Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model

Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model

Abstract Rationale Synchronized positive pressure ventilation is possible using diaphragm electrical activity (EAdi) to control the ventilator. It is unknown whether EAdi can be used to control negative pressure ventilation. Aim To evaluate the feasibility of using EAdi to control negative pressure...

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Main Authors: Daijiro Takahashi, Ling Liu, Christer Sinderby, Jennifer Beck
Format: Article
Language:English
Published: Wiley 2020-07-01
Series:Physiological Reports
Subjects:
diaphragm electrical activity
neural control of breathing
patient‐ventilator interaction
Online Access:https://doi.org/10.14814/phy2.14499
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spelling doaj-56d8098f0f974df5a6aa78a3bc2ff8622020-11-25T02:33:32ZengWileyPhysiological Reports2051-817X2020-07-01813n/an/a10.14814/phy2.14499Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal modelDaijiro Takahashi0Ling Liu1Christer Sinderby2Jennifer Beck3Division of Pediatrics Fukuda Hospital Kumamoto JapanDepartment of Critical Care Medicine Zhongda Hospital School of Medicine Southeast University Nanjing ChinaKeenan Research Centre for Biomedical Science of St. Michael’s Hospital Department of Critical Care St. Michael's Hospital Toronto ON CanadaKeenan Research Centre for Biomedical Science of St. Michael’s Hospital Department of Critical Care St. Michael's Hospital Toronto ON CanadaAbstract Rationale Synchronized positive pressure ventilation is possible using diaphragm electrical activity (EAdi) to control the ventilator. It is unknown whether EAdi can be used to control negative pressure ventilation. Aim To evaluate the feasibility of using EAdi to control negative pressure ventilation. Methods Fourteen anesthetized rats were studied (380–590 g) during control, resistive breathing, acute lung injury or CO2 rebreathing. Positive pressure continuous neurally adjusted ventilatory assist (cNAVAP+) was applied via intubation. Negative pressure cNAVA (cNAVAP−) was applied with the animal placed in a sealed box. In part 1, automatic stepwise increments in cNAVA level by 0.2 cmH2O/µV every 30 s was applied for cNAVAP+, cNAVAP−, and a 50/50 combination of the two (cNAVAP±). In part 2: During 5‐min ventilation with cNAVAP+ or cNAVAP− we measured circuit, box, and esophageal (Pes) pressure, EAdi, blood pressure, and arterial blood gases. Results Part 1: During cNAVAP+, pressure in the circuit increased with increasing cNAVA levels, reaching a plateau, and similarly for cNAVAP−, albeit reversed in sign. This was associated with downregulation of the EAdi. Pes swings became less negative with cNAVAP+ but, in contrast, Pes swings were more negative during increasing cNAVAP− levels. Increasing the cNAVA level during cNAVAP± resulted in an intermediate response. Part 2: no significant differences were observed for box/circuit pressures, EAdi, blood pressure, or arterial blood gases. Pes swings during cNAVAP− were significantly more negative than during cNAVAP+. Conclusion Negative pressure ventilation synchronized and proportional to the diaphragm activity is feasible in small animals.https://doi.org/10.14814/phy2.14499diaphragm electrical activityneural control of breathingpatient‐ventilator interaction
collection DOAJ
language English
format Article
sources DOAJ
author Daijiro Takahashi
Ling Liu
Christer Sinderby
Jennifer Beck
spellingShingle Daijiro Takahashi
Ling Liu
Christer Sinderby
Jennifer Beck
Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model
Physiological Reports
diaphragm electrical activity
neural control of breathing
patient‐ventilator interaction
author_facet Daijiro Takahashi
Ling Liu
Christer Sinderby
Jennifer Beck
author_sort Daijiro Takahashi
title Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model
title_short Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model
title_full Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model
title_fullStr Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model
title_full_unstemmed Feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model
title_sort feasibility of neurally synchronized and proportional negative pressure ventilation in a small animal model
publisher Wiley
series Physiological Reports
issn 2051-817X
publishDate 2020-07-01
description Abstract Rationale Synchronized positive pressure ventilation is possible using diaphragm electrical activity (EAdi) to control the ventilator. It is unknown whether EAdi can be used to control negative pressure ventilation. Aim To evaluate the feasibility of using EAdi to control negative pressure ventilation. Methods Fourteen anesthetized rats were studied (380–590 g) during control, resistive breathing, acute lung injury or CO2 rebreathing. Positive pressure continuous neurally adjusted ventilatory assist (cNAVAP+) was applied via intubation. Negative pressure cNAVA (cNAVAP−) was applied with the animal placed in a sealed box. In part 1, automatic stepwise increments in cNAVA level by 0.2 cmH2O/µV every 30 s was applied for cNAVAP+, cNAVAP−, and a 50/50 combination of the two (cNAVAP±). In part 2: During 5‐min ventilation with cNAVAP+ or cNAVAP− we measured circuit, box, and esophageal (Pes) pressure, EAdi, blood pressure, and arterial blood gases. Results Part 1: During cNAVAP+, pressure in the circuit increased with increasing cNAVA levels, reaching a plateau, and similarly for cNAVAP−, albeit reversed in sign. This was associated with downregulation of the EAdi. Pes swings became less negative with cNAVAP+ but, in contrast, Pes swings were more negative during increasing cNAVAP− levels. Increasing the cNAVA level during cNAVAP± resulted in an intermediate response. Part 2: no significant differences were observed for box/circuit pressures, EAdi, blood pressure, or arterial blood gases. Pes swings during cNAVAP− were significantly more negative than during cNAVAP+. Conclusion Negative pressure ventilation synchronized and proportional to the diaphragm activity is feasible in small animals.
topic diaphragm electrical activity
neural control of breathing
patient‐ventilator interaction
url https://doi.org/10.14814/phy2.14499
work_keys_str_mv AT daijirotakahashi feasibilityofneurallysynchronizedandproportionalnegativepressureventilationinasmallanimalmodel
AT lingliu feasibilityofneurallysynchronizedandproportionalnegativepressureventilationinasmallanimalmodel
AT christersinderby feasibilityofneurallysynchronizedandproportionalnegativepressureventilationinasmallanimalmodel
AT jenniferbeck feasibilityofneurallysynchronizedandproportionalnegativepressureventilationinasmallanimalmodel
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