Involvement of median preoptic nucleus and medullary noradrenergic neurons in cardiovascular and sympathetic responses of hemorrhagic rats

Naves, Lara Marques; Marques, Stefanne M.; Mourão, Aline A.; Fajemiroye, James Oluwagbamigbe; Xavier, Carlos Henrique; Castro, Carlos H.; Rebelo, Ana Cristina Silva; Rosa, Daniel Alves; Gomes, Rodrigo Mello; Colombari, Eduardo; Pedrino, Gustavo Rodrigues

doi:10.1038/s41598-018-29310-z

Cited by 3 publications

(1 citation statement)

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“…Hemorrhage (HEM) is a life-threatening incident due to the loss of intravascular volume caused by hypotension with two compensatory and non-compensatory phases ( Evans, Ventura, Dampney, & Ludbrook, 2001 ; Standl, Annecke, Cascorbi, Heller, Sabashnikov, & Teske, 2018 ). The compensatory phase is performed by the elicit of baroreceptors signaling hypotension to the Nucleus of the Solitary Tract (NTS) followed by the activation of vasomotor neurons in Rostral Ventrolateral Medulla (RVLM), an important area in cardiovascular modulation, that excites the sympathetic neurons and maintains blood pressure in normal condition ( Naves et al, 2018 ; Palkovits, 1999 ). If blood loss continues, the non-compensatory phase, as the next phase, is started, in which sympathetic drive abruptly reduces and arterial pressure falls.…”

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confidence: 99%

Cardiovascular Effect of Cuneiform Nucleus During Hemorrhagic Hypotension

Mohebbati

Hosseini

Khazaei

et al. 2020

Basic Clin. Neurosci. J.

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The underlying mechanism responsible for the cardiovascular response to Hemorrhage (HEM) is still unknown; however, several brain areas, such as the Cuneiform nucleus (CnF) have shown to be involved. In this study, the cardiovascular effect of the CnF during HEM was evaluated. Methods: The animals were divided into the following groups: 1. Vehicle; 2. HEM; 3. Cobalt chloride (CoCl 2); 4. CoCl 2 +saline; and 5. CoCl 2 +HEM. Catheterization of the left and right femoral artery was performed to record blood pressure and blood withdrawal, respectively. Saline and CoCl 2 were microinjected into the CnF nucleus, and then blood withdrawal was done for HEM induction. Cardiovascular regulation throughout the experiments was recorded and changes (∆) in the Systolic Blood Pressure (SBP), Mean Arterial Pressure (MAP) and Heart Rate (HR) were calculated over time and compared with those treated with saline and HEM, using repeated-measures ANOVA. Results: HEM significantly reduced ∆SBP and ∆MAP and augmented ∆HR than the vehicle group. CoCl 2 did not significantly affect basic ∆SBP, ∆MAP, and ∆HR compared with the vehicle group. However, injection of CoCl 2 into the CnF before HEM (CoCl 2 +HEM group) significantly decreased ∆SBP, ∆MAP, and tachycardia, induced by HEM. Conclusion: Our results indicated that blockade of the CnF by CoCl 2 significantly reduced the hypotension and tachycardia, induced by HEM indicating the involvement of CnF in cardiovascular regulation during HEM.

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Section: Introductionmentioning

confidence: 99%

Cardiovascular Effect of Cuneiform Nucleus During Hemorrhagic Hypotension

Mohebbati

Hosseini

Khazaei

et al. 2020

Basic Clin. Neurosci. J.

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The median preoptic nucleus: A major regulator of fluid, temperature, sleep, and cardiovascular homeostasis

Pennington

Ryan

2021

Handbook of Clinical Neurology

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Medullary Noradrenergic Neurons Mediate Hemodynamic Responses to Osmotic and Volume Challenges

et al. 2021

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Despite being involved in homeostatic control and hydro-electrolyte balance, the contribution of medullary (A1 and A2) noradrenergic neurons to the hypertonic saline infusion (HSI)-induced cardiovascular response after hypotensive hemorrhage (HH) remains to be clarified. Hence, the present study sought to determine the role of noradrenergic neurons in HSI-induced hemodynamic recovery in male Wistar rats (290–320 g) with HH. Medullary catecholaminergic neurons were lesioned by nanoinjection of antidopamine-β-hydroxylase–saporin (0.105 ng·nl−1) into A1, A2, or both (LES A1; LES A2; or LES A1+A2, respectively). Sham rats received nanoinjections of free saporin in the same regions (SHAM A1; SHAM A2; or SHAM A1+A2, respectively). After 15 days, rats were anesthetized and instrumented for cardiovascular recordings. Following 10 min of stabilization, HH was performed by withdrawing arterial blood until mean arterial pressure (MAP) reaches 60 mmHg. Subsequently, HSI was performed (NaCl 3 M; 1.8 ml·kg−1, i.v.). The HH procedure caused hypotension and bradycardia and reduced renal, aortic, and hind limb blood flows (RBF, ABF, and HBF). The HSI restored MAP, heart rate (HR), and RBF to baseline values in the SHAM, LES A1, and LES A2 groups. However, concomitant A1 and A2 lesions impaired this recovery, as demonstrated by the abolishment of MAP, RBF, and ABF responses. Although lesioning of only a group of neurons (A1 or A2) was unable to prevent HSI-induced recovery of cardiovascular parameters after hemorrhage, lesions of both A1 and A2 made this response unfeasible. These findings show that together the A1 and A2 neurons are essential to HSI-induced cardiovascular recovery in hypovolemia. By implication, simultaneous A1 and A2 dysfunctions could impair the efficacy of HSI-induced recovery during hemorrhage.

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Involvement of median preoptic nucleus and medullary noradrenergic neurons in cardiovascular and sympathetic responses of hemorrhagic rats

Cited by 3 publications

References 41 publications

Cardiovascular Effect of Cuneiform Nucleus During Hemorrhagic Hypotension

Cardiovascular Effect of Cuneiform Nucleus During Hemorrhagic Hypotension

The median preoptic nucleus: A major regulator of fluid, temperature, sleep, and cardiovascular homeostasis

Medullary Noradrenergic Neurons Mediate Hemodynamic Responses to Osmotic and Volume Challenges

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