Abstract

Our long-term objective is to determine the influence biophysical forces have on heart development and how alterations of these forces early in development can lead to congenital heart defects (CHDs). CHDs are extremely prevalent affecting almost 36,000 newborns in the US each year, or 9 out of 1,000 live births. In order to tease apart what molecular pathways are being regulated by biomechanics, we will be developing new technology (optical pacing) capable of perturbing cardiac dynamics in precise ways. Previous perturbation techniques have involved gross manipulations (vessel ligation, conotruncal banding, etc.) that do not offer the necessary control to determine the exact influences of biomechanics on development. We have demonstrated that optical pacing is capable of consistently pacing early embryonic quail hearts in vivo in a precise manner over a range of developmental stages without causing damage to the tissue. Recent data shows that we can modify the level of regurgitant flow in the outflow tract thereby altering oscillatory shear stress (OSS). It has been suggested that shear forces in the outflow tract are needed for normal development of valves and septa. Outflow tract defects which make up 15-20% of CHDs are very serious requiring surgical intervention. As a demonstration of the potential of OP, we will create a model of abnormal regurgitant flow in the outflow tract and investigate the impact of this change in shear force on molecular expression and morphogenesis during cardiac development. Experiments will be conducted to determine the optimal energy requirements for optical pacing and these optimal settings will be utilized to develop optical pacing protocols that consistently change the levels OSS in the outflow tract to precise degrees. Optical coherence tomography will be employed to refine optical pacing methods and to measure hemodynamics and morphology both during and after optical pacing. Upon completion, we will have optimized and characterized OP as a new experimental tool, used that tool to create a model of abnormal regurgitant flow in the outflow tract, and investigated the impact of this change in shear force on gene expression and morphogenesis during cardiac development. This experimental tool will be valuable more broadly for uncovering the mechanisms of mechanically transduced signaling in the early developing heart, which will enable us to develop a better understanding of the etiology of congenital defects. OP has the potential to manipulate cardiac function in multiple ways and may be capable of producing other models of cardiac irregularities (e.g. arrhythmias, abnormal levels of regurgitant flow in the atrioventricular junction, etc.).

Public Health Relevance

The mechanisms behind congenital heart defects (CHDs) are largely unclear, and biomechanical forces likely play a role during the development of CHDs. This project aims to develop new technology (optical pacing) capable of perturbing biomechanical forces in the heart in order to elucidate the complex interplay between structure and function in the developing heart in vivo. Better understanding of the origins and progression of congenital heart defects can potentially lead to better prediction of outcomes, and earlier, more effective treatments.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21HL115373-01
Application #
8356216
Study Section
Biomedical Imaging Technology Study Section (BMIT)
Program Officer
Evans, Frank
Project Start
2012-07-17
Project End
2014-04-30
Budget Start
2012-07-17
Budget End
2013-04-30
Support Year
1
Fiscal Year
2012
Total Cost
$235,500
Indirect Cost
$85,500

  Institution

Name
Case Western Reserve University
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
077758407
City
Cleveland
State
OH
Country
United States
Zip Code
44106

  Publications

Karunamuni, Ganga; Sheehan, Megan M; Doughman, Yong Qiu et al. (2017) Supplementation with the Methyl Donor Betaine Prevents Congenital Defects Induced by Prenatal Alcohol Exposure. Alcohol Clin Exp Res 41:1917-1927
Ford, Stephanie M; McPheeters, Matthew T; Wang, Yves T et al. (2017) Increased regurgitant flow causes endocardial cushion defects in an avian embryonic model of congenital heart disease. Congenit Heart Dis 12:322-331
Peterson, Lindsy M; Gu, Shi; Karunamuni, Ganga et al. (2017) Embryonic aortic arch hemodynamics are a functional biomarker for ethanol-induced congenital heart defects [Invited]. Biomed Opt Express 8:1823-1837
Lothet, Emilie H; Shaw, Kendrick M; Lu, Hui et al. (2017) Selective inhibition of small-diameter axons using infrared light. Sci Rep 7:3275
Watanabe, Michiko; Rollins, Andrew M; Polo-Parada, Luis et al. (2016) Probing the Electrophysiology of the Developing Heart. J Cardiovasc Dev Dis 3:
Ma, Pei; Chan, Dennis C; Gu, Shi et al. (2016) Volumetric optical mapping in early embryonic hearts using light-sheet microscopy. Biomed Opt Express 7:5120-5128
Blech-Hermoni, Yotam; Sullivan, Connor B; Jenkins, Michael W et al. (2016) CUG-BP, Elav-like family member 1 (CELF1) is required for normal myofibrillogenesis, morphogenesis, and contractile function in the embryonic heart. Dev Dyn 245:854-73
Wang, Yves T; Rollins, Andrew M; Jenkins, Michael W (2016) Infrared inhibition of embryonic hearts. J Biomed Opt 21:60505
Ma, Pei; Gu, Shi; Karunamuni, Ganga H et al. (2016) Cardiac neural crest ablation results in early endocardial cushion and hemodynamic flow abnormalities. Am J Physiol Heart Circ Physiol 311:H1150-H1159
Coram, Ryan J; Stillwagon, Samantha J; Guggilam, Anuradha et al. (2015) Muscleblind-like 1 is required for normal heart valve development in vivo. BMC Dev Biol 15:36

Showing the most recent 10 out of 18 publications