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Your search keyword '"Zhang, Jianying"' showing total 17 results
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17 results on '"Zhang, Jianying"'

1. Metformin lotion promotes scarless skin tissue formation through AMPK activation, TGF-β1 inhibition, and reduced myofibroblast numbers.

Author

Zhang, Jianying, Shimozaki, Kengo, Hattori, Soichi, Pastukh, Vasyl, Maloney, Derek, Hogan, MaCalus V., and Wang, James H-C.

Subjects
*LABORATORY rats, *SCARS, *AMP-activated protein kinases, *SKIN regeneration, *CELL nuclei, *WOUND healing
Abstract

Scar tissue formation following skin wound healing is a challenging public health problem. Skin regeneration and preventing the formation of scar tissue by currently available commercial products are largely ineffective. This study aimed to test the efficacy of a novel topical metformin lotion (ML) in inhibiting scar tissue formation during skin wound healing in rats and to determine the mechanisms of action involved. A 6% ML was prepared in our laboratory. A skin wound healing model in rats was used. The wounded rats were divided into two groups and treated daily for 10 days as follows: Group 1 received a daily application of 50 mg of control lotion, or 0% ML (totaling 100 mg of lotion per rat), and Group 2 received a daily application of 50 mg of 6% ML (totaling 100 mg of 6% ML per rat). Blood samples from the heart of each rat were analyzed for inflammatory markers, HMGB1 and IL-1β, using ELISA, and immunological and histological analyses were performed on skin tissue sections. ML decreased levels of inflammatory markers HMGB1 and IL-1β in the serum of rats and inhibited the release of HMGB1 from cell nuclei into the skin tissue matrix. Additionally, ML demonstrated anti-fibrotic properties by enhancing AMPK activity, decreasing the expression of TGF-β1, reducing the number of myofibroblasts, decreasing the production of collagen III, and increasing the expression of collagen I. ML promotes the regeneration of high-quality skin during wound healing by reducing scar tissue formation. This effect is mediated through the activation of AMPK, inhibition of TGF-β1, and a decrease in the number of myofibroblasts. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Impact of Pre-Analytical Variables on Cancer Targeted Gene Sequencing Efficiency

Author

Araujo, Luiz H., primary, Timmers, Cynthia, additional, Shilo, Konstantin, additional, Zhao, Weiqiang, additional, Zhang, Jianying, additional, Yu, Lianbo, additional, Natarajan, Thanemozhi G., additional, Miller, Clinton J., additional, Yilmaz, Ayse Selen, additional, Liu, Tom, additional, Amann, Joseph, additional, Lapa e Silva, José Roberto, additional, Ferreira, Carlos Gil, additional, and Carbone, David P., additional

Published
2015
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10. Androgen Receptor Status Is a Prognostic Marker in Non-Basal Triple Negative Breast Cancers and Determines Novel Therapeutic Options

Author

Gasparini, Pierluigi, primary, Fassan, Matteo, additional, Cascione, Luciano, additional, Guler, Gulnur, additional, Balci, Serdar, additional, Irkkan, Cigdem, additional, Paisie, Carolyn, additional, Lovat, Francesca, additional, Morrison, Carl, additional, Zhang, Jianying, additional, Scarpa, Aldo, additional, Croce, Carlo M., additional, Shapiro, Charles L., additional, and Huebner, Kay, additional

Published
2014
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16. Prostaglandin E2 (PGE2) Exerts Biphasic Effects on Human Tendon Stem Cells.

Author

Zhang, Jianying and Wang, James H-C.

Subjects
*DINOPROSTONE, *BIPHASIC insulin, *STEM cells, *CELL culture, *PROGENITOR cells, *CELL proliferation, *GENETIC markers, TREATMENT of musculoskeletal system diseases
Abstract

Prostaglandin E2 (PGE2) has been reported to exert different effects on tissues at low and high levels. In the present study, cell culture experiments were performed to determine the potential biphasic effects of PGE2 on human tendon stem/progenitor cells (hTSCs). After treatment with PGE2, hTSC proliferation, stemness, and differentiation were analyzed. We found that high concentrations of PGE2 (>1 ng/ml) decreased cell proliferation and induced non-tenocyte differentiation. However, at lower concentrations (<1 ng/ml), PGE2 markedly enhanced hTSC proliferation. The expression levels of stem cell marker genes, specifically SSEA-4 and Stro-1, were more extensive in hTSCs treated with low concentrations of PGE2 than in cells treated with high levels of PGE2. Moreover, high levels of PGE2 induced hTSCs to differentiate aberrantly into non-tenocytes, which was evident by the high levels of PPARγ, collagen type II, and osteocalcin expression in hTSCs treated with PGE2 at concentrations >1 ng/ml. The findings of this study reveal that PGE2 can exhibit biphasic effects on hTSCs, indicating that while high PGE2 concentrations may be detrimental to tendons, low levels of PGE2 may play a vital role in the maintenance of tendon homeostasis in vivo. [ABSTRACT FROM AUTHOR]

Published
2014
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17. The Effects of Mechanical Loading on Tendons - An In Vivo and In Vitro Model Study.

Author

Zhang, Jianying and Wang, James H-C.

Subjects
*TENDONS, *PATHOLOGICAL physiology, *GROWTH factors, *MUSCULOSKELETAL system, *BIOMECHANICS, *BIOPHYSICS, *IN vitro studies, *ANIMAL models in research
Abstract

Mechanical loading constantly acts on tendons, and a better understanding of its effects on the tendons is essential to gain more insights into tendon patho-physiology. This study aims to investigate tendon mechanobiological responses through the use of mouse treadmill running as an in vivo model and mechanical stretching of tendon cells as an in vitro model. In the in vivo study, mice underwent moderate treadmill running (MTR) and intensive treadmill running (ITR) regimens. Treadmill running elevated the expression of mechanical growth factors (MGF) and enhanced the proliferative potential of tendon stem cells (TSCs) in both patellar and Achilles tendons. In both tendons, MTR upregulated tenocyte-related genes: collagen type I (Coll. I ∼10 fold) and tenomodulin (∼3–4 fold), but did not affect non-tenocyte-related genes: LPL (adipocyte), Sox9 (chondrocyte), Runx2 and Osterix (both osteocyte). However, ITR upregulated both tenocyte (Coll. I ∼7–11 fold; tenomodulin ∼4–5 fold) and non-tenocyte-related genes (∼3–8 fold). In the in vitro study, TSCs and tenocytes were stretched to 4% and 8% using a custom made mechanical loading system. Low mechanical stretching (4%) of TSCs from both patellar and Achilles tendons increased the expression of only the tenocyte-related genes (Coll. I ∼5–6 fold; tenomodulin ∼6–13 fold), but high mechanical stretching (8%) increased the expression of both tenocyte (Coll. I ∼28–50 fold; tenomodulin ∼14–48 fold) and non-tenocyte-related genes (2–5-fold). However, in tenocytes, non-tenocyte related gene expression was not altered by the application of either low or high mechanical stretching. These findings indicate that appropriate mechanical loading could be beneficial to tendons because of their potential to induce anabolic changes in tendon cells. However, while excessive mechanical loading caused anabolic changes in tendons, it also induced differentiation of TSCs into non-tenocytes, which may lead to the development of degenerative tendinopathy frequently seen in clinical settings. [ABSTRACT FROM AUTHOR]

Published
2013
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