Login / Signup

Thermal Investigations of Annelated Triazinones-Potential Analgesic and Anticancer Agents.

Małgorzata SztankeKrzysztof SztankeAgnieszka OstaszHalina GłuchowskaRenata Łyszczek
Published in: Molecules (Basel, Switzerland) (2023)
In this article, for the first time, TG-DSC and TG-FTIR investigations of potential pharmaceutics, i.e., analgesic and anticancer active annelated triazinones ( 1 - 9 ) have been presented. The thermal behaviour of these molecules was established in oxidative and inert conditions. The solid-liquid phase transition for each compound ( 1-9 ) was documented by one sharp DSC peak confirming the high purity of each sample studied. All the molecules were characterised in terms of calorimetric changes and mass changes during their heating. They revealed high thermal stability in oxidative and inert conditions. The observed tendency in thermal stability changes in relation to a substituent present at the phenyl moiety was found to be similar in air and nitrogen. It was confirmed that annelated triazinones 1-9 were stable up to a temperature range of 241-296 °C in air, and their decomposition process proceeded in two stages under oxidative conditions. In addition, it was established that their thermal stability in air decreased in the following order of R at the phenyl moiety: 4-Cl > 3,4-Cl 2 > H > 3-Cl > 4-CH 3 > 2-CH 3 > 3-CH 3 > 2-Cl > 2-OCH 3 . The volatile decomposition products of the investigated molecules were proposed by comparing the FTIR spectra collected during their thermogravimetric analysis in nitrogen with the spectra from the database of reference compounds. None of annelated triazinones 1-9 underwent any polymorphic transformation during thermal studies. All the compounds proved to be safe for erythrocytes. In turn, molecules 3 , 6, and 9 protected red blood cells from oxidative damage, and therefore may be helpful in the prevention of free radical-mediated diseases.
Keyphrases
  • room temperature
  • emergency department
  • human health
  • spinal cord injury
  • climate change
  • risk assessment
  • sensitive detection
  • molecular dynamics
  • single molecule
  • fluorescent probe
  • drug induced
  • high speed
  • solid state