Morphological and Transcriptomic Analysis of the Supplemental Boron in the Liver of Ostrich Chicks.

African ostrich chicks (Struthio camelus) were divided into six groups, and each received different levels of boric acid (source of boron) in the drinking water (0, 40, 80, 160, 320, and 640 mg/L respectively) to examine the histological, apoptotic, biochemical, and transcriptomic parameters. Morphological analysis in different groups was assessed by hematoxylin and eosin (H&E) staining, periodic acid Schiff (PAS) staining, and terminal deoxynucleotide transferase dUTP Nick-End Labeling (TUNEL) assay. The biochemical profile was evaluated spectrophotometrically. Detailed RNA-Seq of the data was performed using the transcriptomic method. H&E staining showed well-developed liver structure up to the 160 mg/L boric acid (BA) supplement groups, while BA doses (320 mg/L and 640 mg/L) caused changes in hepatocytes and portal triads. PAS staining showed that glycogen levels were optimal in the 80 mg/L BA dose group, but a reduction in glycogen levels was observed after this group, particularly in the 640 mg/L BA supplement group. Cellular apoptosis showed a biphasic pattern, and the BA dose above 160 mg/L enhanced cell death. In addition, serum analysis showed that doses of 80-160 mg BA were beneficial for ostrich liver. Then, the transcriptome analysis of the 80 mg dose also showed mainly positive effects on the liver. These results demonstrated that chronic BA exposure (320-640 mg) can cause significant histological, apoptotic, and biochemical changes in African ostrich liver, while the adequate dose of supplementation (particularly 80 mg BA) promotes liver growth.

Chemical compositions and pharmacological activities of natural musk (Moschus) and artificial musk: A review.

ETHNOPHARMACOLOGICAL RELEVANCE: Natural musk (Moschus), derived naturally from male musk deer (Moschus berezovskii Flerov, Moschus sifanicus Przewalski, or Moschus moschiferus Linnaeus), has long been an important component of traditional Chinese medicine (TCM), and was used as resuscitation, blood circulation, and collateral drainage. detumescence and pain relief. Artificial musk was researched and applied into TCM as natural musk being as unsustainable resources. AIM OF THE STUDY: We mainly summarized chemical compositions, pharmacological activities and mechanism of action of natural and artificial musk, and designed to serve as a foundation for further research into musk chemical compositions and pharmacological effect. MATERIALS AND METHODS: Those mainstream scientific databases including Google Scholar, ScienceDirect, SpringerLink, CNKI, Wiley Online Library, web of science, were used for searching with below "Keywords", as well as literature-tracking. Literatures spanned 1962 to 2021, and involved into Chinese, English, Janpanese, Korean. RESULTS: Natural musk contains some very desirable but scarce compounds, as well as their biological features, which led to the development of artificial musk. The chemical ingredients, pharmacological activities, and mechanisms of action of natural and artificial musk are summarized and compared in this paper. Polypeptide and protein, muscone, musclide, steroids, muscopyridine, and other chemical constituents of musk demonstrated important therapeutic properties against inflammation, immune system disorders, neurological disorders, cardiovascular system disorders, and so on. The mechanism of action contributed to effect on mediators, acceptors and relative signal pathways. CONCLUSIONS: Natural and artificial musk were revealed having some activated compounds, and showed excellent pharmacological effect. Meantime, above two sides of natural and artificial musk ought to get further research.

Resistant cutoff values and optimal scheme establishments for florfenicol against Escherichia coli with PK-PD modeling analysis in pigs.

Florfenicol, a structural analog of thiamphenicol, has broad-spectrum antibacterial activity against gram-negative and gram-positive bacteria. This study was conducted to investigate the epidemiological, pharmacokinetic-pharmacodynamic cutoff, and the optimal scheme of florfenicol against Escherichia coli (E. coli) with PK-PD integrated model in the target infectious tissue. 220 E. coli strains were selected to detect the susceptibility to florfenicol, and a virulent strain P190, whose minimum inhibitory concentration (MIC) was similar to the MIC50 (8 µg/ml), was analyzed for PD study in LB and ileum fluid. The MIC of P190 in the ileum fluid was 0.25 times lower than LB. The ratios of MBC/MIC were four both in the ileum and LB. The characteristics of time-killing curves also coincided with the MBC determination. The recommended dosages (30 mg/kg·body weight) were orally administrated in healthy pigs, and both plasma and ileum fluid were collected for PK study. The main pharmacokinetics (PK) parameters including AUC24 hr , AUC0-∞ , Tmax , T1/2 , Cmax , CLb, and Ke were 49.83, 52.33 µg*h/ml, 1.32, 10.58 hr, 9.12 µg/ml, 0.50 L/hr*kg, 0.24 hr-1 and 134.45, 138.71 µg*hr/ml, 2.05, 13.01 hr, 16.57 µg/ml, 0.18 L/hr*kg, 0.14 hr-1 in the serum and ileum fluid, respectively. The optimum doses for bacteriostatic, bactericidal, and elimination activities were 29.81, 34.88, and 36.52 mg/kg for 50% target and 33.95, 39.79, and 42.55 mg/kg for 90% target, respectively. The final sensitive breakpoint was defined as 16 µg/ml. The current data presented provide the optimal regimens (39.79 mg/kg) and susceptible breakpoint (16 µg/ml) for clinical use, but these predicted data should be validated in the clinical practice.