Rhodiola crenulata extract decreases fatty acid oxidation and autophagy to ameliorate pulmonary arterial hypertension by targeting inhibiton of acylcarnitine in rats.

Pulmonary arterial hypertension (PAH) is a devastating pulmonary circulation disease lacking high-efficiency therapeutics. The present study aims to decipher the therapeutic mechanism of Rhodiola crenulata, a well-known traditional chinese medicine with cardiopulmonary protection capacity, on PAH by exploiting functional lipidomics. The rat model with PAH was successfully established for first, following Rhodiola crenulata water extract (RCE) treatment, then analysis of chemical constituents of RCE was performed, additional morphologic, hemodynamic, echocardiographic measurements were examined, further targeted lipidomics assay was performed to identify differential lipidomes, at last accordingly mechanism assay was done by combining qRT-PCR, Western blot and ELISA. Differential lipidomes were identified and characterized to differentiate the rats with PAH from healthy controls, mostly assigned to acylcarnitines, phosphatidylcholines, sphingomyelin associated with the PAH development. Excitingly, RCE administration reversed high level of decadienyl-L-carnitine by the modulation of metabolic enzyme CPT1A in mRNA and protein level in serum and lung in the rats with PAH. Furthermore, RCE was observed to reduce autophagy, confirmed by significantly inhibited PPARγ, LC3B, ATG7 and upregulated p62, and inactivated LKB1-AMPK signal pathway. Notably, we accurately identified the constituents in RCE, and delineated the therapeutic mechansim that RCE ameliorated PAH through inhibition of fatty acid oxidation and autophagy. Altogether, RCE might be a potential therapeutic medicine with multi-targets characteristics to prevent the progression of PAH. This novel findings pave a critical foundation for the use of RCE in the treatment of PAH.

Preparation of Superhydrophobic Porous SiO2 Aerogel Using Methyl Trimethoxy Silane Single Precursor and Superhydrophobic Cotton Fabric Coating from It.

Superhydrophobic cotton fabrics were prepared by simultaneous incorporation of SiO2 aerogel particles and polydimethylsiloxane (PDMS). The SiO2 aerogels were synthesized via acid-base catalyzed sol-gel reaction with methyl trimethoxy silane (MTMS) as the single precursor and oxalic acid and ammonium hydroxide as the catalyst in methanol (MeOH) solution by drying under ambient pressure. The preparation parameters (e.g., MTMS/MeOH molar ratio, oxalic acid/MTMS molar ratio, gelation pH value, and gelation temperature) had great influences on the density and porosity of the SiO2 aerogel. The obtained SiO2 aerogel had low density, high porosity and high specific surface area, showing the typical rough mesoporous structure. The prepared bulk SiO2 aerogel displayed excellent superhydrophobicity with a water contact angle (WCA) of 151.0 ± 0.8°. Superhydrophobic cotton fabric with a WCA of 155.6 ± 0.9° for a 5 µL water droplet was successfully obtained by simply coating the PDMS/SiO2 aerogel composite solution via dip-pad-cure process. This could be attributed to the combination of SiO2 aerogel particles with porous rough microstructure, high specific surface area and PDMS adhesive layer with low surface energy. The effect of PDMS/SiO2 aerogel coating treatment on the mechanical strength properties of the cotton fabrics was negligible. This simple approach may pave the potential way for practical applications.

Compact fiber tip modal interferometer for high-temperature and transverse load measurements.

A compact fiber tip modal interferometer (FTMI) based on two-wave interference has been demonstrated. Its fabrication process is very simple, just involving fiber tapering by a fusion splicer. The effective sensing area of the FTMI has a small length of ~310 µm. The interference spectra of the fiber tips with different size and profile have been analyzed. The FTMI has a good mechanical strength and high-temperature stability. It can be used for high-temperature and transverse load sensing simultaneously in a harsh environment when two different attenuation peaks are chosen to be monitored.

KIR2DL1-HLA signaling pathway: notable inhibition in the cytotoxicity of allo-NK cell against KG1A cell.

BACKGROUND: KIR2DL1 is an important member of killer cell immunoglobulin-like receptors (KIRs). It recognizes the C2 group of alleles exclusively and delivers signals that inhibit NK cell cytotoxicity. METHODS: In this study, NK cells were isolated by magnetic activated cell sorting (MACS) from peripheral blood of 12 healthy unrelated male donors. Flow cytometry (FCM) was used to evaluate the purity of NK cells and phenotypic KIR2DL1 expression on them. The lysis of KG1A and K562 cells by NK cells was analyzed in the lactate dehydrogenase (LDH) assay to investigate whether KIR2DL1 expression on NK cells would affect the cytotoxicity. RESULTS: Significant differences in KIR2DL1 frequency were noted among the donors (range, 27.14% - 92.49%). NK cells with lower KIR2DL1 expression exerted higher cytolytic activity against KG1A cells, whereas those with higher KIR2DL1 expression exerted significantly lower lysis against KG1A cells (R2 = 0.8169, p < 0.05). CONCLUSIONS: KIR2DL1 expression frequency was negatively correlated with the cytotoxicity of NK cells against KG1A cells. This study discovered that differential KIR2DL1 expression could positively affect the lytic activity of NK cells against KG1A cells, suggesting potential clinical value of KIR2DL1 selection in the treatment of acute myeloid leukemia (AML) patients.

Ultrasensitive temperature sensor based on an isopropanol-sealed optical microfiber taper.

We demonstrate an ultrasensitive temperature sensor based on an isopropanol-sealed optical microfiber taper (OMT) in a capillary. The OMT is highly sensitive to ambient refractive index (RI) with a maximum sensitivity of 18989 nm/RI unit in the range of 1.3955-1.4008. The thermo-optic effect of isopropanol and the thermal expansions of the sealant and sealed liquid turn the OMT into an ultrasensitive temperature sensor with the maximum sensitivity of -3.88 nm/°C in the range of 20°C-50°C. The temperature sensitivity contributions from different mechanisms are also investigated theoretically and experimentally.