement déterminée par le profil ventilatoire, on s’attend à ce que la composante à haute fréquence de la VFC soit absente chez les sujets transplantés bi-pulmonaires. Les résultats montrent que cette dénervation pulmonaire implique une forte réduction de la VFC totale et dans les deux bandes de fréquence étudiées, hautes et basses. Cela indique donc qu’une large contribution de la modulation nerveuse de la VFC répond aux afférences pulmonaires. La sensibilité du baroréflexe est réduite. Le rapport plus élevé entre les basses et les hautes fréquences traduit une réduction de puissance totale principalement due à la diminution de la composante haute fréquence. Ces résultats montrent que les afférences pulmonaires contribuent largement à la à la modulation neurovégétative de la composante à hautes fréquences de la VFC. La variabilité de la pression artérielle est beaucoup moins modifiée que celle de la VFC par la transplantation bipulmonaire, ce qui met en évidence que les afférences pulmonaires contribuent spécifiquement à la modulation de la VFC. Cette observation est un argument fort pour reconnaître des voies de régulation différentes pour les variabilités de fréquence cardiaque d’une part et de pression artérielle d’autre part. Le troisième article traite des effets sur la modulation cardiovasculaire de blocages pharmacologiques du SNA sur les régulations de fréquence cardiaque et de vasomotricité périphérique, au repos et pendant l'exercice. / Autonomic nervous system (ANS) and cardiovascular regulation are closely linked. For decades, researches have tried to understand how heart rate variability (HRV) and baroreflexes can be used as significant markers of the autonomic nervous control, and sometimes of its impairments. The general aim of this thesis is to gain further insights into the role of ANS in modulating cardiac and vascular functions. The project consisted of four studies.In the first study, we analysed the effects of gravitational acceleration on cardiovascular autonomic control. This special condition showed interesting results for cardiorespiratory variables. Our results did not agree with the notion of sympathetic up-regulation in hypergravity. We speculated that only the sympathetic branch of the ANS might have been active during elevated gravitational acceleration exposure. Furthermore, the vascular response occurred in a condition of massive baroreceptor unloading.Our second work targeted the effect of lung denervation on HRV in bilateral lung transplant recipients. As the graft is no longer connected to the ANS, this is an excellent experimental model for the study of cardiovascular regulation without modulation of heart activity by parasympathetic and/or sympathetic lung afferents. The hypothesis was that the modulation of the high frequency component of HRV by the breathing frequency is mediated by the ANS. This hypothesis would be supported by the results if the high frequency component of HRV is suppressed in bilateral lung transplant recipients. Lung denervation implied strong HRV reduction, all indices being decreased, indicating that neural modulation from lung afferents contributes largely to HRV. Baroreflex sensitivity was reduced. The higher low-versus-high frequency ratio implied that the total power drop was mostly due to the high frequency component, indicating that neural modulation from lung afferents largely contributes to the high frequency component of HRV. The changes in blood pressure variability were smaller than those in HRV, suggesting that the effects of lung denervation were specific to HRV modulation. This finding confirms that blood pressure variability and HRV are under different control mechanisms.The third article concerns the effects of autonomic blockades on cardiovascular modulation, at rest and during exercise. We hypothesized that HRV should decrease with vagal or sympathetic blockades, and disappear during simultaneous blockade of both ANS branches. The results suggest that the parasympathetic outflow to the heart is the main determinant of HRV, while the role of the sympathetic branch is less important. Indeed, sympathetic blockades failed in changing HRV indices at rest, indicating that a selective blockade of cardiac ß-adrenergic receptors has no effects on spontaneous heart rate oscillations. These effects are specific to HRV, as the effects observed on blood pressure variability are indirectly related to the action of the administered drugs. The changes in baroreflex sensitivity were consistent with the changes in arterial blood pressure variability, suggesting that baroreflexes may modulate the LF power of arterial blood pressure.

Système nerveux autonome

Variabilité de fréquence cardiaque

Baroréflexe

Régulations cardiovasculaires

Pression artérielle

Hypergravité

Transplanté pulmonaire

Autonomic nervous system

Heart rate variability

Baroreflexes

Cardiovascular regulation

Blood pressure

Hypergravity

Pulmonary transplant

Functional contributions of a sex-specific population of myelinated aortic baroreceptors in rat and their changes following ovariectomy

Santa Cruz Chavez, Grace C.

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Gender differences in the basal function of autonomic cardiovascular control are well documented. Consistent baroreflex (BRx) studies suggest that women have higher tonic parasympathetic cardiac activation compared to men. Later in life and concomitant with menopause, a significant reduction in the capacity of the BRx in females increases their risk to develop hypertension, even exceeding that of age-matched males. Loss of sex hormones is but one factor. In female rats, we previously identified a distinct myelinated baroreceptor (BR) neuronal phenotype termed Ah-type, which exhibits functional dynamics and ionic currents that are a mix of those observed in barosensory afferents functionally identified as myelinated A-type or unmyelinated C-type. Interestingly, Ah-type afferents constitute nearly 50% of the total population of myelinated aortic BR in female but less than 2% in male rat. We hypothesized that an afferent basis for sexual dimorphism in BRx function exists. Specifically, we investigated the potential functional impact Ah-type afferents have upon the aortic BRx and what changes, if any, loss of sex hormones through ovariectomy brings upon such functions. We assessed electrophysiological and reflexogenic differences associated with the left aortic depressor nerve (ADN) from adult male, female, and ovariectomized female (OVX) Sprague-Dawley rats. Our results revealed sexually dimorphic conduction velocity (CV) profiles. A distinct, slower myelinated fiber volley was apparent in compound action potential (CAP) recordings from female aortic BR fibers, with an amplitude and CV not observed in males. Subsequent BRx studies demonstrated that females exhibited significantly greater BRx responses compared to males at myelinated-specific intensities. Ovariectomy induced an increased overall temporal dispersion in the CAP of OVX females that may have contributed to their attenuated BRx responses. Interestingly, the most significant changes in depressor dynamics occurred at electrical thresholds and frequencies most closely aligned with Ah-type BR fibers. Collectively, we provide evidence that, in females, two anatomically distinct myelinated afferent pathways contribute to the integrated BRx function, whereas in males only one exists. These functional differences may partly account for the enhanced control of blood pressure in females. Furthermore, Ah-type afferents may provide a neuromodulatory pathway uniquely associated with the hormonal regulation of BRx function.

Baroreceptor

Baroreflex

Nerve electrophysiology

Ovariectomy

Sex differences

Cardiovascular

Electrophysiology -- Technique

Neurophysiology -- Research

Baroreceptors -- Research -- Evaluation

Baroreflexes -- Research -- Evaluation

Ovariectomy -- Research

Medicine -- Research -- Sex differences

Hypertension -- Women

Neural conduction -- Measurement

Cardiography

Hormones, Sex

Menopause

Cardiovascular system -- Innervation