Browsing by Author "Wang, Hai"
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Item Bioinspired One Cell Culture Isolates Highly Tumorigenic and Metastatic Cancer Stem Cells Capable of Multilineage Differentiation(Wiley, 2020-04-28) Wang, Hai; Agarwal, Pranay; Jiang, Bin; Stewart, Samantha; Liu, Xuanyou; Liang, Yutong; Hancioglu, Baris; Webb, Amy; Fisher, John P.; Liu, Zhenguo; Lu, Xiongbin; Tkaczuk, Katherine H. R.; He, Xiaoming; Medical and Molecular Genetics, School of MedicineItem Carbon nano-onion-mediated dual targeting of P-selectin and P-glycoprotein to overcome cancer drug resistance(Springer Nature, 2021-01-12) Wang, Hai; Liang, Yutong; Yin, Yue; Zhang, Jie; Su, Wen; White, Alisa M.; Jiang, Bin; Xu, Jiangsheng; Zhang, Yuntian; Stewart, Samantha; Lu, Xiaongbin; He, Xiaoming; Medical and Molecular Genetics, School of MedicineThe transmembrane P-glycoprotein (P-gp) pumps that efflux drugs are a major mechanism of cancer drug resistance. They are also important in protecting normal tissue cells from poisonous xenobiotics and endogenous metabolites. Here, we report a fucoidan-decorated silica-carbon nano-onion (FSCNO) hybrid nanoparticle that targets tumor vasculature to specifically release P-gp inhibitor and anticancer drug into tumor cells. The tumor vasculature targeting capability of the nanoparticle is demonstrated using multiple models. Moreover, we reveal the superior light absorption property of nano-onion in the near infrared region (NIR), which enables triggered drug release from the nanoparticle at a low NIR power. The released inhibitor selectively binds to P-gp pumps and disables their function, which improves the bioavailability of anticancer drug inside the cells. Furthermore, free P-gp inhibitor significantly increases the systemic toxicity of a chemotherapy drug, which can be resolved by delivering them with FSCNO nanoparticles in combination with a short low-power NIR laser irradiation.Item Correction to Overcoming Ovarian Cancer Drug Resistance with a Cold Responsive Nanomaterial(American Chemical Society, 2021) Wang, Hai; Agarwal, Pranay; Zhao, Gang; Ji, Guang; Jewell, Christopher M.; Fisher, John P.; Lu, Xiongbin; He, Xiaoming; Medicine, School of Medicine[This corrects the article DOI: 10.1021/acscentsci.8b00050.].Item Enhanced cancer therapy with cold-controlled drug release and photothermal warming enabled by one nanoplatform(Elsevier, 2018-10) Wang, Hai; Agarwal, Pranay; Liang, Yutong; Xu, Jiangsheng; Zhao, Gang; Tkaczuk, Katherine H. R.; Lu, Xiongbin; He, Xiaoming; Medical and Molecular Genetics, School of MedicineStimuli-responsive nanoparticles hold great promise for drug delivery to improve the safety and efficacy of cancer therapy. One of the most investigated stimuli-responsive strategies is to induce drug release by heating with laser, ultrasound, or electromagnetic field. More recently, cryosurgery (also called cryotherapy and cryoablation), destruction of diseased tissues by first cooling/freezing and then warming back, has been used to treat various diseases including cancer in the clinic. Here we developed a cold-responsive nanoparticle for controlled drug release as a result of the irreversible disassembly of the nanoparticle when cooled to below ∼10 °C. Furthermore, this nanoparticle can be used to generate localized heating under near infrared (NIR) laser irradiation, which can facilitate the warming process after cooling/freezing during cryosurgery. Indeed, the combination of this cold-responsive nanoparticle with ice cooling and NIR laser irradiation can greatly augment cancer destruction both in vitro and in vivo with no evident systemic toxicity.Item Overcoming Ovarian Cancer Drug Resistance with a Cold Responsive Nanomaterial(American Chemical Society, 2018-05-23) Wang, Hai; Agarwal, Pranay; Zhao, Gang; Ji, Guang; Jewell, Christopher M.; Fisher, John P.; Lu, Xiongbin; He, Xiaoming; Medical and Molecular Genetics, School of MedicineDrug resistance due to overexpression of membrane transporters in cancer cells and the existence of cancer stem cells (CSCs) is a major hurdle to effective and safe cancer chemotherapy. Nanoparticles have been explored to overcome cancer drug resistance. However, drug slowly released from nanoparticles can still be efficiently pumped out of drug-resistant cells. Here, a hybrid nanoparticle of phospholipid and polymers is developed to achieve cold-triggered burst release of encapsulated drug. With ice cooling to below ∼12 °C for both burst drug release and reduced membrane transporter activity, binding of the drug with its target in drug-resistant cells is evident, while it is minimal in the cells kept at 37 °C. Moreover, targeted drug delivery with the cold-responsive nanoparticles in