SiO2/hyaluronic acid nanoparticles carry CaO2, DOX and p53 plasmid to effectively achieve ion interference/chemical/gene multimodal therapy of lung cancer.

Monotherapy of lung cancer shows limited therapeutic effects due to its poorly targeted enrichment and low bioavailability. Using nanomaterials as carriers to form drug delivery systems has become a popular method to improve the targeting of anticancer drug therapy and patients' safety. However, the uniformity of the loaded drugs and the unsatisfactory effects are still the bottleneck in this field up to now. This study aims to construct a novel nanocomposite carrying 3 different types of anticancer drugs to enhance treatment efficacy. Herein, mesoporous silica (MSN) with high loading rate was constructed by dilute sulfuric acid thermal etching as the framework. Hyaluronic acid (HA) was loaded with CaO2, p53 and DOX to construct nanoparticle complexes-SiO2@CaO2@DOX@P53-HA. First, MSN was proved to be a porous sorbent with a mesoporous structure through BET analysis. The images obtained from the uptake experiment clearly show the gradual enrichment of the DOX and Ca2+ within the target cell. For in vitro experiments, the pro-apoptotic effects of SiO2@CaO2@DOX@P53-HA significantly increased compared to that of the single-agent group at different time points. Furthermore, in the tumor-bearing mouse experiment, the tumor volume was remarkably inhibited in the SiO2@CaO2@DOX@P53-HA group compared to that in the single-agent group. By observing the pathological sections of the euthanized mice, it is obvious that the tissues of the mice treated with the nanoparticles were more intact. Based on these beneficial results, it is believed that multimodal therapy is a meaningful treatment strategy for lung cancer.

Upregulation of ITGB6 in primary palmar hyperhidrosis.

BACKGROUND: The regulatory effect of integrin ß6 (ITGB6) on sweat gland cells in primary palmar hyperhidrosis (PPH) remains unclear. OBJECTIVES: This study investigated the involvement of ITGB6 in the pathogenesis of PPH. MATERIAL AND METHODS: Sweat gland tissues were collected from PPH patients and healthy volunteers. The expression levels of ITGB6 in sweat gland tissues were detected with quantitative polymerase chain reaction (qPCR), western blot and immunohistochemical staining. Sweat gland cells were extracted from PPH patients, and identified with immunofluorescence staining of CEA and CK7. The expression of aquaporin 5 (AQP5) and Na-K-Cl cotransporter 1 (NKCC1) in primary sweat gland cells that overexpress ITGB6 were also detected. Through a series of bioinformatic methods, differentially expressed genes in sweat gland tissues were examined and validated via comparing PPH samples and controls. The key proteins and biological functions enriched in PPH were determined using Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) analyses. RESULTS: The ITGB6 was upregulated in sweat gland tissues of PPH patients compared to that of healthy volunteers. The CEA and CK7 were positively expressed in sweat gland cells extracted from PPH patients. The overexpression of ITGB6 upregulated AQP5 and NKCC1 protein expression in the sweat gland cells of PPH patients. A total of 562 differentially expressed mRNAs were identified using high-throughput sequencing (394 upregulated, 168 downregulated), which were mainly active in the chemokine and Wnt signaling pathways. After verification with qPCR and western blot, the overexpression of ITGB6 significantly upregulated CXCL3, CXCL5, CXCL10, and CXCL11, and downregulated Wnt2 mRNA and protein expression in sweat gland cells. CONCLUSIONS: The ITGB6 is upregulated in PPH patients. It may be involved in the pathogenesis of PPH by upregulating AQP5, NKCC1, CXCL3, CXCL5, CXCL10, and CXCL11, and downregulating Wnt2 expression in sweat glands.

Antagonist of Chrna1 prevents the pathogenesis of primary focal hyperhidrosis.

BACKGROUND: Primary focal hyperhidrosis (PFH) is an autonomic neurological disease in which exocrine glands are oversecreted due to autonomic dysfunction of the sympathetic nervous system. Chrna1 promotes the pathogenesis of PFH. We aimed to check if downregulating of Chrna1 by cisatracurium could alleviate the symptoms of PFH. METHODS: The effect of cisatracurium in a hyperhidrosis mice model induced by pilocarpine hydrochloride was monitored for sweat gland secretion, and ultrastructural sweat secretory granules in sweat glands were analyzed. Meanwhile, markers of hyperhidrosis were checked, and release of Bdnf and Nrg1 from sympathetic ganglia axon was tested. Furthermore, the mechanism of cisatracurium function was evaluated in vitro using HEK293 expressing Chrna1. Finally, the effect of cisatracurium was determined in the hyperhidrosis mice model with overexpression or downregulation of Chrna1. RESULTS: In hyperhidrosis mice, pretreatment with cisatracurium effectively inhibited sweat secretion, along with fewer particle secretion in sweat glands. The molecular markers of hyperhidrosis (Aqp5 and Cacna1c) were inhibited by cisatracurium, acetylcholine (Ach) level in serum was found decreased. Neurotrophic factors (Bdnf and Nrg1) secreted by sympathetic axon activation were also inhibited. At last, it was confirmed that cisatracurium could not alter the gene or protein expression level of Chrna1, but could block the ion channel. Overexpression of Chrna1 abolished the effect of cisatracurium on hyperhidrosis, while cisatracurium could not function more in siChrna1-treated mice. CONCLUSION: Our results suggested that pretreatment of cisatracurium could alleviate hyperhidrosis in mice, probably through blocking the ion channel function of Chrna1.