Michael Ibrahim scite author profile

The transverse tubules (t-tubules) are invaginations of the cell membrane rich in several ion channels and other proteins devoted to the critical task of excitation-contraction coupling in cardiac muscle cells (cardiomyocytes). They are thought to promote the synchronous activation of the whole depth of the cell despite the fact that the signal to contract is relayed across the external membrane. However, recent work has shown that t-tubule structure and function are complex and tightly regulated in healthy cardiomyocytes. In this review, we outline the rapidly accumulating knowledge of its novel roles and discuss the emerging evidence of t-tubule dysfunction in cardiac disease, especially heart failure. Controversy surrounds the t-tubules' regulatory elements, and we draw attention to work that is defining these elements from the genetic and the physiological levels. More generally, this field illustrates the challenges in the dissection of the complex relationship between cellular structure and function.

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Modern management of systolic anterior motion of the mitral valve

Ibrahim¹,

Rao²,

Ashrafian³

et al. 2012

European Journal of Cardio-Thoracic Surgery

100

106

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Systolic anterior motion (SAM) of the mitral valve (MV) can be a life-threatening condition. The SAM can result in severe left ventricular outflow tract obstruction and/or mitral regurgitation and is associated with an up to 20% risk of sudden death (which is substantially lower in hypertrophic cardiomyopathy (HCM)). The mechanisms of SAM are complex and depend on the functional status of the ventricle. The SAM can occur in the normal population, but is typically observed in patients with HCM or following MV repair. Echocardiography (2D, 3D and stress) has a central diagnostic role as the application of echocardiographic SAM predictors allows the incorporation of prevention techniques during surgery and post-operative SAM assessment. Cardiac magnetic resonance imaging has a special role in understanding the dynamic nature of SAM, especially in anatomically atypical hearts (including HCM). This article describes what the clinician needs to know about SAM ranging from pathophysiological mechanisms and imaging modalities to conservative (medical) and surgical approaches and their respective outcomes. A stepwise approach is advocated consisting of medical therapy, followed by aggressive volume loading and beta-adrenoceptor blockade. Surgery is the final option. The correct choice of surgical technique requires an understanding of the anatomical substrate of SAM.

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Prolonged mechanical unloading affects cardiomyocyte excitation‐contraction coupling, transverse‐tubule structure, and the cell surface

et al. 2010

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Prolonged mechanical unloading (UN) of the heart is associated with detrimental changes to the structure and function of cardiomyocytes. The mechanisms underlying these changes are unknown. In this study, we report the influence of UN on excitationcontraction coupling, Ca 2؉ -induced Ca 2؉ release (CICR) in particular, and transverse (t)-tubule structure. UN was induced in male Lewis rat hearts by heterotopic abdominal heart transplantation. Left ventricular cardiomyocytes were isolated from the transplanted hearts after 4 wk and studied using whole-cell patch clamping, confocal microscopy, and scanning ion conductance microscopy (SICM). Recipient hearts were used as control (C). UN reduced the volume of cardiomyocytes by 56.5% compared with C (UN, n‫;09؍‬ C, n‫;95؍‬ P<0.001). The variance of time-to-peak of the Ca 2؉ transients was significantly increased in unloaded cardiomyocytes (UN 227.4؎24.9 ms 2 , n‫24؍‬ vs.

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Mechanical unloading reverses transverse tubule remodelling and normalizes local Ca²⁺‐induced Ca²⁺release in a rodent model of heart failure

Ibrahim

Navaratnarajah

Siedlecka

et al. 2012

European J of Heart Fail

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Aims Ca2+‐induced Ca2+ release (CICR) is critical for contraction in cardiomyocytes. The transverse (t)‐tubule system guarantees the proximity of the triggers for Ca2+ release [L‐type Ca2+ channel, dihydropyridine receptors (DHPRs)] and the sarcoplasmic reticulum Ca2+ release channels [ryanodine receptors (RyRs)]. Transverse tubule disruption occurs early in heart failure (HF). Clinical studies of left ventricular assist devices in HF indicate that mechanical unloading induces reverse remodelling. We hypothesize that unloading of failing hearts normalizes t‐tubule structure and improves CICR. Methods and results Heart failure was induced in Lewis rats by left coronary artery ligation for 12 weeks; sham‐operated animals were used as controls. Failing hearts were mechanically unloaded for 4 weeks by heterotopic abdominal heart transplantation (HF‐UN). HF reduced the t‐tubule density measured by di‐8‐ANEPPS staining in isolated left ventricular myocytes, and this was reversed by unloading. The deterioration in the regularity of the t‐tubule system in HF was also reversed in HF‐UN. Scanning ion conductance microscopy showed the reappearance of normal surface striations in HF‐UN. Electron microscopy revealed recovery of normal t‐tubule microarchitecture in HF‐UN. L‐type Ca2+ current density, measured using whole‐cell patch clamping, was reduced in HF but unaffected by unloading. The variance of the time‐to‐peak of the Ca2+ transient, an index of CICR dyssynchrony, was increased in HF and normalized by unloading. The increased Ca2+ spark frequency observed in HF was reduced in HF‐UN. These results could be explained by the recoupling of orphaned RyRs in HF, as indicated by immunofluorescence. Conclusions Our data show that mechanical unloading of the failing heart reverses the pathological remodelling of the t‐tubule system and improves CICR.

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Michael Ibrahim

The structure and function of cardiac t-tubules in health and disease

Modern management of systolic anterior motion of the mitral valve

Prolonged mechanical unloading affects cardiomyocyte excitation‐contraction coupling, transverse‐tubule structure, and the cell surface

Mechanical unloading reverses transverse tubule remodelling and normalizes local Ca²⁺‐induced Ca²⁺release in a rodent model of heart failure

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Michael Ibrahim

The structure and function of cardiac t-tubules in health and disease

Modern management of systolic anterior motion of the mitral valve

Prolonged mechanical unloading affects cardiomyocyte excitation‐contraction coupling, transverse‐tubule structure, and the cell surface

Mechanical unloading reverses transverse tubule remodelling and normalizes local Ca2+‐induced Ca2+release in a rodent model of heart failure

Contact Info

Product

Resources

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Mechanical unloading reverses transverse tubule remodelling and normalizes local Ca²⁺‐induced Ca²⁺release in a rodent model of heart failure