Browsing by Author "Qiao, Li"
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Item Open Access An off-the-shelf artificial cardiac patch improves cardiac repair after myocardial infarction in rats and pigs.(Science translational medicine, 2020-04) Huang, Ke; Ozpinar, Emily W; Su, Teng; Tang, Junnan; Shen, Deliang; Qiao, Li; Hu, Shiqi; Li, Zhenhua; Liang, Hongxia; Mathews, Kyle; Scharf, Valery; Freytes, Donald O; Cheng, KeCell therapy has been a promising strategy for cardiac repair after injury or infarction; however, low retention and engraftment of transplanted cells limit potential therapeutic efficacy. Seeding scaffold material with cells to create cardiac patches that are transplanted onto the surface of the heart can overcome these limitations. However, because patches need to be freshly prepared to maintain cell viability, long-term storage is not feasible and limits clinical applicability. Here, we developed an off-the-shelf therapeutic cardiac patch composed of a decellularized porcine myocardial extracellular matrix scaffold and synthetic cardiac stromal cells (synCSCs) generated by encapsulating secreted factors from isolated human cardiac stromal cells. This fully acellular artificial cardiac patch (artCP) maintained its potency after long-term cryopreservation. In a rat model of acute myocardial infarction, transplantation of the artCP supported cardiac recovery by reducing scarring, promoting angiomyogenesis, and boosting cardiac function. The safety and efficacy of the artCP were further confirmed in a porcine model of myocardial infarction. The artCP is a clinically feasible, easy-to-store, and cell-free alternative to myocardial repair using cell-based cardiac patches.Item Open Access Biomimetics: Platelet-Inspired Nanocells for Targeted Heart Repair After Ischemia/Reperfusion Injury (Adv. Funct. Mater. 4/2019)(Advanced Functional Materials, 2019-01) Su, Teng; Huang, Ke; Ma, Hong; Liang, Hongxia; Dinh, Phuong‐Uyen; Chen, Justin; Shen, Deliang; Allen, Tyler A; Qiao, Li; Li, Zhenhua; Hu, Shiqi; Cores, Jhon; Frame, Brianna N; Young, Ashlyn T; Yin, Qi; Liu, Jiandong; Qian, Li; Caranasos, Thomas G; Brudno, Yevgeny; Ligler, Frances S; Cheng, KeItem Open Access Cardiac cell-integrated microneedle patch for treating myocardial infarction.(Science advances, 2018-11) Tang, Junnan; Wang, Jinqiang; Huang, Ke; Ye, Yanqi; Su, Teng; Qiao, Li; Hensley, Michael Taylor; Caranasos, Thomas George; Zhang, Jinying; Gu, Zhen; Cheng, KeWe engineered a microneedle patch integrated with cardiac stromal cells (MN-CSCs) for therapeutic heart regeneration after acute myocardial infarction (MI). To perform cell-based heart regeneration, cells are currently delivered to the heart via direct muscle injection, intravascular infusion, or transplantation of epicardial patches. The first two approaches suffer from poor cell retention, while epicardial patches integrate slowly with host myocardium. Here, we used polymeric MNs to create "channels" between host myocardium and therapeutic CSCs. These channels allow regenerative factors secreted by CSCs to be released into the injured myocardium to promote heart repair. In the rat MI model study, the application of the MN-CSC patch effectively augmented cardiac functions and enhanced angiomyogenesis. In the porcine MI model study, MN-CSC patch application was nontoxic and resulted in cardiac function protection. The MN system represents an innovative approach delivering therapeutic cells for heart regeneration.Item Open Access Circulating tumor cells exit circulation while maintaining multicellularity, augmenting metastatic potential.