about
Mechanisms underlying the cardiac pacemaker: the role of SK4 calcium-activated potassium channelsMicroRNAs: a new piece in the paediatric cardiovascular disease puzzleGap junction modulation and its implications for heart functionGap junctionsCross talk between cardiac myocytes and fibroblasts: from multiscale investigative approaches to mechanisms and functional consequencesSimulation of Cardiac Arrhythmias Using a 2D Heterogeneous Whole Heart ModelComputational model of erratic arrhythmias in a cardiac cell network: the role of gap junctionsMaturing human pluripotent stem cell-derived cardiomyocytes in human engineered cardiac tissuesGenetics of sick sinus syndromeH2S-releasing nanoemulsions: a new formulation to inhibit tumor cells proliferation and improve tissue repair.Functional scaffold-free 3-D cardiac microtissues: a novel model for the investigation of heart cells.Connexins and the atrioventricular node.A rapid and sensitive assay of intercellular coupling by voltage imaging of gap junction networksReciprocal myocardial-endocardial interactions pattern the delay in atrioventricular junction conduction.Naturally Engineered Maturation of CardiomyocytesEffect of beta-carotene on oxidative stress and expression of cardiac connexin 43.Myosin light chain 2-based selection of human iPSC-derived early ventricular cardiac myocytes.The App-Runx1 region is critical for birth defects and electrocardiographic dysfunctions observed in a Down syndrome mouse model.A peptide mimetic of the connexin43 carboxyl terminus reduces gap junction remodeling and induced arrhythmia following ventricular injury.Mammalian enabled (Mena) is a critical regulator of cardiac function.SHOX2 overexpression favors differentiation of embryonic stem cells into cardiac pacemaker cells, improving biological pacing ability.High flow conditions increase connexin43 expression in a rat arteriovenous and angioinductive loop modelAtrial fibrillation-linked germline GJA5/connexin40 mutants showed an increased hemichannel functionAssembly of the cardiac intercalated disk during pre- and postnatal development of the human heart.Genetic variation at the human connexin 43 locus but not at the connexin 40 locus is associated with left bundle branch block.Enhanced PKCε mediated phosphorylation of connexin43 at serine 368 by a carboxyl-terminal mimetic peptide is dependent on injury.Cardiac response to low-energy field pacing challenges the standard theory of defibrillation.Remodeling of the peripheral cardiac conduction system in response to pressure overloadAtrial Anti-Arrhythmic Effects of Heptanol in Langendorff-Perfused Mouse HeartsDifferent Profile of mRNA Expression in Sinoatrial Node from Streptozotocin-Induced Diabetic RatAltered conductance and permeability of Cx40 mutations associated with atrial fibrillationCardiac ion channelopathies and the sudden infant death syndromeNew protein-protein interactions of mitochondrial connexin 43 in mouse heartMechanism of Mitochondrial Connexin43's Protection of the Neurovascular Unit under Acute Cerebral Ischemia-Reperfusion Injury.The road to biological pacing.Late arrhythmias after surgery for transposition of the great arteries.New antiarrhythmic targets to control intracellular calcium handling.Connexins in the heart.Role of connexins and pannexins in cardiovascular physiology.Gq-activated fibroblasts induce cardiomyocyte action potential prolongation and automaticity in a 3D microtissue environment.
P2860
Q26771350-04500208-4BF0-44ED-9DA2-4FA1921EEE75Q26822990-E6512D85-8E9C-4897-B387-A6FAFD766DA9Q26823004-87D45A34-6DBA-44D9-A5C8-282E4BC92B00Q26850591-C0FBC99C-BBAB-41F0-93E3-D592FF5B3A08Q27021613-673CD269-098F-4B67-9537-078E18BAAEACQ27307949-C7DC9A70-1813-4B5E-A2AB-79D28925A94AQ27322666-66C1A288-2AB4-4F04-8CDD-A0020838B829Q28550738-855A8CAB-3442-48D1-A813-A4E6364CC76CQ28741053-02DB587D-94BD-4BCF-887E-8E5BF6D3065AQ30358087-07C9F0BC-0102-4439-AF65-675C4CCB4B48Q30514243-A891A0C8-FD84-4CE6-BCF2-DB221D5D015EQ30535769-6D57909B-4967-4117-BAB8-43A6D3523003Q30557012-0A48D8B6-B2C4-407B-A5A7-22E51B795D4CQ30617471-D5A700E1-49A5-452E-85C7-AFC4266E0FFEQ33639096-2D1F095D-9387-4AE3-A611-0037137080C8Q33655072-B91A1118-1A55-4841-9787-FB9D3ADF7F8AQ34103739-9B4D2C2E-8583-4B66-924B-B2D9D39E2CC9Q34302163-EDB91894-D617-49D9-A383-8E66697929C8Q34789344-1F2A4EF0-7E1D-4937-897C-665E00A72B86Q34979743-18708AF5-0245-497B-A3F4-5C376B95C314Q34980766-77C80B58-194D-4E80-AB37-9C7E94BDCE93Q35043578-A39885AA-1D41-46A3-8A3D-C7F64B7671E9Q35147842-4E26940D-8A3D-421C-A0DD-B23B6DC9BDBCQ35147854-734AD4C0-B976-4897-90F0-FF319FF9AB1CQ35399823-D4016583-67F7-4C6F-9A06-08EC43522B02Q35577761-E0A7D965-A544-4043-9ECE-DC21ACA89ABBQ35756172-159E14E5-1AF1-433B-BB4D-A26D4D4EA3CCQ35900985-7F4F6E4B-A1D2-477B-B57D-AF7165F857A1Q35922458-44CD4A33-CF92-4AB6-8658-F6AC3C530BFCQ35994650-15CF4966-5E8C-4535-B723-3345445369D5Q36210366-2088F88B-7372-4855-BDDA-8021A91280B8Q36486478-7F67F285-B3A2-4948-8D32-FC5A94ECD45AQ36797515-51259E81-472C-4BC3-A8B0-A4BC09B39D54Q36939210-004FBD5F-6C80-4066-BDF7-FE9AEF2C7295Q37918327-B1458EFD-982F-45D5-94D9-E786D5166723Q38117351-8DA2C653-AEF9-442D-B2DA-3974409F762FQ38204723-EEAAD681-77C0-45B6-8E92-7C6C17F8AB3FQ38263987-A12A90CE-6FD9-47CF-847F-692310C988A4Q38532371-C77B8B6F-D683-4CB5-900E-0290B3578B74Q38678276-D2761CB4-96B4-427A-A226-E0825A9E2B8B
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 31 August 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Cardiac connexins and impulse propagation.
@en
Cardiac connexins and impulse propagation.
@nl
type
label
Cardiac connexins and impulse propagation.
@en
Cardiac connexins and impulse propagation.
@nl
prefLabel
Cardiac connexins and impulse propagation.
@en
Cardiac connexins and impulse propagation.
@nl
P2093
P1476
Cardiac connexins and impulse propagation.
@en
P2093
Harold V M van Rijen
Jacques M T de Bakker
John A Jansen
Toon A B van Veen
P356
10.1016/J.YJMCC.2009.08.018
P577
2009-08-31T00:00:00Z