Your search keyword '"David S. Pitcher"' showing total 2 results

1. 4969Enhanced gap junction coupling organised and terminated acute ventricular fibrillation in ex-vivo perfused hearts

Author

Rasheda A. Chowdhury, Caroline H. Roney, Fu Siong Ng, Balvinder S. Handa, N S Peter, David S. Pitcher, and Xinyang Li

Subjects

Coupling (electronics), Nuclear magnetic resonance, business.industry, Ventricular fibrillation, medicine, Gap junction, Cardiology and Cardiovascular Medicine, medicine.disease, business, Ex vivo

Abstract

Background The underlying mechanism of ventricular fibrillation (VF) remains unclear. There are both experimental and clinical data to support the existence of rotational drivers (RDs), though other opposing studies suggest that VF is the result of disorganized myocardial activation. Abnormal electrical coupling between cardiomyocytes through gap junctions (GJ) has been considered an important factor in the genesis and maintenance of VF and pre-treatment with GJ couplers, rotigaptide (RTG), has been shown to reduce VF inducibility. Purpose We hypothesized that the degree of GJ coupling determines the underlying mechanism of VF, and that changes in GJ coupling can shift or modify the predominant mechanism of fibrillation along the spectrum between disorganised activity and organised drivers. We proposed that increased organisation of VF is critical to its termination. Methods Thirty Sprague-Dawley rat hearts were explanted, perfused ex-vivo and acute VF was induced with burst pacing and 30μM pinacidil. Optical mapping of transmembrane potential was performed at baseline and the effects of GJ coupling on VF dynamics were studied in an acute VF model by perfusing with increasing concentrations of a GJ uncoupler; carbenoxolone (0–50μM, CBX, n=10) or a GJ coupling-enhancer; RTG (0–80nM, n=10). A chronic diffuse fibrosis model (n=10) was generated with 4 weeks of in-vivo angiotensin infusion (500nm/kg/min). Fibrillation dynamics were quantified using phase analysis, phase singularity (PS) tracking and our novel method of global fibrillation organisation quantification, frequency dominance index (FDI), which is a power ratio of highest amplitude dominant frequency in the frequency spectrum. Results RTG increased average rotations per RD (Baseline: 2.86±0.10 vs 80nM: 5.66±0.43, p5 rotations. FDI increased with RTG (0.53±0.04 vs 0.78±0.3, p Conclusion The degree of GJ coupling is a key determinant of the underlying mechanism of VF. RTG organised fibrillation and stabilised RDs in a concentration-dependent manner whilst CBX disorganised VF. Enhancing GJ coupling with RTG in diseased hearts with fibrosis can terminate VF and may be a potential therapeutic target in acute VF. Acknowledgement/Funding BHF Programme Grant PG/16/17/32069

Published

2019

2. P1594Ventricular fibrosis spatial distribution and quantity is a key mechanistic determinant of ventricular fibrillation mechanisms

Author

Rasheda A. Chowdhury, Balvinder S. Handa, Nicholas S. Peters, Richard J. Jabbour, Fu Siong Ng, David S. Pitcher, Xinyang Li, and Catherine Mansfield

Subjects

Fibrosis, business.industry, Ventricular fibrillation, Key (cryptography), medicine, Cardiology and Cardiovascular Medicine, medicine.disease, business, Neuroscience

Abstract

Background Ventricular fibrosis is known to play a critical role in initiation and maintenance of ventricular fibrillation (VF). Post myocardial infarction the quantity of fibrosis negatively correlates with survival. There is a lack of data on how the quantity and degree of fibrosis influences the mechanisms of VF itself. VF mechanisms remain debated, there are data to support both critical areas sustaining rotational drivers (RDs) and the contrary hypothesis of disorganized myocardial activation driving VF. Purpose We hypothesized that the underlying mechanism of VF is influenced by the spatial distribution and quantity of ventricular fibrosis. Methods Thirty-five Sprague-Dawley rats underwent permanent left anterior descending (LAD) ligation (n=11), 20mins LAD territory ischaemia-reperfusion (n=13) or in-vivo angiotensin infusion (500ng/kg/min, n=11) to generate compact (CF), patchy (PF) and diffuse fibrosis (DF) models respectively. After a 4-week maturation period, the hearts were explanted, Langendorff perfused and VF induced with burst pacing and 30μM pinacidil. Fibrillation dynamics were quantified using phase analysis, phase singularity (PS) tracking and our novel method of global fibrillation organisation quantification, frequency dominance index (FDI), which is a power ratio of highest amplitude dominant frequency in the frequency spectrum. Results Ventricular fibrosis for each group was characterized and quantified (CF: 22.3±3.2%, PF: 18.4±4.2%, DF: 5.8±1.3%, p=0.046). VF was driven predominantly by disorganised activity in CF, PSs were detected 26±7% of time comparative to 51.2±4% in DF and 69.5±8% in PF group (p=0.001). PF stabilised RDs, average maximum rotations for a single RD in PF were 31.6±7.1 comparative to 12.5±1.7 in DF and 6.4±1.1 in CF, p Conclusion VF mechanisms occur along a spectrum between organised activity sustained by discrete drivers and disorganised myocardial activation. The underlying VF mechanism can differ significantly dependent on the quantity and pattern of fibrosis. Patchy fibrosis stabilises RDs with localization to discrete areas and sustains an organised form of VF comparative to CF where VF is largely disorganised. Characterising the degree and pattern of fibrosis in patient groups vulnerable to VF might be beneficial in identifying patients with suitable targets for ablation. Acknowledgement/Funding BHF Programme Grant PG/16/17/32069

Published

2019