Study on Dicyandiamide-Imprinted Polymers with Computer-Aided Design.

Dadong Liang,Junbo Liu,Shanshan Tang,Yan Wang,Ruifa Jin,Bo Li,Miliang Zhang,Weishuai Tian,Yang Li,Songyang Li,Yuqing Li

doi:10.3390/ijms17111750

Abstract

With the aid of theoretical calculations, a series of molecularly imprinted polymers (MIPs) were designed and prepared for the recognition of dicyandiamide (DCD) via precipitation polymerization using acetonitrile as the solvent at 333 K. On the basis of the long-range correction method of M062X/6-31G(d,p), we simulated the bonding sites, bonding situations, binding energies, imprinted molar ratios, and the mechanisms of interaction between DCD and the functional monomers. Among acrylamide (AM), N,N’-methylenebisacrylamide (MBA), itaconic acid (IA), and methacrylic acid (MAA), MAA was confirmed as the best functional monomer, because the strongest interaction (the maximum number of hydrogen bonds and the lowest binding energy) occurs between DCD and MAA, when the optimal molar ratios for DCD to the functional monomers were used, respectively. Additionally, pentaerythritol triacrylate (PETA) was confirmed to be the best cross-linker among divinylbenzene (DVB), ethylene glycol dimethacrylate (EGDMA), trimethylolpropane trimethylacrylate (TRIM), and PETA. This is due to the facts that the weakest interaction (the highest binding energy) occurs between PETA and DCD, and the strongest interaction (the lowest binding energy) occurs between PETA and MAA. Depending on the results of theoretical calculations, a series of MIPs were prepared. Among them, the ones prepared using DCD, MAA, and PETA as the template, the functional monomer, and the cross-linker, respectively, exhibited the highest adsorption capacity for DCD. The apparent maximum absorption quantity of DCD on the MIP was 17.45 mg/g.

Highlights

Molecular imprinting is a class of highly efficient molecular recognition technologies
Liu et al used the quantum chemical method PBE1PBE to investigate the interaction between melamine and acrylamide in the molecularly imprinted polymers (MIPs) [25]
We prepared a series of MIPs via precipitation polymerization, using computer-aided design

Summary

Introduction

Molecular imprinting is a class of highly efficient molecular recognition technologies. Targeted molecules with suitable size, shape, and functional group can be selectively absorbed by the selective recognition sites of the molecularly imprinted polymers (MIPs) [1,2]. To prepare the MIPs, templates and functional monomers should be employed. The functional monomer molecules are allowed to self-assemble around the template molecules to form the template-monomer. Stoci.s2e0l1f6-a, 1s7s,e1m75b0le around the template molecules to form the template-monomer compl2eoxfe1s1. Cross-linkers are added, allowing the crosslinking polymerization reactions to be performed caoromupnldextehse. CTohmenp,lecxroess.s-Fliinnaklelyrs, tahree atedmdpedla,taelmlowoliencgultehseacrreoesxstlirnakctiendg, paonldymtheerMizaIPtisonwirtehactatiiolonrs-mtoabdee preecrofogrnmiteiodnasriotuesndarteheobctoaminpelde.xeSso. fFairn,adlluy,ethtoe ttheme apdlavtaenmtaogleescuolfesMaIrPese, xntaramcetelyd,eaxncdelltehnetMmIoPlsecwuiltahr traeicloogr-nmitaiodne repceorfgonrimtioanncsei,tesloawre ocbotsati,nehdig. HSo pfahry, sdiucael toatnhde acdhveamnitcaaglessotafbMiliItPys,, naanmd elaypepxlciceallteionnt munoilveecruslaalritrye,ctohgenyithiaovnepreercfeoirvmedanmceu,clhowattceonstti,ohnigahndphbeycsoicmaleaantdtracchteivmeicinalmstaanbyiliftiye,ldasn,dsuacphplaiscastoiolind upnhiavseeresxatlirtayc,ttihoeny[3h,a4v],echreicraelivseedpamrauticohna[t5te],nitmiomnuanned-lbikeecoamsseayat[t6r]a,catnivteibiondmy asinmyufilealtdiosn, s[u7]c,hchasemsoilciadl psehnassoeresx[t8r,a9c]t,idornu[g3,d4e],licvheirryal[s1e0p],aprarotitoenom[5i]c,sim[1m1]u, anne-dliwkeaastseswayat[e6r],tarenattibmoednyt s[1im2]u. Lation [7], chemical sensoIrns [r8e,9ce],ndtruygeadresl,ivmerayn[y10s]c, ipernottiefiocmgicrsou[1p1s], ahnadvewastsutedwieadterMtrIePastmweintht [1t2h]e. Yitahñdezyneatmailc. spirmouvildateidonsa tocosmelepcutttahteiomn otsot suscitraebenle mcoomnommoenrlsy[1u6s]e. dYañmeozneotmale.rpsroavniddedsealeccotmthpeutamtioosnt tosusictraebelne cmoomnmomonelrysufsoerd msyonntohmeseizrsinagndchseolleacttet-hime pmroinsttesduitaanbdle mnoonn-oimmeprrsinfoterdsypnothlyesmizeirng[1c7h]o.laItne-ismupmri,nttehde athnedonreotnic-iaml cparlicnuteladtipoonlsymmeary[1r7e]d.uIncesuthme, ttihmeethreeoqrueitriecadl fcoarlceuxlapteiroinmsemntaayl rsetduudcieest.hMe toimreeimreqpuoirrteadntfloyr, ethxepemriomleecnutalalrstiumdpierisn. tMinogremiemcphoarntiasnmtl,ys,uthceh masotlheceuilnatreirmacptrioinntsinbgetmweecehnanthisemm, souncohmaesrthmeoilnetceurlaecstiaonnds btheetwteemenptlahteemmoonleocmuelersm, molaeycubleesananaldyzthede taenmdpelxaptelaminoeldec.ules, may be analyzed and explained

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Results

Conclusion