[Research status of insect infestation of Chinese medicinal materials during storage].

During the storage process, Chinese medicinal materials are susceptible to insect infestation due to their own nature and external storage factors. Infestation by insects can have varying impacts on the materials. In mild cases, it affects the appearance and reduces consumer purchasing power, while in severe cases, it affects the quality, reduces medicinal value, and introduces impurities such as insect bodies, excrement, and secretions, resulting in significant contamination of the medicinal materials. This study reviewed the rele-vant factors influencing insect infestation in Chinese medicinal materials and the compositional changes that occur after infestation and summarized maintenance measures for preventing insect infestation. Additionally, it provided an overview of detection techniques applicable to identifying insect infestation during the storage of Chinese medicinal materials. During the storage process, insect infestation is the result of the combined effects of biological factors(source, species, and population density of insects), intrinsic factors(moisture, chemical composition, and metabolism), and environmental factors(temperature, relative humidity, and oxygen content). After infestation, there are significant changes in the content of constituents in the medicinal materials. By implementing strict pre-storage inspections, regular maintenance after storage, and appropriate storage and maintenance methods, the occurrence of insect infestation can be reduced, and the preservation rate of Chinese medicinal materials can be improved. The storage and maintenance of Chinese medicinal materials are critical for ensuring their quality. Through scientifically standardized storage and strict adherence to operational management standards, the risk of insect infestation can be minimized, thus guaranteeing the quality of Chinese medicinal materials.

[Aflatoxins and fungal community distribution during harvesting and processing of Platycladi Semen].

This study aimed to analyze aflatoxins content and fungal community distribution in the harvesting and processing of Platycladi Semen, and explore the key link that affects aflatoxins contamination. The related Platycladi Semen samples of different maturity periods(cone non-rupture period, early rupture, and complete rupture period) and different processing periods(before drying, during 2-d drying, during 7-d drying, before and after seed scale removal, before and after peeling, 1 d after color sorting, and 7 d after color sorting) were collected for identifying the fungal community composition on sample surface by ITS amplicon sequencing. Then the content of aflatoxins B_1, B_2, G_1 and G_2 was determined by HPLC-MS/MS. The results showed that during the harvesting of Platycladi Semen from cone non-rupture to complete rupture, aflatoxins were only detected in the seed scale and seed coat, with aflatoxin G_2 in the seed scale and aflatoxin B_1 in the seed coat. During the drying, with the prolongation of drying time, aflatoxins B_1 and G_2 were detected simultaneously in the seed scale, aflatoxin B_1 in the seed coat, and low-content aflatoxin B_1 in the seed kernel. During subsequent processing, the aflatoxin content in seed kernel during subsequent processing was slighted increased. As demonstrated by fungal detection, Aspergillus flavus was not present during the harvesting of Platycladi Semen, but present during the drying and processing. Its content in the seed coat during the drying process was relatively higher. In short, Platycladi Semen should be harvested as soon as possible after it becomes fully mature. Drying process is the key link of preventing aflatoxin contamination. It is advised to build a sunlight room or adopt similar settings, standardize the operations in other processes, and keep the surrounding environment clean to minimize aflatoxin contamination.

[Investigation and research on fungal diversity of Platycladi Semen on Chinese market].

In the process of harvesting, production and processing, storage, and transportation, the traditional Chinese medicine Platycladi Semen is prone to mildew due to its own and environmental factors, which can nourish the production of toxic or pathogenic fungi, and even produce mycotoxins, which affects the safety of clinical medication. The 2020 edition of Chinese Pharmacopoeia limits the highest standard of aflatoxin content in Platycladi Semen. However, there are few studies on the fungal contamination of Platycladi Semen, and it is difficult to prevent and control it in a targeted manner. Therefore, based on the Illumina NovaSeq6000 platform, this article uses ITS sequence amplicon technology to analyze the distribution and diversity of fungi in 27 batches of commercially available Platycladi Semen in the Chinese market. A total of 10 phyla, 35 classes, 93 orders, 193 families, 336 genera, and 372 species of fungi were identified in China. Among them, Aspergillus, Alternaria spp. were dominant, 20 batches of samples were detected for A. flavus, 10 batches of samples were detected for A. nidulans, and all samples were detected for potential pathogenic fungi such as A. fumigatus and A. niger. According to diversity analysis, the diversity of the fungal communities in the samples from Gansu province was high, the samples in Shandong province contain the largest number of fungal species, and the samples in Guangxi province had the lo-west diversity and the least number of species. In most samples, pathogenic fungi such as A. fumigatus, A. niger, A. flavus, A. parasiticus were detected in varying degrees. This study systematically investigated the fungal contamination of Platycladi Semen from the markets in the last link of the its industrial chain, and clarified the distribution of Platycladi Semen fungi, especially toxin-producing fungi, and provided theoretical basis for the targeted prevention and control of fungal contamination in Platycladi Semen.