In Vivo Toxicity, Redox-Modulating Capacity and Intestinal Permeability of Novel Aroylhydrazone Derivatives as Anti-Tuberculosis Agents.
Violeta ValchevaRumyana SimeonovaMilka MilevaStanislav PhilipovReneta PetrovaSimeon DimitrovAlmira GeorgievaElina TzvetanovaYoana TenevaViolina T AngelovaPublished in: Pharmaceutics (2022)
The emergence and spread of Mycobacterium tuberculosis strains resistant to many or all anti-tuberculosis (TB) drugs require the development of new compounds both efficient and with minimal side effects. Structure-activity-toxicity relationships of such novel, structurally diverse compounds must be thoroughly elucidated before further development. Here, we present the aroylhydrazone compounds ( 3a and 3b ) regarding their: (i) acute and subacute toxicity in mice; (ii) redox-modulating in vivo and in vitro capacity; (iii) pathomorphology in the liver, kidney, and small intestine tissue specimens; and (iv) intestinal permeability. The acute toxicity test showed that the two investigated compounds exhibited low toxicity by oral and intraperitoneal administration. Changes in behavior, food amount, and water intake were not observed during 14 days of the oral administration at two doses of 1/10 and 1/20 of the LD 50 . The histological examination of the different tissue specimens did not show toxic changes. The in vitro antioxidant assays confirmed the ex vivo results. High gastrointestinal tract permeability at all tested pH values were demonstrated for both compounds. To conclude, both compounds 3a and 3b are highly permeable with low toxicity and can be considered for further evaluation and/or lead optimization.
Keyphrases
- mycobacterium tuberculosis
- oxidative stress
- liver failure
- endothelial cells
- escherichia coli
- type diabetes
- emergency department
- drug induced
- metabolic syndrome
- high throughput
- adipose tissue
- climate change
- weight loss
- hepatitis c virus
- hepatitis b virus
- high resolution
- skeletal muscle
- single molecule
- extracorporeal membrane oxygenation
- atomic force microscopy
- mechanical ventilation
- adverse drug