Abstract
In this paper, the kinetics of the reaction of phenyl isocyanate with crosslinking agents such as sucrose, sorbitol, and glycerol are reported. Crosslinking agents were used in high molar excess to isocyanate to obtain pseudo-first-order rate dependencies, and the reaction products were separated by high-performance liquid chromatography and detected by UV spectroscopy and mass spectrometry. It was found that the glycerol’s primary hydroxyl groups were approximately four times reactive than the secondary ones. However, in the case of sorbitol, the two primary OH groups were found to be the most reactive, and the reactivity of hydroxyl groups decreased in the order of kOH(6)(8.43) > kOH(1)(6.91) > kOH(5)(1.19) > kOH(2)(0.98) > kOH(3)(0.93) > kOH(4)(0.64), where the numbers in the subscript and in the brackets denote the position of OH groups and the pseudo-first-order rate constants, respectively. The Atomic Polar Tenzor (APT) charges of OH groups and dipole moments of monosubstituted sorbitol derivatives calculated by density functional theory (DFT) also confirmed the experimental results. On the other hand, the reactions of phenyl isocyanate with crosslinking agents were also performed using high excess isocyanate in order to determine the number of OH-groups participating effectively in the crosslinking process. However, due to the huge number of derivatives likely formed in these latter reactions, a simplified reaction scheme was introduced to describe the resulting product versus reaction time distributions detected by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-TOF MS). Based on the results, the kinetically equivalent functionality (fk) of each crosslinking agent was determined and found to be 2.26, 2.6, and 2.96 for glycerol, sorbitol, and sucrose, respectively.
Highlights
In recent years, the development and production of polyurethane-based materials (PURs) have been steadily increasing
Our aim was to determine the reactivity of each hydroxyl group for glycerol, sorbitol, and sucrose towards phenyl isocyanate used as a model compound, and to be able to find the most reactive functional groups of these materials that are responsible for forming crosslinks in polyurethane networks
To determine the pseudo first-order rate constants, the reaction products were separated by high-performance liquid chromatography (HPLC)-UV, and the areas under the detected peaks in the UV chromatogram were used for the calculation of the mole fractions of reaction products (Equation (1))
Summary
The development and production of polyurethane-based materials (PURs) have been steadily increasing. Due to their versatility and easy-to-tailor properties, the application of PURs spans from electronic components to various biomedical devices [1,2]. They have been frequently used polymeric materials in tissue engineering as well [3,4]. It is, essential in biomedical applications that the material planned to be embedded into the body be biocompatible. The reactivities of the OH groups towards isocyanate, due to their different chemical environments, are different, which, in turn, will affect the resulting crosslinking efficiency and density [13,14,15]
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