(Journal of cell science, 2019-09) Allen, Tyler A; Asad, Dana; Amu, Emmanuel; Hensley, M Taylor; Cores, Jhon; Vandergriff, Adam; Tang, Junnan; Dinh, Phuong-Uyen; Shen, Deliang; Qiao, Li; Su, Teng; Hu, Shiqi; Liang, Hongxia; Shive, Heather; Harrell, Erin; Campbell, Connor; Peng, Xinxia; Yoder, Jeffrey A; Cheng, KeMetastasis accounts for the majority of all cancer deaths, yet the process remains poorly understood. A pivotal step in the metastasis process is the exiting of tumor cells from the circulation, a process known as extravasation. However, it is unclear how tumor cells extravasate and whether multicellular clusters of tumor cells possess the ability to exit as a whole or must first disassociate. In this study, we use in vivo zebrafish and mouse models to elucidate the mechanism tumor cells use to extravasate. We found that circulating tumor cells exit the circulation using the recently identified extravasation mechanism, angiopellosis, and do so as both clusters and individual cells. We further show that when melanoma and cervical cancer cells utilize this extravasation method to exit as clusters, they exhibit an increased ability to form tumors at distant sites through the expression of unique genetic profiles. Collectively, we present a new model for tumor cell extravasation of both individual and multicellular circulating tumor cells.This article has an associated First Person interview with the first author of the paper.Item Open Access Mesenchymal Stem Cell/Red Blood Cell-Inspired Nanoparticle Therapy in Mice with Carbon Tetrachloride-Induced Acute Liver Failure.(ACS nano, 2018-07) Liang, Hongxia; Huang, Ke; Su, Teng; Li, Zhenhua; Hu, Shiqi; Dinh, Phuong-Uyen; Wrona, Emily A; Shao, Chen; Qiao, Li; Vandergriff, Adam C; Hensley, M Taylor; Cores, Jhon; Allen, Tyler; Zhang, Hongyu; Zeng, Qinglei; Xing, Jiyuan; Freytes, Donald O; Shen, Deliang; Yu, Zujiang; Cheng, KeAcute liver failure is a critical condition characterized by global hepatocyte death and often time needs a liver transplantation. Such treatment is largely limited by donor organ shortage. Stem cell therapy offers a promising option to patients with acute liver failure. Yet, therapeutic efficacy and feasibility are hindered by delivery route and storage instability of live cell products. We fabricated a nanoparticle that carries the beneficial regenerative factors from mesenchymal stem cells and further coated it with the membranes of red blood cells to increase blood stability. Unlike uncoated nanoparticles, these particles promote liver cell proliferation in vitro and have lower internalization by macrophage cells. After intravenous delivery, these artificial stem cell analogs are able to remain in the liver and mitigate carbon tetrachloride-induced liver failure in a mouse model, as gauged by histology and liver function test. Our technology provides an innovative and off-the-shelf strategy to treat liver failure.Item Open Access microRNA-21-5p dysregulation in exosomes derived from heart failure patients impairs regenerative potential.(The Journal of clinical investigation, 2019-04) Qiao, Li; Hu, Shiqi; Liu, Suyun; Zhang, Hui; Ma, Hong; Huang, Ke; Li, Zhenhua; Su, Teng; Vandergriff, Adam; Tang, Junnan; Allen, Tyler; Dinh, Phuong-Uyen; Cores, Jhon; Yin, Qi; Li, Yongjun; Cheng, KeExosomes, as functional paracrine units of therapeutic cells, can partially reproduce the reparative properties of their parental cells. The constitution of exosomes, as well as their biological activity, largely depends on the cells that secrete them. We isolated exosomes from explant-derived cardiac stromal cells from patients with heart failure (FEXO) or from normal donor hearts (NEXO) and compared their regenerative activities in vitro and in vivo. Patients in the FEXO group exhibited an impaired ability to promote endothelial tube formation and cardiomyocyte proliferation in vitro. Intramyocardial injection of NEXO resulted in structural and functional improvements in a murine model of acute myocardial infarction. In contrast, FEXO therapy exacerbated cardiac function and left ventricular remodeling. microRNA array and PCR analysis revealed dysregulation of miR-21-5p in FEXO. Restoring miR-21-5p expression rescued FEXO's reparative function, whereas blunting miR-21-5p expression in NEXO diminished its therapeutic benefits. Further mechanistic studies revealed that miR-21-5p augmented Akt kinase activity through the inhibition of phosphatase and tensin homolog. Taken together, the heart failure pathological condition altered the miR cargos of cardiac-derived exosomes and impaired their regenerative activities. miR-21-5p contributes to exosome-mediated heart repair by enhancing angiogenesis and cardiomyocyte survival through the phosphatase and tensin homolog/Akt pathway.Item Open Access Platelet-Inspired Nanocells for Targeted Heart Repair After Ischemia/Reperfusion Injury.