Schaefermejer6979

We found that METD decreases COL1α1-mRNA, α-SMA, and TIMP1 protein expression in LX2 cells treated with and TGF-β. This treatment also decreases MFN2 and TIMP1 protein expression and induces overexpression of MMP2-mRNA.

Our results suggest that a methanolic extract of Turnera diffusa is associated with an antifibrotic effect by decreasing profibrotic and mitochondrial markers together with the possible induction of apoptosis through SNAI1 expression in activated HSC cells.

Our results suggest that a methanolic extract of Turnera diffusa is associated with an antifibrotic effect by decreasing profibrotic and mitochondrial markers together with the possible induction of apoptosis through SNAI1 expression in activated HSC cells.Melanoma anti-tumor therapy remains a challenge. SiRNA-based therapies provide a powerful means, but limitations remain in its pharmaceutical applications owing to the lack of highly efficient delivery systems. In this study, to improve the siRNA delivery efficiency of chitooligosaccharide (COS), phenylboronic acid (PBA)-modified COS was synthesized and structurally characterized. PBA-modified COS was used to deliver survivin-targeted siRNA for melanoma treatment. The siRNA-loaded nanoparticles were prepared by a synergetic assembly of electrostatic complexation and chemical cross-linking. The particle size and zeta potential were characterized by dynamic light scattering, and transmission electron microscopy was utilized to observe the morphology of the nanoparticles. The cellular uptake of nanoparticles on B16F10 cells was studied by flow cytometry and confocal laser scanning microscopy. A luciferase reporter gene assay determined the gene silencing efficiency of different nanoparticles. As a result, the novel nanoparticles remarkably inhibited the proliferation of B16F10 cells in vitro and significantly inhibited the growth and metastasis of melanoma in vivo. In conclusion, PBA-modified COS can serve as a promising carrier for siRNA delivery in the field of anti-tumor therapy.

Bencycloquidium bromide (BCQB) is a novel inhaled anticholinergic bronchodilator with high selectivity for muscarinic M3 receptor. BCQB's potential utility of for therapy in Chronic obstructive pulmonary disease (COPD) has been indicated in pre-clinical studies.

To investigate the initial safety, tolerability and pharmacokinetics of BCQB delivered via pressurised Metered Dose Inhaler (pMDI) in healthy subjects.

This study consisted of single-ascending-dose (SAD), multiple-ascending-dose (MAD) tolerability study periods, and single- plus multiple-dose pharmacokinetic study periods. Randomized, double-blind, placebo-controlled, dose-escalating tolerability and pharmacokinetic studies were conducted. Seventy-two healthy subjects were assigned 31 (BCQB placebo) to 7 single-dose cohorts (125, 250, 500, 750, 1125, 1500 and 2000 μg) and 2 multiple-dose cohorts (1500 μg/d and 2000 μg/d). In the pharmacokinetic periods, 12 subjects were allocated three-way crossover to receive single dose of 250, 750 or 2000 μg files of BCQB inhalation, and could enable further clinical development in COPD patients.

The results of our study provided the initial safety, tolerability and pharmacokinetic profiles of BCQB inhalation, and could enable further clinical development in COPD patients.Small cell lung cancer (SCLC) is a particular subtype of lung cancer with high mortality. Recent advances in understanding SCLC genomics and breakthroughs of immunotherapy have substantially expanded existing knowledge and treatment modalities. However, challenges associated with SCLC remain enigmatic and elusive. Most of the conventional drug discovery approaches targeting altered signaling pathways in SCLC end up in the 'grave-yard of drug discovery', which mandates exploring novel approaches beyond inhibiting cell signaling pathways. Epigenetic modifications have long been documented as the key contributors to the tumorigenesis of almost all types of cancer, including SCLC. The last decade witnessed an exponential increase in our understanding of epigenetic modifications for SCLC. The present review highlights the central role of epigenetic regulations in acquiring neoplastic phenotype, metastasis, aggressiveness, resistance to chemotherapy, and immunotherapeutic approaches of SCLC. Different types of epigenetic modifications (DNA/histone methylation or acetylation) that can serve as predictive biomarkers for prognostication, treatment stratification, neuroendocrine lineage determination, and development of potential SCLC therapies are also discussed. We also review the utility of epigenetic targets/epidrugs in combination with first-line chemotherapy and immunotherapy that are currently under investigation in preclinical and clinical studies. Altogether, the information presents the inclusive landscape of SCLC epigenetics and epidrugs that will help to improve SCLC outcomes.RNA methylations, as the prevalent post-transcriptional modifications, are critical in regulating various biological processes, such as RNA transcription, splicing, structure, stability, and translation. Its dysregulation is closely related to the occurrence of human malignancies. The advance of high-throughput sequencing technology facilitates the investigations about how methylation of coding and non-coding RNAs regulates cancer progression through reshaping the transcriptomics. Here, we review the current progress about the regulatory role of several representative RNA modifications in cancers, including N6-methyladenosine (m6A), 5-methylcytosine (m5C), N1-methyladenosine (m1A) and 2'-O-methylation (Nm). Meanwhile, we also discuss the potential clinical value of RNA methylation in diagnostic and therapeutic implications of human cancers.Both genetic and epigenetic mechanisms intimately regulate cancer development and chemoresistance. Different genetic alterations are observed in multiple genes, and most are irreversible. Aside from genetic alterations, epigenetic alterations play a crucial role in cancer. The reversible nature of epigenetic modifications makes them an attractive target for cancer prevention and therapy. Specific epigenetic alteration is also being investigated as a potential biomarker in multiple cancers. c-MYC is one of the most important transcription factors that are centrally implicated in multiple types of cancer cells reprogramming, proliferation, and chemoresistance. TPEN supplier c-MYC shows not only genetic alterations but epigenetic changes in multiple cancers. It has been observed that epigenome aberrations can reversibly alter the expression of c-MYC, both transcriptional and translational levels. Understanding the underlying mechanism of the epigenetic alterations of c-MYC, that has its role in multiple levels of cancer pathogenesis, can give a better understanding of various unresolved questions regarding cancer.