combination with ice cooling not only can effectively kill drug-resistant ovarian cancer cells and their CSCs in vitro but also destroy both subcutaneous and orthotopic ovarian tumors in vivo with no evident systemic toxicity.Item Precise targeting of POLR2A as a therapeutic strategy for human triple negative breast cancer(Springer Nature, 2019-04) Xu, Jiangsheng; Liu, Yunhua; Li, Yujing; Wang, Hai; Stewart, Samantha; Van der Jeught, Kevin; Agarwal, Pranay; Zhang, Yuntian; Liu, Sheng; Zhao, Gang; Wan, Jun; Lu, Xiongbin; He, Xiaoming; Medical and Molecular Genetics, School of MedicineTP53 is the most frequently mutated or deleted gene in triple negative breast cancer (TNBC). Both the loss of TP53 and the lack of targeted therapy are significantly correlated with poor clinical outcomes, making TNBC the only type of breast cancer that has no approved targeted therapies. Through in silico analysis, we identified POLR2A in the TP53-neighbouring region as a collateral vulnerability target in TNBC tumours, suggesting that its inhibition via small interfering RNA (siRNA) may be an amenable approach for TNBC targeted treatment. To enhance bioavailability and improve endo/lysosomal escape of siRNA, we designed pH-activated nanoparticles for augmented cytosolic delivery of POLR2A siRNA (siPol2). Suppression of POLR2A expression with the siPol2-laden nanoparticles leads to enhanced growth reduction of tumours characterized by hemizygous POLR2A loss. These results demonstrate the potential of the pH-responsive nanoparticle and the precise POLR2A targeted therapy in TNBC harbouring the common TP53 genomic alteration.Item Targeted Heating of Mitochondria Greatly Augments Nanoparticle-Mediated Cancer Chemotherapy(Wiley, 2020-07) Xu, Jiangsheng; Shamul, James G; Wang, Hai; Lin, John; Agarwal, Pranay; Sun, Mingrui; Lu, Xiongbin; Tkaczuk, Katherine H.R.; He, Xiaoming; Medical and Molecular Genetics, School of MedicineCancer is the second leading cause of mortality globally. Various nanoparticles have been developed to improve the efficacy and safety of chemotherapy, photothermal therapy, and their combination for treating cancer. However, most of the existing nanoparticles are low in both subcellular precision and drug loading content (<≈5%), and the effect of targeted heating of subcellular organelles on the enhancement of chemotherapy has not been well explored. Here, a hybrid Py@Si-TH nanoparticle is reported to first target cancer cells overexpressed with the variant CD44 via its natural ligand HA on the outermost surface of the nanoparticle before cellular uptake, and then target mitochondria after they are taken up inside cells. In addition, the nanoparticle is ultraefficient for encapsulating doxorubicin hydrochloride (DOX) to form Py@Si-TH-DOX nanoparticle. The encapsulation efficiency is ≈100% at the commonly used low feeding ratio of 1:20 (DOX:empty nanoparticle), and >80% at an ultrahigh feeding ratio of 1:1. In combination with near infrared (NIR, 808 nm) laser irradiation, the tumor weight in the Py@Si-TH-DOX treatment group is 8.5 times less than that in the Py@Si-H-DOX (i.e., DOX-laden nanoparticles without mitochondrial targeting) group, suggesting targeted heating of mitochondria is a valuable strategy for enhancing chemotherapy to combat cancer.Item Targeted production of reactive oxygen species in mitochondria to overcome cancer drug resistance(Nature Publishing Group, 2018-02-08) Wang, Hai; Gao, Zan; Liu, Xuanyou; Agarwal, Pranay; Zhao, Shuting; Conroy, Daniel W.; Ji, Guang; Yu, Jianhua; Jaroniec, Christopher P.; Liu, Zhenguo; Lu, Xiongbin; Li, Xiaodong; He, Xiaoming; Medical and Molecular Genetics, School of MedicineMultidrug resistance is a major challenge to cancer chemotherapy. The multidrug resistance phenotype is associated with the overexpression of the adenosine triphosphate (ATP)-driven transmembrane efflux pumps in cancer cells. Here, we report a lipid membrane-coated silica-carbon (LSC) hybrid nanoparticle that targets mitochondria through pyruvate, to specifically produce reactive oxygen species (ROS) in mitochondria under near-infrared (NIR) laser irradiation. The ROS can oxidize the NADH into NAD+ to reduce the amount of ATP available for the efflux pumps. The treatment with LSC nanoparticles and NIR laser irradiation also reduces the expression and increases the intracellular distribution of the efflux pumps. Consequently, multidrug-resistant cancer cells lose their multidrug resistance capability for at least 5 days, creating a therapeutic window for chemotherapy. Our in vivo data show that the drug-laden LSC nanoparticles in combination with NIR laser treatment can effectively inhibit the growth of multidrug-resistant tumors with no evident systemic toxicity