Fabrication of Antifouling-antibacterial Dual Functional Polymer Coating via Dopamine-based Multiple Interactions

doi:10.7503/cjcu20200567

Abstract

Abstract:

Biomedical device relating bacterial colonization has become a severe issue in clinical practice. To prevent the formation of bacterial biofilm， we develop a facile and versatile one-step codeposition method to readily fabricate an antifouling-antibacterial dual functional polymer coating by virtue of multiple interactions between dopamine derivatives and primary amines in zwitterionic polymer（PMA） and carboxymethyl chitosan（CMC）. The presence of DA drives the codeposition of polydopamine（PDA）， CMC and PMA， endowing the coating with good durability. While the multiple interactions among CMA， PMA and DA， i.e. hydrogen bonding， Michael addition and/or Schiff base reacions， are beneficial to regulate the oxidation and self- aggregation of DA， eventually achieving a uniformly codeposited polymer coating. Due to the coexistance of zwitterionic antifouling moieties and bactericidal CMC， the resultant CMC-PMA-PDA coating both has the capacity of resisting bacterial adhesion and killing the bacteria adhered on its surface， effectively inhibiting the bacteria biofilm formation.

Key words: Dopamine, Codeposition, Multiple interaction, Antifouling-antibacteria, Biomimetic coating

CLC Number:

O647

TrendMD:

WANG Yupeng, ZHAO Yang, LI Mohan, SHI Suqing, GONG Yongkuan. Fabrication of Antifouling-antibacterial Dual Functional Polymer Coating via Dopamine-based Multiple Interactions[J]. Chem. J. Chinese Universities, 2021, 42(3): 811.

