Delving into the Latest Updates on Thiamphenicol with Synapse

Overview

Basic Info

Drug Type

Small molecule drug

Synonyms

Thiamphenicol (JAN/USAN/INN), CB-8053, NSC-522822

+ [6]

Target

50S subunit

Action

inhibitors

Mechanism

50S subunit inhibitors(50S ribosomal subunit inhibitors)

Therapeutic Areas

Infectious Diseases

Active Indication

Bacterial Infections

Inactive Indication-

Originator Organization

Tianjin Jinyao Pharmaceutical Co., Ltd.

Active Organization

Tianjin Pharmaceutical Da Ren Tang Group Corp. Ltd.

Tianjin Jinyao Pharmaceutical Co., Ltd.

Inactive Organization-

License Organization-

Drug Highest PhaseApproved

First Approval Date-

Regulation-

Login to view timeline

Structure/Sequence

Molecular FormulaC12H15Cl2NO5S

InChIKeyOTVAEFIXJLOWRX-NXEZZACHSA-N

CAS Registry15318-45-3

In pre-antibiotic times, various highly contagious diseases like cholera, smallpox and tuberculosis were widespread worldwide. Penicillin discovery in the late 1920s was a groundbreaking moment in medical history, saving countless lives. However, over the next few decades, microbes developed antibiotic resistance, leading to a global public health threat known as antimicrobial resistance (AMR). Pseudomonas aeruginosa is a major contributor to hospital-acquired infections, affecting millions of patients and causing numerous deaths annually. Several non-[Formula: see text]-lactam antibiotics combat these infections effectively, while their effect on P. aeruginosa quorum sensing (QS) has been insufficiently explored. We have undertaken comprehensive research to understand the effect of non-[Formula: see text]-lactam antibiotics on various targets of P. aeruginosa. Using molecular simulations, we scrutinize these antibiotics” dynamic behavior and stability. Based on toxicity, binding energy and binding site, platensimycin and sulfasalazine were identified as promising candidates against various targets of P. aeruginosa. The binding energies for sulfasalazine and platensimycin with LasA were found to be −8.1 and −8.6 kcal/mol, respectively. Both of these leading antibiotics were interacting at the active sites of all tested proteins (LasA, LasI and PqsR). The examination of molecular dynamics confirmed the stable complex formation of the lead non-[Formula: see text]-lactam antibiotics with all selected target proteins under normal physiological conditions. These findings emphasize the potential efficacy of platensimycin and sulfasalazine. They could potentially be repurposed for targeting the QS of P. aeruginosa.

01 Sep 2025·FOOD CHEMISTRY

Novel nanoceria in situ-derived porphyrin heterostructure enhanced electrochemiluminescent and colorimetric dual-mode detection of tetracycline residue in foods

Article

Author: Han, Qian ; Gu, Tiance ; Wang, Jing ; Shi, Xueran ; Cao, Yingbo ; Cong, Lin

Due to serious harm caused by tetracycline (TC) residue to human health, here a multifunctional nanoceria in situ-derived porphyrin heterogeneous framework (CeO₂-POF) was innovatively applied to an electrochemiluminescence (ECL) and colorimetric dual-mode sensing platform for TC detection. Concretely, the CeO₂-POF fully interprets a "kill three birds with one stone" strategy. Firstly, CeO₂-POF integrated ECL luminophore ("bird" one) and co-reaction accelerator ("bird" two), obtaining a 1.6-fold stronger ECL emission than that of tetrakis (4-carboxyphenyl) porphyrin (TCPP) ligand. Secondly, compared with two self-separated signal probes, the single CeO₂-POF heterostructure exhibited enhanced ECL and peroxidase-like properties ("bird" three). CeO₂-POF showed high catalytic activity against H₂O₂ and TMB, with color changes monitored via smartphone. Under optimized conditions, the dual-mode sensor for TC achieved a satisfied ECL detection limit of 0.57 pM and a colorimetric detection limit of 0.52 nM. Compared with the commercial ELISA kit, the dual-mode sensing strategy exhibited satisfactory recovery in foods.

01 Sep 2025·WATER RESEARCH

The new strategies for high efficiency removal of antibiotics and antibiotic resistance genes by direct bio-drying of biogas slurry: Microbiological mechanisms

Article

Author: Yong, Xiaoyu ; Zhang, Haorong ; Zhou, Jun ; Liu, Fenwu ; Ma, Liqian ; Tong, Zhenye ; Li, Siqin ; Li, Zhenguo

High levels of antibiotics and antibiotic resistance genes (ARGs) still exist in biogas slurry after anaerobic digestion of cow manure. In this study, direct bio-drying strategies of cow manure biogas slurry without solid-liquid separation for the removal of antibiotics and ARGs were explored. The results showed that, after direct bio-drying of biogas slurry, the moisture contents decreased to 25.2 %-31.5 %. The maximum temperatures of the piles reached 76.1-77.4 °C, which is close to ultra-high temperatures (>80 °C). Direct biogas slurry bio-drying (CK treatment) achieved efficient removal of antibiotics, ARGs, and mobile genetic elements (MGEs) (95.4 %, 98.6 % and 86.7 % removal, respectively). Compared to the CK treatment, molecular membrane covering (MMC) alone was the most effective in further significantly decreasing the antibiotic concentration and the abundance of ARGs and MGEs in the final bio-dried samples, followed by food waste hydrochar (FHC) addition alone. Methanogenic archaea were identified as potential hosts for ARGs based on Network analysis. FHC addition-MMC increased the abundance of potential hosts for ARGs and promoted the expression of microbial methane metabolism function relative to the CK treatment during the later stages of bio-drying, thereby decreasing the removal efficiency of ARGs. The results of structural equation model and redundancy analysis showed that MGEs had the most significant direct effect on ARGs and moisture content had the highest relative contribution to changes in ARGs. In summary, direct bio-drying strategies were able to efficiently remove antibiotics and ARGs from cow manure biogas slurry and also achieve biological dewatering of the biogas slurry.

100 Deals associated with Thiamphenicol

Login to view more data