PURPOSE: To design a method suitable for obtaining tissue samples from regions of different function as ascertained by magnetic resonance imaging (MRI). MATERIALS AND METHODS: In vivo MRI was used to create azimuthal projections of the heart from dilated cardiomyopathy transplant patients with the cardiac valves in the center and four concentric rings representing the septum and free wall. Tagged MRI could identify regions of different contractile strength that were then transferred onto the map projection. The resulting tissue sampling map was used to guide dissection of tissue samples from the explanted heart for analysis by electron microscopy (EM) as well as provide samples for subsequent mRNA analysis. Accuracy of the sampling was determined in a sheep heart using 17 fiduciary markers glued to the epicardial surface. RESULTS: Tagged MRI identified areas of "normal"(%S(c)-11),"poor"(%S(c)-4) and "failed" contraction (%S(c)+3). The mapping method we developed enabled straightforward sampling of these regions after surgical excision. EM showed good tissue preservation while the test of accuracy using the fiduciary markers showed a sampling accuracy of 0.3 ± 3.7 mm. This was similar to the resolution of tagged MRI images themselves. CONCLUSION: The methods we have developed can accurately guide tissue sampling for ex vivo tissue analysis. J. Magn. Reson. Imaging 2011. © 2011 Wiley-Liss, Inc.

1. Alterations in intracellular Ca(2+) homeostasis have frequently been implicated as underlying the contractile dysfunction of failing hearts. Contraction in cardiac muscle is due to a balance between sarcolemmal (SL) and sarcoplasmic reticulum (SR) Ca(2+) transport, which has been studied in single cells and small tissue samples. However, many studies have not used physiological temperatures and pacing rates, and this could be problematic given different temperature dependencies and kinetics for transport processes. 2. Spontaneously-hypertensive rats (SHR) and their age-matched Wistar Kyoto controls (WKY) provide an animal model of hypertensive failure with many features in common to heart failure in humans. Steady-state measurements of Ca(2+) and force showed that peak stress was reduced in trabeculae from failing SHR hearts in comparison to WKY, although the Ca(2+) transients were bigger and decayed more slowly. 3. Dynamic Ca(2+) cycling was investigated by determining the recirculation fraction (RF) of activator Ca(2+) through the SR between beats during recovery from experimental protocols that potentiated twitch force. No difference in RF between rat strains was found, although the RF was dependent on the potentiation protocol used. 4. Superfusion with 10 mmol/L caffeine and 0 mmol/L [Ca(2+)](o) was used to measure SL Ca(2+) extrusion. The caffeine-induced [Ca(2+)](i) transient decayed more slowly in SHR trabeculae, suggesting that SL Ca(2+) extrusion was slower in SHR. 5. An ultrastructural immunohistochemical analysis of left ventricular free wall sections using confocal microscopy showed that t-tubule organization was disrupted in myocytes from SHR, with reduced labelling of the SR Ca(2+)-ATPase and Na(+)-Ca(2+) exchanger in comparison to WKY, with the latter possibly related to a lower fraction of t-tubules per unit cell volume. 6. We suggest that although Ca(2+) transport is altered in the progression to heart failure, force development is not limited by the amplitude of the Ca(2+) transient. Despite slower SR Ca(2+) transport, the recirculation fraction and dynamic response to a change of inotropic state minimally altered changes in the SHR model because there was a similar slowing in Ca(2+) extrusion across the surface membrane.

[This corrects the article on p. e17901 in vol. 6.].

BACKGROUND The cardiac myocyte t-tubular system ensures rapid, uniform cell activation and several experimental lines of evidence suggest changes in the t-tubular system and associated excitation-contraction coupling proteins may occur in heart failure. METHODS AND RESULTS The organization of t-tubules, L-type calcium channels (DHPRs), ryanodine receptors (RyRs) and contractile machinery were examined in fixed ventricular tissue samples from both normal and failing hearts (idiopathic (non-ischemic) dilated cardiomyopathy) using high resolution fluorescent imaging. Wheat germ agglutinin (WGA), Na-Ca exchanger, DHPR and caveolin-3 labels revealed a shift from a predominantly transverse orientation to oblique and axial directions in failing myocytes. In failure, dilation of peripheral t-tubules occurred and a change in the extent of protein glycosylation was evident. There was no change in the fractional area occupied by myofilaments (labeled with phalloidin) but there was a small reduction in the number of RyR clusters per unit area. The general relationship between DHPRs and RyR was not changed and RyR labeling overlapped with 51±3% of DHPR labeling in normal hearts. In longitudinal (but not transverse) sections there was an ∼30% reduction in the degree of colocalization between DHPRs and RyRs as measured by Pearson's correlation coefficient in failing hearts. CONCLUSIONS The results show that extensive remodelling of the t-tubular network and associated excitation-contraction coupling proteins occurs in failing human heart. These changes may contribute to abnormal calcium handling in heart failure. The general organization of the t-system and changes observed in failure samples have subtle differences to some animal models although the general direction of changes are generally similar.

