Engineered Cardiac Pacemaker Nodes Created by TBX18 Gene Transfer Overcome Source–Sink Mismatch

Autor:	Natasha Fernandez, Hee Cheol Cho, Jung Hoon Sung, Flavio H. Fenton, Jin-mo Gu, Jinqi Fan, Erin M. Buckley, Jun Li, Sung-Jin Park, Conner Herndon, Seung Yup Lee, Sandra I. Grijalva
Rok vydání:	2019
Předmět:	Heartbeat Computer science TBX18 General Chemical Engineering medicine.medical_treatment General Physics and Astronomy Medicine (miscellaneous) Gene transfer 02 engineering and technology 010402 general chemistry 01 natural sciences Biochemistry Genetics and Molecular Biology (miscellaneous) Cardiac pacemaker biological pacemakers medicine General Materials Science Ventricular myocytes lcsh:Science cell and tissue engineering Source sink Full Paper Cardiac cycle Sinoatrial node General Engineering Full Papers 021001 nanoscience & nanotechnology 0104 chemical sciences medicine.anatomical_structure Physical separation source–sink mismatch cardiovascular system sinoatrial nodes lcsh:Q 0210 nano-technology Neuroscience
Zdroj:	Advanced Science, Vol 6, Iss 22, Pp n/a-n/a (2019) Advanced Science
ISSN:	2198-3844
DOI:	10.1002/advs.201901099
Popis:	Every heartbeat originates from a tiny tissue in the heart called the sinoatrial node (SAN). The SAN harbors only ≈10 000 cardiac pacemaker cells, initiating an electrical impulse that captures the entire heart, consisting of billions of cardiomyocytes for each cardiac contraction. How these rare cardiac pacemaker cells (the electrical source) can overcome the electrically hyperpolarizing and quiescent myocardium (the electrical sink) is incompletely understood. Due to the scarcity of native pacemaker cells, this concept of source–sink mismatch cannot be tested directly with live cardiac tissue constructs. By exploiting TBX18 induced pacemaker cells by somatic gene transfer, 3D cardiac pacemaker spheroids can be tissue‐engineered. The TBX18 induced pacemakers (sphTBX18) pace autonomously and drive the contraction of neighboring myocardium in vitro. TBX18 spheroids demonstrate the need for reduced electrical coupling and physical separation from the neighboring ventricular myocytes, successfully recapitulating a key design principle of the native SAN. β‐Adrenergic stimulation as well as electrical uncoupling significantly increase sphTBX18s' ability to pace‐and‐drive the neighboring myocardium. This model represents the first platform to test design principles of the SAN for mechanistic understanding and to better engineer biological pacemakers for therapeutic translation. The engineering sinoatrial node (eSAN) in a dish design is inspired by the remarkable structure of the native SAN exit pathways. The architecture of the native SAN reduces the need for large number of pacemaker cells to spontaneously and autonomously pace‐and‐drive every single heartbeat.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::3baed4a1d9c44ff4cef897cd23da6584 https://doi.org/10.1002/advs.201901099 Zobrazit plný text záznamu Plný text