Your search keyword '"Wencheng Jiao"' showing total 3 results

1. Oral Curcumin–Thioketal–Inulin Conjugate Micelles against Radiation–Induced Enteritis

Author

Jintao Shen, Wencheng Jiao, Bochuan Yuan, Hua Xie, Ziyuan Chen, Meng Wei, Yingbao Sun, Yanping Wu, Feng Zhang, Zhangyu Li, Xu Jin, Lina Du, and Yiguang Jin

Subjects

curcumin, micelles, radioprotection, radiation enteritis, Therapeutics. Pharmacology, RM1-950

Abstract

Radiation–induced enteritis is an unavoidable complication associated with pelvic tumor radiotherapy, significantly influencing the prognosis of cancer patients. The limited availability of commercial gastrointestinal radioprotectors in clinical settings poses a substantial challenge in preventing radiation enteritis. Despite the inherent radioprotective characteristics of Cur in vitro, its poor solubility in water, instability, and low bioavailability lead to inferior therapeutic effects in vivo. Herein, we developed novel ROS-responsive micelles (CTI) from inulin and curcumin, aimed at mitigating radiation enteritis. CTI micelles had excellent solubility and stability. Importantly, CTI improved the cytotoxicity and bioavailability of curcumin, thereby showing enhanced effectiveness in neutralizing ROS induced by radiation, safeguarding against DNA damage, and reducing radiation-induced cellular mortality. Moreover, in a radiation enteritis mice model, CTI not only alleviated severe radiation-induced intestinal injury but also improved redox-related indicators and reduced inflammatory cytokine expression. Furthermore, CTI effectively increased gut microbiota abundance and maintained gut homeostasis. In conclusion, CTI could be a promising candidate for the clinical management of radiation enteritis. Our study provides a new perspective for radioprotection using natural antioxidants.

Published

2024

2. Quercetin inclusion complex gels ameliorate radiation-induced brain injury by regulating gut microbiota

Author

Jinglu Hu, Wencheng Jiao, Ziyan Tang, Chunqing Wang, Qi Li, Meng Wei, Shiyong Song, Lina Du, and Yiguang Jin

Subjects

Quercetin, Inclusion complex, Gel, Radiation-induced brain injury, Gut microbiota, Microbiota-gut-brain axis, Therapeutics. Pharmacology, RM1-950

Abstract

Radiation-induced brain injury (RIBI) is a serious adverse effect of radiotherapy. RIBI has garnered considerable clinical attention owing to its powerful effects on brain function and cognition; however, no effective treatment is available. The microbiota–gut–brain axis theory is a novel concept of treating RIBI by regulating gut microbiota. Quercetin, a particularly common flavonoid compound, has a wide range of biological activities and can regulate gut microbiota; however, it has poor solubility and dispersibility. In the present study, oral gels of inclusion complex comprising quercetin and HP-β-CD were prepared, which increased quercetin dispersion and extended its release time in the intestinal tract. First, the relative abundance and diversity of gut microbiota in RIBI mice changed after oral administration of quercetin inclusion complex gels (QICG). Second, the spontaneous activity behavior and short-term memory ability as well as anxiety level were improved. Third, changes in physical symptoms were observed, including a decrease in TNF-α and IL-6 levels. H&E staining revealed that gut epithelial injury and intestinal inflammation as well as hippocampal inflammation were ameliorated. Antibiotics treatment (Abx) mice were developed to disrupt the mice's original gut microbiota composition. No significant improvement was observed in behavior or histopathology after oral administration of QICG in Abx mice of RIBI, indicating that the effect of QICG on improving RIBI was regulated by intestinal microbiota. Finally, the QICG preparation is efficient, exerting a protective effect on RIBI by regulating gut microbiota via the microbiota–gut–brain axis, which provides a novel idea for RIBI treatment.

Published

2023

3. Cinnarizine dissolving microneedles against microwave-induced brain injury

Author

Yuanyuan Zhang, Qian Li, Chunqing Wang, Lin Zhu, Furun Wang, Wencheng Jiao, Xiaomei Zhuang, Fei Xie, Lina Du, and Yiguang Jin

Subjects

Brain injury, Microwave, Microneedle, Cinnarizine, Polyvinylpyrrolidone K90, Brain targeting, Therapeutics. Pharmacology, RM1-950

Abstract

Microwave is commonly used in the life, manufacturing and military fields, which may induce body injuries. Brain is the major target organ of microwave radiation and microwave-induced brain injury (MIBI) can lead to insomnia, dreaminess, and a decline in learning and memory. However, there is no clinical medications are available currently. Calcium channel blockers may protect the brain tissue from microwave but most of them cannot enter the brain. Here, we selected a calcium channel blocker-cinnarizine to prepare its dissolving microneedles (MNs) for the therapy of MIBI. The cinnarizine MNs was composed of polyvinyl pyrrolidone (PVP) K90 as the tip, the photopolymerized PVP as the base and the drug, which owned high mechanical strength, leading to easily piecing the skin on the neck and high drug release in vivo. The cinnarizine MNs markedly improved the recovery of spatial memory and spontaneous exploratory behavior of the rats after microwave radiation by inhibiting the expression of calcineurin and calpain-1. The dissolving MN technique is a promising method to improve drugs into the body and perform the anti-microwave radiation action.

Published

2022