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  1. Home
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Browsing by Subject "Cardiac muscle"

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    Effect of melatonin on the cardiotoxicity of doxorubicin
    (Murcia : F. Hernández, 2004) Balli, E.; Mete, U.O.; Tuli, A.; Tap, O.; Kaya, M.
    This study was designed to investigate the preventive effect of melatonin on doxorubicin’s most important side effect, cardiotoxicity. Forty male albino Wistar rats were utilized and the rats were divided into five groups: group I, 0.9 % NaCl for 4 days; group II, doxorubicin 3 mg/kg/day for 4 days; group III, 2.5 % ethanol for 15 days; group IV, melatonin 6 mg/kg/day for 15 days; and group V, a doxorubicin and melatonin combination were administered intraperitoneally. At the end of the experiment, tissue samples obtained from the cardiac muscle of the left ventricle of the rats were processed for measurement of malondialdehyde and for electron microscopic examination. Malondialdehyde, a product of lipid peroxidation, was found to be significantly higher in the doxorubicin group. However, in the doxorubicin and melatonin combination group the level of malondialdehyde was decreased statistical significant. The histological examination revealed destruction of myofibrils, disorganization of sarcomeres, mitochondrial degeneration and formation of giant mitochondria and lipid accumulation in the doxorubicin group. Also, accumulation of filamentous structures in the sarcoplasma in some of the cells, structural changes in capillaries and an increase in collagen fibers forming bundles were observed. When melatonin was added to the doxorubicin treatment all structural changes were reduced. The cardiotoxic side effect of doxorubicin used as a chemotherapeutic agent and was probably developed as a result of supression of the antioxidant system and lipid peroxidation. Therefore, it could be assumed that the addition of melatonin in the treatment of doxorubicin could prevent the cardiotoxicity of doxorubicin.
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    Stretching molecular springs: elasticity of titin filaments in vertebrate striated muscle
    (F. Hernández y Juan F. Madrid. Universidad de Murcia: Departamento de Biología Celular e Histología, 2000) Linke, W. A.
    Titin, the giant protein of striated muscle, provides a continuous link between the Z-disk and the M-line of a sarcomere. The elastic I-band section of titin comprises two main structural elements, stretches of immunoglobulin-like domains and a unique sequence, the PEYK segment. Both elements contribute to the extensibility and passive force development of nonactivated muscle. Extensibility of the titin segments in skeletal muscle has been determined by immunof1uorescence/immunoelectron microscopy of sarcomeres stained with sequence-assigned titin antibodies. The force developed upon stretch of titin has been measured on isolated molecules or recombinant titin fragments with the help of optical tweezers and the atomic force microscope. Force has also been measured in single isolated myofibrils. The force-extension relation of titin could be readily fitted with models of biopolymer elasticity . For physiologically relevant extensions, the elasticity of the titin segments was largely explainable by an entropic-spring mechanism. The modelling explains why during stretch of titin, the Ig-domain regions (with folded modules) extend before the PEYK domain. In cardiac muscle, I-band titin is expressed in different isoforms, termed N2-A and N2-B. The N2-A isoform resembles that of skeletal muscle, whereas N2-B titin is shorter and is distinguished by cardiac-specific Ig-motifs and nonmodular sequences within the central I-band section . Examination of N2-B titin extensibility revealed that this isoform extends by recruiting three distinct elastic elements: poly-Ig regions and the PEYK domain at lower stretch and, in addition , a unique 572- residue sequence insertion at higher physiological stretch. Extension of all three elements allows cardiac titin to stretch fully reversibly at physiological sarcomere lengths, without the need to unfold individual Ig domains. However, unfolding of a very small number of Ig domains remains a possibility.
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    Telocytes in skeletal, cardiac and smooth muscle interstitium: morphological and functional aspects
    (Universidad de Murcia. Departamento de Biología Celular e Histología, 2018) Marini, Mirca; Rosa, Irene; iIbba Mannesch, Lidia; Manetti, Mirko
    Telocytes (TCs) represent a new distinct type of cells found in the stromal compartment of many organs, including the skeletal, cardiac and smooth muscles. TCs are morphologically defined as interstitial cells with a small cellular body from which arise very long (up to hundreds of micrometers) and thin moniliform processes (named telopodes) featuring the alternation of slender segments (called podomers) and small dilated portions (called podoms) accommodating some organelles. Although these stromal cells are mainly characterized by their ultrastructural traits, in the last few years TCs have been increasingly studied for their immunophenotypes, microRNA profiles, and gene expression and proteomic signatures. By their longdistance spreading telopodes, TCs build a threedimensional network throughout the whole stromal space and communicate with each other and neighboring cells through homocellular and heterocellular junctions, respectively. Moreover, increasing evidence suggests that TCs may exert paracrine functions being able to transfer genetic information and signaling molecules to other cells via the release of different types of extracellular vesicles. A close relationship between TCs and stem/progenitor cell niches has also been described in several organs. However, the specific functions of TCs located in the muscle interstitium remain to be unraveled. Here, we review the morphological and possible functional aspects of TCs in skeletal, cardiac and smooth muscle tissues. The potential involvement of TCs in muscle tissue pathological changes and future possibilities for targeting TCs as a novel promising therapeutic strategy to foster muscle tissue regeneration and repair are also discussed.

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