Literature DB >> 27895597

Corrigendum: Pacemaking Property of RVLM Presympathetic Neurons.

Daniela Accorsi-Mendonça¹, Melina P da Silva¹, George M P R Souza¹, Ludmila Lima-Silveira¹, Marlusa Karlen-Amarante¹, Mateus R Amorim¹, Carlos E L Almado¹, Davi J A Moraes¹, Benedito H Machado¹.

Abstract

[This corrects the article on p. 424 in vol. 7, PMID: 27713705.].

Entities: Chemical Disease Species

Keywords: neurogenic hypertension; presympathetic neurons; sympathetic activity

Year: 2016 PMID： 27895597 PMCID： PMC5120487 DOI： 10.3389/fphys.2016.00575

Source DB: PubMed Journal: Front Physiol ISSN： 1664-042X Impact factor: 4.566

Due to an oversight, the authors did not properly cite two important publications by Roger A. Dampney. In section “RVLM and sympathetic outflow,” the second paragraph should read as follows: Additional evidence about the relevance of RVLM in the maintenance of baseline arterial pressure was provided in a study by Guertzenstein and Silver (1974), in which they demonstrated that bilateral inhibition of specific areas in the ventral medulla, using inhibitory amino acid glycine, produced a large fall in the arterial blood pressure, similar to that described by Dittmar after medullo-spinal transections. Equally important were the contributions by Dampney (1981) and Dampney et al. (1982), which original studies documented that microinjections of L-glutamate into the ventral medulla increased arterial pressure in anesthetized rabbits. The role of RVLM in controlling the cardiovascular function was also described in a study by Granata et al. (1983), which reinforced the concept of a key region in the medullary surface for the maintenance of arterial blood pressure. Moreover, RVLM activation by either electrical stimulation or application of excitatory amino acid (glutamate) or even RVLM disinhibition by application of GABA receptor antagonist (bicuculline), in anesthetized or conscious animals, elicited an increase in sympathetic activity and arterial blood pressure (Willette et al., 1983; Reis et al., 1984; Ross et al., 1984a; de Paula and Machado, 2000; Sakima et al., 2000; Moraes et al., 2011), while bilateral electrolytic lesions, microinjection of GABA or administration of tetrodotoxin, leads to a large fall in the arterial pressure to levels comparable to those observed after transection below brainstem (Dampney and Moon, 1980; Willette et al., 1983; Reis et al., 1984; Benarroch et al., 1986). The authors apologize for this oversight. This error does not affect the scientific conclusions of this article in any way.

Conflict of interest statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

12 in total

1. Changes in regional vascular resistance in response to microinjection of L-glutamate into different antero-posterior coordinates of the RVLM in awake rats.

Authors: P M de Paula; B H Machado
Journal: Auton Neurosci Date: 2000-08-14 Impact factor: 3.145

2. Fall in blood pressure produced from discrete regions of the ventral surface of the medulla by glycine and lesions.

Authors: P G Guertzenstein; A Silver
Journal: J Physiol Date: 1974-10 Impact factor: 5.182

3. Rostral ventrolateral medulla: selective projections to the thoracic autonomic cell column from the region containing C1 adrenaline neurons.

Authors: C A Ross; D A Ruggiero; T H Joh; D H Park; D J Reis
Journal: J Comp Neurol Date: 1984-09-10 Impact factor: 3.215

4. Role of ventrolateral medulla in vasomotor response to cerebral ischemia.

Authors: R A Dampney; E A Moon
Journal: Am J Physiol Date: 1980-09

5. Cardiovascular and sympathetic effects of L-glutamate and glycine injected into the rostral ventrolateral medulla of conscious rats.

Authors: A Sakima; M Yamazato; S Sesoko; H Muratani; K Fukiyama
Journal: Hypertens Res Date: 2000-11 Impact factor: 3.872

6. Modulation of respiratory responses to chemoreflex activation by L-glutamate and ATP in the rostral ventrolateral medulla of awake rats.

Authors: Davi J A Moraes; Leni G H Bonagamba; Daniel B Zoccal; Benedito H Machado
Journal: Am J Physiol Regul Integr Comp Physiol Date: 2011-03-16 Impact factor: 3.619

7. Role of ventrolateral medulla in vasomotor regulation: a correlative anatomical and physiological study.

Authors: R A Dampney; A K Goodchild; L G Robertson; W Montgomery
Journal: Brain Res Date: 1982-10-14 Impact factor: 3.252

8. Vasopressor and depressor areas in the rat medulla. Identification by microinjection of L-glutamate.

Authors: R N Willette; P P Barcas; A J Krieger; H N Sapru
Journal: Neuropharmacology Date: 1983-09 Impact factor: 5.250

9. Lesions of epinephrine neurons in the rostral ventrolateral medulla abolish the vasodepressor components of baroreflex and cardiopulmonary reflex.

Authors: A R Granata; D A Ruggiero; D H Park; T H Joh; D J Reis
Journal: Hypertension Date: 1983 Nov-Dec Impact factor: 10.190

10. Neurons of C1 area mediate cardiovascular responses initiated from ventral medullary surface.

Authors: E E Benarroch; A R Granata; D A Ruggiero; D H Park; D J Reis
Journal: Am J Physiol Date: 1986-05