Salicyl alcohol (2-Hydroxybenzyl alcohol)

Comparative evaluation of gastroulcerogenic potential of nitrogen isoforms of salicyl alcohol and aspirin in rats: biochemical and histological study

The aim of the current study was to explore in vivo any relative gastroulcerogenic prospective propensity of newly synthesized nitrogen containing derivatives of salicyl alcohol; compound (I) [1-(2-hydroxybenzyl)piperidinium chloride], compound (II) [4-carbamoyl-1-(2-hydroxybenzyl)piperidinium chloride] and aspirin in albino rats. The experimental groups received the following oral treatments daily for 6 days: group I saline control; group II, standard (aspirin) treatment group [150 mg/kg of body weight]; group III, test (compound I) treatment group [100, 150 mg/kg]; group IV, test (compound II) treatment group [100, 150 mg/kg]. The results showed that in the case of the aspirin treated group and compound (I) [150 mg/kg], there was a significant increase in gastric volume, free acidity, total acidity, ulcer score and a decrease in gastric pH. Furthermore, histopathological examination of gastric mucosa of these treated groups revealed detectable morphological changes. Utilizing the same protocol, synthetic compound (I) [100 mg/kg] and (II) [100, 150 mg/kg] exhibited no statistically significant ulcerogenic or cytotoxic properties. A cyclooxygenase (COX) selectivity test indicated the preferential inhibition of COX-I and COX-II enzymes by compounds (I) and (II). This study therefore indicates that these synthetic compounds may possess reduced ulcerogenic potential and could be a functional substitute to aspirin.

Synthetically modified bioisosteres of salicyl alcohol and their gastroulcerogenic assessment versus aspirin: biochemical and histological correlates

The present study was conducted to synthesize nitrogen containing derivatives of salicyl alcohol and to investigate in vivo their ulcerogenic potential in comparison with aspirin in rats. The compounds [4-(2-hydroxybenzyl) morpholin-4-iumchloride (I)] and [1,4-bis(2-hydroxybenzyl) piperazine-1,4-diium chloride (II)] were synthesized and their chemical structures were characterized using spectral data. In our previous study (Ali et al., Afr J Pharm Pharmacol 7:585-596, 2013), both compounds showed anti-inflammatory, antinociceptive, and antipyretic properties in standard animal models and a greater binding affinity for cyclooxygenase-2 versus cyclooxygenase-1 in molecular docking and dynamics analysis. For in vivo studies, animals were randomly divided into four groups. The synthetic compounds (both at 100 or 150 mg/kg), aspirin (150 mg/kg), or saline vehicle was administered orally, once daily for 6 days and then tested for ulcerogenic activity. At the end of the procedure, gastric juice and tissues were collected and subjected to biochemical and histological analyses. The results of the study revealed that in the case of the aspirin-treated group, there was a significant increase in gastric juice volume, free acidity, total acidity, and ulcer score and a decrease in gastric pH. Moreover, histological examination of the gastric mucosa of the aspirin-treated group indicated morphological changes while neither of the synthetic compounds showed any significant ulcerogenic or cytotoxic properties. The results of the present study suggest that both compounds are free from ulcerogenic side effects and may represent a better alternative to aspirin.

Differentiation of extractive and synthetic salicin. The 2H aromatic pattern of natural 2-hydroxybenzyl alcohol

The natural abundance deuterium NMR characterization of four commercially available samples (Kahlbaum, Aldrich, Fluka, and Extrasynthese) of salicin 1 in comparison with two extractive samples from Salix humboldiana and Salix purpurea L. and with a synthetic material, performed on the pentaacetate derivative 2 and on diacetyl salicyl alcohol 4, is reported. Product 2 from S. humboldiana and the sample from salicin Kahlbaum show mean (D/H)aromatic values of 117 and 121 ppm, whereas, for the remaining, values of 146, 154, 153, and 150 ppm are observed, thus suggesting that salicin Kahlbaum is from extractive origin. The (D/H) values at positions 5' and 6' of the sugar moiety suggest a hypothesis on the origin of the glucose residue discriminating between those deriving from C3 or C4 plants. The analysis of 4, obtained from 3, formed in the beta-glucosidase hydrolysis of salicin 1, reveals in the natural samples from S. purpurea and from Kahlbaum the trend (D/H)4(para) > (DH)3(meta) approximately (D/H)5(meta) > (D/H)6(ortho), the first example of deuterium pattern of an ortho-oxygen-substituted phenylpropanoid. The three samples derived from commercial 1 (Aldrich, Fluka, and Extrasynthese) and the synthetic sample show almost identical deuterium content at positions 4 and 6 (around 153 ppm), whereas for the two meta positions (D/H)3 > (D/H)5 (ca. 162 and 140 ppm, respectively). Product 4, obtained from 3 submitted to acid-catalyzed deuteration, shows different deuterium incorporations in the two meta positions (which are ortho/para to the activating phenolic hydroxyl group), suggesting that possibly the deuterium abundance at the two meta positions may be affected by exchange phenomena with the medium.

Structure of saligenin: microwave, UV and IR spectroscopy studies in a supersonic jet combined with quantum chemistry calculations

In this study, we have determined the structure of a medicinally important molecule saligenin (2-hydroxybenzyl alcohol) using UV, IR and microwave absorption spectroscopy in a supersonic jet combined with ab initio calculations. The structure of the only observed conformer of saligenin corresponds to the global minimum on the conformational surface. The observed structure is stabilized by an intramolecular strong O-H···O hydrogen bonding as well as a very weak O-H···π interaction. The hydrogen bond is formed through phenolic OH as the hydrogen bond donor and benzylic OH as the hydrogen bond acceptor while the O-H···π interaction is through benzylic O-H as the hydrogen bond donor and phenyl group as the hydrogen bond acceptor. It has been observed that the benzylic OH stretching frequency in saligenin is more red-shifted compared to that in benzyl alcohol as the strong O-H···O interaction present in saligenin acts on the benzylic O-H group. In fact, there is a subtle interplay among the strong O-H···O hydrogen bond, weak O-H···π interaction, and steric effects arising from the ortho substitution of the OH group in benzyl alcohol. This fine-tuning of multiple interactions very often governs the specific structures of biomolecules and materials.