Nuclear radiation exposure events and tumor radiotherapy are highly susceptible to a range of psychological, physiological and other health problems, which can seriously affect patients' quality of life. It has been shown that 87.5 % of tumor patients are exposed to varying degrees of radiation injury during radiotherapy. The treatment of radiation injury (RI) in modern medicine is limited to drug therapy, cell therapy, etc. Among them, the most chemical drugs cause many adverse reactions including fatigue, nausea, vomiting, etc., and there are very few drugs dedicated to the treatment of RI. Traditional Chinese medicine (TCM) is a rich natural medicinal resource, which has a wide range of pharmacological activities, multiple targets of action and minimal toxic side effects. Many studies have demonstrated that TCM and its compound preparations have enormous potential in the treatment of radiation induced comprehensive diseases. However, TCM is limited in clinical application due to its slow onset of action, complex active ingredients, and low bioavailability. Therefore, the article reviews the application, molecular mechanisms, and new dosage forms of TCM in the prevention and treatment of RI. On this basis, we will focus on discussing the development advantages and application prospects of the combination of traditional Chinese and Western medicine to achieve highly efficient treatment of RI. This review aims to provide scientific and effective drug delivery strategies and basic theoretical support for the clinical effective treatment of RI with TCM, and further promote the innovative development of TCM.

ObjectiveTo investigate the effects of different cultivation modes on the yield of Gentiana crassicaulis and its microbial diversity and secondary metabolite content in the rhizosphere soil. MethodWith G. crassicaulis of different cultivation modes and its rhizosphere soil as the research objects， the composition of bacterial and fungal communities， dominant bacteria， and differential microorganisms in the rhizosphere soil were analyzed by high-throughput sequencing technology. HPLC was used to determine the content of iridoids in G. crassicaulis with different cultivation modes. ResultCompared with plastic film mulching， planting without mulch and intercropping of peony， white kidney bean， potato， and corn increased the yield of fresh products by 16.11%-17.68%， 22.48%-26.34%， 29.37%-32.19%， 34.82%-36.57%， and 35.34%-39.71%， respectively， and increased the yield of dry products by 19.75%-23.17%， 25.86%-29.32%， 30.18%-34.94%， 35.22%-39.87%， and 39.72%-43.73%. The total content of four iridoids， including gentiopicrin， loganic acid， sweroside， and swertiamarin， increased by 10.17%-37.83%， 5.93%-47.44%， 9.09%-28.84%， and 10.71%-28.57%， respectively. The diversity of bacterial and fungal communities in the rhizosphere soil increased significantly （P<0.05）. The relative abundance of pathogenic bacteria such as Sordariomycetes， Leotiomycetes， Tremellomycetes， Eurotiomycetes， Fusarium， and Cladophialophora decreased， and the proportions of beneficial bacteria such as Proteobacteria， Acidobacteria， and Actinobacteriota increased and they gradually became the dominant bacteria. ConclusionDifferent cultivation modes can affect the yield of G. crassicaulis and its microbial diversity and iridoid content in the rhizosphere soil. Cultivation without mulch and intercropping patterns have certain advantages， which can provide theoretical references for the planting of G. crassicaulis.

In the microscale, bacteria with helical body shapes have been reported to yield advantages in many bio-processes. In the human society, there are also wisdoms in knowing how to recognize and make use of helical shapes with multi-functionality. Herein, we designed atypical chiral mesoporous silica nano-screws (CMSWs) with ideal topological structures (e.g., small section area, relative rough surface, screw-like body with three-dimension chirality) and demonstrated that CMSWs displayed enhanced bio-adhesion, mucus-penetration and cellular uptake (contributed by the macropinocytosis and caveolae-mediated endocytosis pathways) abilities compared to the chiral mesoporous silica nanospheres (CMSSs) and chiral mesoporous silica nanorods (CMSRs), achieving extended retention duration in the gastrointestinal (GI) tract and superior adsorption in the blood circulation (up to 2.61- and 5.65-times in AUC). After doxorubicin (DOX) loading into CMSs, DOX@CMSWs exhibited controlled drug release manners with pH responsiveness in vitro. Orally administered DOX@CMSWs could efficiently overcome the intestinal epithelium barrier (IEB), and resulted in satisfactory oral bioavailability of DOX (up to 348%). CMSWs were also proved to exhibit good biocompatibility and unique biodegradability. These findings displayed superior ability of CMSWs in crossing IEB through multiple topological mechanisms and would provide useful information on the rational design of nano-drug delivery systems.