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A theoretical protocol for the rational design of the bioinspired multifunctional hybrid material MIP@cercosporin
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Springer
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Abstract
Context Rational design of polymeric materials prepared with the molecular imprinting technology is gaining even more
space, as it can provide the optimal conditions to direct the laboratory molecularly imprinting polymer (MIP) preparation,
maximizing their efciency while reducing costs and preparation time, when compared to try-and-error approaches. We
perform a rational design of an MIP with specifc cavities for cercosporin accommodation by means of computational tools.
The main steps of an MIP preparation were simulated and it was found that the most appropriated functional monomer to
be used in the MIP preparation for cercosporin is the acrylamide, while the most suitable crosslinking agent is found to
be p-divinylbenzene. Also, the most suitable solvents to remove cercosporin from the cavity are those with low dielectric
constant, such as chloroform. This kind of solvent can then be used in washing step, in the case of use the MIP for sensing
destinations. On the other hand, solvents like water, which has high dielectric constants, can efciently improve the interactions between cercosporin and the functional monomer acrylamide, being indicated when the objective is to attract or
maintain the cercosporin inside the MIP cavity. Thus, a MIP@cercosporin hybrid material can be used in aqueous solutions
more reliably, or even the cercosporin detection in this media can be favoured. In the selectivity analysis of the material
prepared in this specifc condition, the results point that this MIP can also detect elsinochrome A with high efciency, and
could be more selective for hypericin, altertoxin, hypocrelin A, and phleichrome mycotoxins.
Method The main steps of a MIP synthesis were theoretically simulated trough density functional theory (DFT) calculations aiming to direct and optimize the synthesis and applications of the material before the bench tests. Initially, in order to
choose the most suitable functional to be employed for cercosporin calculations, eight of the DFT functionals that had been
previously used for cercosporin calculations in literature were tested, which were the LCWPBE, B3LYP, CAM-B3LYP,
M062-X, mPW1PW91, PBE0, TPSSh, and ωb97Xd. The theoretical 1
H NMR chemical shifts for cercosporin molecule
were calculated and compared with experimental results to analyze the performance of the functionals. Of all these, the best
results were obtained with the TPSSh functional, employing the 6-31G(d,p) basis set, and this level of theory was then used
for all the following steps. All the simulations were performed by means of geometry optimizations and frequency calculations. Additionally, AIM calculations were employed for further analysis of the interactions between the chosen functional
monomer and cercosporin template in step 1, which was functional monomer selection. In washing step, the calculations
were done using implicit solvation model, and fnally, in selectivity tests, the putative “solid” MIP was simulated by freezing the positions of the monomers after the template remotion, and then other structurally similar toxins were placed in its
cavity for the geometry optimizations and frequency calculations.
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SALES, Thaís A. et al. A theoretical protocol for the rational design of the bioinspired multifunctional hybrid material MIP@cercosporin. Journal of Molecular Modeling, [S.l.], v. 29, 2023.
