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Cancer, one of the deadliest diseases caused by cells escaping homeostasis, abnormal proliferation, and abnormal differentiation, is fast becoming one of the most burdensome diseases of this century. With decades of human research and cognitive changes in cancer, cancer treatment is also developing rapidly, but there is still a lack of effective treatment and countermeasures. Especially, the search for safe, efficient, and non-toxic drugs has become a long-term goal in the field of cancer. Saponins extracted and separated from traditional Chinese medicine can improve cancer through various pathways and have almost no toxic side effects. Therefore, the research on the anti-cancer effect of saponins is heating up. It is found that saponins play anti-tumor roles by inhibiting proliferation, metastasis, and angiogenesis of cancer cells, promoting apoptosis of cancer cells, inducing autophagy of tumor cells, and regulating miRNA expression and immune functions. Chinese herbal medicine saponins can regulate secretory glycoprotein /β-catenin (Wnt/β-catenin), adenylate activated protein kinase (AMPK), nuclear transcription factor-κB (NF-κB), mitogen-activated protein kinase (MAPK), phosphatidylinositol 3-kinase (PI3K)/protein kinase B (Akt)/mammalian target of rapamycin (mTOR), Janus kinase/activator of signal transduction and transcription 3 (JAK/ STAT3), hypoxia-inducible factor-1α (HIF-1α), Toll-like receptor (TLR), and other related signaling pathways to get involved in the proliferation, metastasis, angiogenesis, apoptosis, autophagy, and other processes of cancer cells, thus interfering with the progression of cancer. Therefore, the focus of this review is to update the discovery and evaluation of Chinese herbal medicine saponins with anti-cancer properties, clarify their mechanism of action, including the progress of related signaling pathways, and deepen the understanding of the anti-cancer function of Chinese herbal medicine saponins, so as to provide a new perspective and direction for the prevention and treatment of tumors by traditional Chinese medicine and better promote the development and utilization of resources.
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Chronic cough is a common condition that imposes significant physical, psychological, and social burdens on patients. Although chronic cough is often associated with underlying conditions such as asthma, gastroesophageal reflux disease, and eosinophilic bronchitis, some patients experience uncontrollable coughing that is difficult to attribute to a specific cause. Many of these patients exhibit clinical features of cough hypersensitivity syndrome, providing new directions for research into the treatment of chronic cough. As the pathophysiological mechanisms of chronic cough are further elucidated, treatment approaches for chronic cough are entering a new stage of development. This article summarizes and discusses the mechanisms and clinical evidence of central neuromodulators used in the treatment of chronic cough, suggesting promising clinical applications for these drugs in the future.
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Chronic obstructive pulmonary disease (COPD) is the most common chronic airway disease. The current status of treatment based mainly on bronchodilators and ICS is not sufficient for all of COPD patients. Various studies have attempted to use biologics targeting specific cytokines and their receptors in COPD patients to alleviate respiratory symptoms or reduce the risk of acute exacerbations. However, they failed to bring significant clinical benefits. More studies are needed to further determine the efficacy of targeted biotherapy for COPD.
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OBJECTIVE:To identify Panax notoginseng and its processed products . METHODS :The fingerprint was established by HPLC. Using ginsenoside Rb 1 as reference ,HPLC fingerprints of 15 batches of P. notoginseng and its processed products were drawn and the similarity evaluation was conducted by using the Similarity Evaluation System for TCM Chromatographic Fingerprints(2012 edition). The common peaks were confirmed by comparing with substance control. SPSS 21.0 and SIMCA 14.1 software were used to perform cluster analysis ,principal component analysis and orthogonal partial least squares-discriminant analysis;taking the variable importance projection (VIP)value greater than 1 as the standard ,the differential marker components causing the quality difference between P. notoginseng and its processed products were screened. IR fingerprints of P. notoginseng and its processed products were established by OMNIC 8.2.0 software,and the spectral similarity was evaluated ;double index sequence analysis was used to analyze absorption peaks of IR fingerprints of 15 batches of P. notoginseng and its processed products. RESULTS :There were 16 common peaks in the fingerprints of 15 batches of P. notoginseng , and the similarities were 0.911-1.000;there were 25 common peaks in the fingerprints of processed products ,and the similaritieswere 0.862-1.000. They had 12 identical common peaks ,and wang668@sina.com three of them were ident ified as sanchinoside R 1,ginsenoside Rg1 and ginsenoside Rb 1. Results of cluster analysi s showed that when the distance was 10,15 batches of P. notoginseng could be clustered into two categories ,SW1-SW5 into one category ,SH1-SH5 and SQ 1-SQ5 into one category ,ZW1-ZW5,ZH1-ZH5 and ZQ1-ZQ5 of 15 batches of processed products could be clustered into one category. When the distance was 5,15 batches of P. notoginseng could be clustered into three categories ,SW1-SW5 into one category ,SH2-SH5 and SQ 2 into one category ,SQ1, SQ3-SQ5 and SH 1 into one category. Fifteen batches of processed products could be clustered into two categories ,ZW1-ZW5 into one category ,ZH1-ZH5 and ZQ 1-ZQ5 into one category. The results of principal component analysis showed that the cumulative variance contribution rate of the first two principal components was 80.104% . The results of orthogonal partial least squares-discriminant analysis showed that the VIP values of the five peaks were greater than 1,which were peak H ,peak G ,peak J,peak F (ginsenoside Rg 1)and peak I. The similarity of IR fingerprints of 15 batches of P. notoginseng and its processed products were 0.889 7-1.000 0 and 0.972 8-1.000 0;the common peak rates were 80%-100%,and the variation peak rates were 0-17.65% and 0-18.75%,respectively. By comparing the wave numbers of absorption peaks ,it was found that there were differences between P. notoginseng at 3 440 and 1 450 cm-1 and processed products at 1 530 and 575 cm-1. CONCLUSIONS :Established HPLC fingerprint and IR fingerprint have good similarity ,and could effectively distinguish P. notoginseng and its processed products. P. notoginseng and its processed products from different habitats have high common peak rate and low variation rate ,and their chemical components are different ;peak H ,peak G ,peak J ,ginsenoside Rg 1 and peak I are differential marker components causing the quality difference between P. notoginseng and processed products.