(Advanced functional materials, 2019-01) Su, Teng; Huang, Ke; Ma, Hong; Liang, Hongxia; Dinh, Phuong-Uyen; Chen, Justin; Shen, Deliang; Allen, Tyler A; Qiao, Li; Li, Zhenhua; Hu, Shiqi; Cores, Jhon; Frame, Brianna N; Young, Ashlyn T; Yin, Qi; Liu, Jiandong; Qian, Li; Caranasos, Thomas G; Brudno, Yevgeny; Ligler, Frances S; Cheng, KeCardiovascular disease is the leading cause of mortality worldwide. While reperfusion therapy is vital for patient survival post-heart attack, it also causes further tissue injury, known as myocardial ischemia/reperfusion (I/R) injury in clinical practice. Exploring ways to attenuate I/R injury is of clinical interest for improving post-ischemic recovery. A platelet-inspired nanocell (PINC) that incorporates both prostaglandin E2 (PGE2)-modified platelet membrane and cardiac stromal cell-secreted factors to target the heart after I/R injury is introduced. By taking advantage of the natural infarct-homing ability of platelet membrane and the overexpression of PGE2 receptors (EPs) in the pathological cardiac microenvironment after I/R injury, the PINCs can achieve targeted delivery of therapeutic payload to the injured heart. Furthermore, a synergistic treatment efficacy can be achieved by PINC, which combines the paracrine mechanism of cell therapy with the PGE2/EP receptor signaling that is involved in the repair and regeneration of multiple tissues. In a mouse model of myocardial I/R injury, intravenous injection of PINCs results in augmented cardiac function and mitigated heart remodeling, which is accompanied by the increase in cycling cardiomyocytes, activation of endogenous stem/progenitor cells, and promotion of angiogenesis. This approach represents a promising therapeutic delivery platform for treating I/R injury.Item Open Access Tumor cell-derived exosomes home to their cells of origin and can be used as Trojan horses to deliver cancer drugs.(Theranostics, 2020-01) Qiao, Li; Hu, Shiqi; Huang, Ke; Su, Teng; Li, Zhenhua; Vandergriff, Adam; Cores, Jhon; Dinh, Phuong-Uyen; Allen, Tyler; Shen, Deliang; Liang, Hongxia; Li, Yongjun; Cheng, KeCancer is the second leading cause of death worldwide and patients are in urgent need of therapies that can effectively target cancer with minimal off-target side effects. Exosomes are extracellular nano-shuttles that facilitate intercellular communication between cells and organs. It has been established that tumor-derived exosomes contain a similar protein and lipid composition to that of the cells that secrete them, indicating that exosomes might be uniquely employed as carriers for anti-cancer therapeutics. Methods: We isolated exosomes from two cancer cell lines, then co-cultured each type of cancer cells with these two kinds of exosomes and quantified exosome. HT1080 or Hela exosomes were systemically injected to Nude mice bearing a subcutaneous HT1080 tumor to investigate their cancer-homing behavior. Moreover, cancer cell-derived exosomes were engineered to carry Doxil (a common chemotherapy drug), known as D-exo, were used to detect their target and therapeutic efficacy as anti-cancer drugs. Exosome proteome array analysis were used to reveal the mechanism underly this phenomenon. Results: Exosomes derived from cancer cells fuse preferentially with their parent cancer cells, in vitro. Systemically injected tumor-derived exosomes home to their original tumor tissues. Moreover, compared to Doxil alone, the drug-loaded exosomes showed enhanced therapeutic retention in tumor tissues and eradicated them more effectively in nude mice. Exosome proteome array analysis revealed distinct integrin expression patterns, which might shed light on the underlying mechanisms that explain the exosomal cancer-homing behavior. Conclusion: Here we demonstrate that the exosomes' ability to target the parent cancer is a phenomenon that opens up new ways to devise targeted therapies to deliver anti-tumor drugs.