Diabetes now affects more than 5% of the world's population and heart failure is the most common cause of death amongst diabetic patients. Accumulating evidence supports a view that myocardial mitochondrial structural and functional changes are central to the onset of diabetic heart failure, but the exact nature of these changes at the proteomic level remains unclear.Here we report on proteomic changes in diabetic rat heart mitochondria following 120 days of streptozotocin-diabetes using the recently developed iTRAQ™ labeling method, which permits quantification of proteins directly from complex mixtures, bypassing the limitations associated with gel-based methods such as 2-DE. Of 252 unique proteins identified, 144 were represented in at least three of six individual paired experiments. Relative amounts of 65 proteins differed significantly between the groups, confirming that the cardiac mitochondrial proteome is indeed impacted by diabetes. The most significant changes were increased protein levels of enzymes involved in mitochondrial oxidation of long-chain fatty acids, which was also confirmed by enzyme assays, and decreased levels of multiple enzymes involved in oxidative phosphorylation and catabolism of short-chain fatty acids and branched-chain amino acids. We also found significant changes in levels of several enzymes linked to oxidative stress.

Using deconvolved confocal microscopy of fluorescently labeled markers for z-disks, t-tubules and ryanodine receptors, we have examined sarcomere organization in cardiac myocytes from rat, rabbit and human. We show that sarcomeres exhibit dislocations in registration and occasionally more complex helicoidal topology. This organization was present at both slack ( approximately 1.8 microm) and long sarcomere lengths ( approximately 2.2 microm). Misregistrations in z-disks persisted over 15-20 sarcomere lengths and appeared to arise primarily from variations in fiber direction; particularly as myofibrils pass around nuclei. In addition, myofibrils twist along the cell length. T-tubules generally follow the sarcomere z-disks although additional elements bridging adjacent myofibrils and along the length of the myofibril are present to varying degrees in all cells. Ryanodine receptors (the sarcoplasmic reticulum Ca(2+) release channel) are generally located within 250 nm of the local plane containing t-tubules and z-disks, but a small fraction ( approximately 2%) is found on longitudinal elements of the t-system between z-disks. The results are discussed with respect to the possible role(s) of such complex z-disk organization and z-disk dislocations in the maintenance of cell structure and sarcomere assembly. In addition, the non-planar organization of z-disks may be important in the propagation of local Ca(2+) waves which may have a useful role in helping maintain the uniformity of sarcomere activation in the presence of t-tubule remodeling.

Heart disease is the major cause of death in diabetes, a disorder characterized by chronic hyperglycemia and cardiovascular complications. Although altered systemic regulation of transition metals in diabetes has been the subject of previous investigation, it is not known whether changed transition metal metabolism results in heart disease in common forms of diabetes and whether metal chelation can reverse the condition. We found that administration of the Cu-selective transition metal chelator trientine to rats with streptozotocin-induced diabetes caused increased urinary Cu excretion compared with matched controls. A Cu(II)-trientine complex was demonstrated in the urine of treated rats. In diabetic animals with established heart failure, we show here for the first time that 7 weeks of oral trientine therapy significantly alleviated heart failure without lowering blood glucose, substantially improved cardiomyocyte structure, and reversed elevations in left ventricular collagen and beta(1) integrin. Oral trientine treatment also caused elevated Cu excretion in humans with type 2 diabetes, in whom 6 months of treatment caused elevated left ventricular mass to decline significantly toward normal. These data implicate accumulation of elevated loosely bound Cu in the mechanism of cardiac damage in diabetes and support the use of selective Cu chelation in the treatment of this condition.