Browsing by Author "Wu, Xiaobo"

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    Detection, Isolation and Quantification of Myocardial Infarct with Four Different Histological Staining Techniques
    Wu, Xiaobo; Meier, Linnea; Liu, Tom X.; Toldo, Stefano; Poelzing, Steven; Gourdie, Robert G. (MDPI, 2024-10-18)
    Background/Objectives: The precise quantification of myocardial infarction is crucial for evaluating therapeutic strategies. We developed a robust, color-based semi-automatic algorithm capable of infarct region detection, isolation and quantification with four different histological staining techniques, and of the isolation and quantification of diffuse fibrosis in the heart. Methods: Our method is developed based on the color difference in the infarct and non-infarct regions after histological staining. Mouse cardiac tissues stained with Masson’s trichrome (MTS), hematoxylin and eosin (H&E), 2,3,5-Triphenyltetrazolium chloride and picrosirius red were included to demonstrate the performance of our method. Results: We demonstrate that our algorithm can effectively identify and produce a clear visualization of infarct tissue in the four staining techniques. Notably, the infarct region on an H&E-stained tissue section can be clearly visualized after processing. The MATLAB-based program we developed holds promise for infarct quantification. Additionally, our program can isolate and quantify diffuse fibrotic elements from an MTS-stained cardiac section, which suggests the algorithm’s potential for evaluating pathological cardiac fibrosis in diseased cardiac tissues. Conclusions: We demonstrate that this color-based algorithm is capable of accurately identifying, isolating and quantifying cardiac infarct regions with different staining techniques, as well as diffuse and patchy fibrosis in MTS-stained cardiac tissues.
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    The role of the perinexus in Long QT Syndrome Type 3
    Wu, Xiaobo (Virginia Tech, 2023-02-13)
    Gain of function of cardiac voltage-gated sodium channel (Nav1.5) leads to Long QT Syndrome Type 3 (LQT3). LQT3 phenotype can be exacerbated by expanding the perinexus, which is an intercellular nanodomain with high density of Nav1.5 in the intercalated disc. Following this finding, we found that elevating extracellular sodium and widening the perinexus synergistically exacerbated LQT3 phenotype, Importantly, we also found that perinexal expansion increases the susceptibility to cardiac arrest in aged LQT3, which demonstrated that perinexal expansion is an arrhythmogenic risk especially in aged LQT3 patients. Furthermore, we observed that the perinexus narrows with aging and conceals LQT3 phenotype, which suggests that perinexal narrowing may have a cardio-protective role during aging in LQT3. Surprisingly, following the finding of the synergistic effect of extracellular sodium elevation and perinexal widening on LQT3 phenotype in drug-induced LQT3 guinea pig hearts, we found that this synergistic effect was not observed in genetically-modified LQT3 mouse hearts, which is due to high sodium also increasing transient outward potassium current (Ito). In summary, the whole project investigated the role of the perinexus in LQT3 from different conditions including sodium, aging and species. The findings in this project discovered the importance of perinexal expansion in LQT3 and also the involvement of Ito in sodium regulating LQT3 phenotype in hearts which functionally express Ito channels. Therefore, a LQT3 animal model which has similar electrophysiology close to human may be a great option for translational purpose.