Figures/Tables 10

References 32

3	Costerton J. W.， Stewart P. S.， Greenberg E. P.， Science，1999， 284， 1318—1322
4	Busscher H. J.， Ploeg R. J.， van der Mei H. C.， Biomaterials，2009，27（1）， 4247—4248
5	Francolini I.， Donelli G.， FEMA Immunol. Med. Microbiol.， 2010， 59， 227—238
6	Banerjee I.， Pangul R. C.， Kane R. S.， Adv. Mater.， 2011， 23， 690—718
7	Ghilini F.， Pissinis D. E.， Minan A.， Schilardi P. L.， Diaz C.， ACS Biomater. Sci. Eng.，2019，5， 4920—4936
8	Zander Z. K.， Becker M. L.， ACS Macro Lett.， 2018， 7，16—25
9	Wei Q.， Becherer T.， Mutiha R.， Noeska P. M.， Paulus F.， Haag R.， Grunwald I.， Biomacromolecules， 2014， 15， 3061—3071
10	Zhang C.， Li H. N.， Du Y.， Ma M. Q.， Xu Z. K.， Langmuir， 2017， 54， 5959—5967
11	Cheng G.， Zhang Z.， Chen S.， Bryers J. D.， Jiang S.， Biomaterials， 2007， 28， 4192—4199
12	Ma J.， Lin W.， Xu X.， Liu S.， Xue W.， Chen S.， Langmuir， 2020， 12， 3251—3259
13	Zhao Y.， Wen J.， Ge Y.， Zhang X.， Shi H.， Yang K.， Gao X.， Shi S.， Gong Y.， Appl. Surf. Sci.，2019， 469， 720—730
14	Ding X.， Duan S.， Ding X.， Liu R.， Xu F. J.， Adv. Fun. Mater.，2018， 28， 1802140
15	Zhang P.， Li S.， Chen H.， Wang X.， Liu L.， Lv F.， Wang S.， ACS Appl. Mater. Interfaces， 2017， 9， 16933—16938
16	Wei T.， Tang Z.， Yu Q.， Chen H.， ACS Appl. Mater. Interfaces， 2017， 9， 37511—37523
17	Qu Y.， Zhao J.， Wei T.， Jiang S.， Yang P.， Yu Q.， Chen H.， J. Mater. Chem. B， 2018， 6， 3946—3955
18	Li Y.， Zhu Y.， Meng L.， Wei W.， Luo J.， Liu X. Y.， Chem. J. Chinese Universities， 2018， 39（6）， 1326—1333 （李杨，朱叶，孟龙，魏玮，罗静，刘晓亚. 高等学校化学学报， 2018， 39（6）， 1326—1333）
19	Wu C.， Schwibbert K.， Achazi K.， Landsberger P.， Gorbushina A.， Haag R.， Biomacromolecules， 2017， 18， 210—216
20	Wong S. Y.， Moskowitz J. S.， Veselinovic J.， Rosario R. A.， Timachova K.， Blaisse M. R.， Fuller R. C.， Klibanov A. M.， Hammond R. T.， J. Am. Chem. Soc.， 2010， 132， 17840—17848
21	Su C.， Hu Y.， Song Q.， Ye Y.， Gao L.， Li P.， Ye T.， ACS Appl. Mater. Interfaces，2020， 12， 18978—18986
22	Zhi Z.， Su Y.， Xi Y.， Tian L.， Xu M.， Wang Q.， Padidan S.， Li P.， Huang W.， ACS Appl. Mater. Interfaces，2017， 9， 10383—10397
23	Hadjesfandiari N.， Weinhart M.， Kizhakkedathu J. N.， Haag R.， Brooks D. E.， Adv. Healthcare Mater.， 2018， 7， 1700819
24	Su Y.， Feng T.， Feng W.， Pei Y.， Li Z.， Huo J.， Xie C.， Qu X.， Li P.， Huang W.， Macromol. Rapid Commun.， 2019， 40， 1900268
25	Xin X.， Li P.， Zhu Y.， Shi L.， Yuan J.， Shen J.， Langmuir，2019， 1788—1797
26	Cheng W.， Yang C.， Ding X.， Engler A.C.， Hedrick J. L.， Ynag Y. Y.， Biomacromolecules， 2015， 16， 1967—1977
27	Fullenkamp D. E.， Rivera J. G.， Gong Y. K.， Lau K. H. A.， He L.， Varshney R.， Messersmith P. B.， Biomateials， 2012， 33， 3783—3791
28	Yang C.， Ding X.， Ono R. J.， Lee H.， Hsu L. Y.， Tong Y. W.， Hedrick J.， Yang Y. Y.， Adv. Mater.，2014， 26， 7346—7351
29	Xu G.， Liu P.， Pranantyo D.， Neoh K. G.， Kang E. T.， Teo S. L.， ACS sustainable Chem. Eng.， 2019， 7， 1786—1795
30	Zangmeister R. A.， Morris T. A.， Tarlov M. J.， Langmuir， 2013， 29， 8619—8628
31	Qiu W. Z.， Wu G. P.， Xu Z. K.， ACS Appl. Mater. Interfaces，2018， 10， 5902—5908
1	Magill S. S.， Edwards J. R.， Bamberg W.， Beldavs Z. G.， Dumyati G.， Kainer M. A.， Lynfield R.， Maloney M.， McAllisterHollod L.， Nadle J.， Ray S. M.， Thompson D. L.， Wilson L. E.， Fridkin S. K.， Engl. J. Med.，2014，370（13）， 1198—1208
2	Pronovost P.， Needham D.， Berenholtz S.， Sinopoli D.， Chu H.， Cosgrove S.， Sexton B.， Hyzy R.， Welsh R.， Roth G.， Bander J.， Kepros J.， Goeschel C.， Engl. J. Med.， 2006， 355（26）， 2725—2732
32	Zhang H.， Bian C.， Jackson J. K.， Khademolhosseini F.， Burt H. M.， Chiao M.， ACS Appl. Mater. Interfaces，2014， 6， 9126—9133

Sample	Atomic fraction(%)				N_402.4/P
Sample	C	O	N	P	N_402.4/P
Bare PP	99.1	0.9	—	—	—
PDA@PP	74.0	19.7	6.3	—	—
CMC?PDA@PP	76.1	19.0	4.9	—	—
PMA?PDA@PP	74.3	19.1	4.8	1.8	0.94
CMC?PMA?PDA@PP	81.0	14.7	3.5	0.8	0.91
CMC?PMA@PP	93.0	4.8	2.0	0.2	0.93

Sample	Atomic fraction(%)				N_402.4/P
Sample	C	O	N	P	N_402.4/P
Bare PP	99.1	0.9	—	—	—
PDA@PP	74.0	19.7	6.3	—	—
CMC?PDA@PP	76.1	19.0	4.9	—	—
PMA?PDA@PP	74.3	19.1	4.8	1.8	0.94
CMC?PMA?PDA@PP	81.0	14.7	3.5	0.8	0.91
CMC?PMA@PP	93.0	4.8	2.0	0.2	0.93

Sample	Atomic fraction of N₁_s(%)
Sample	398.6 eV	399.9 eV	401.6 eV	402.4 eV
PDA@PP	7.4	69.5	23.1	—
CMC?PDA@PP	9.5	60.3	30.2	—
PMA?PDA@PP	15.6	48.7	5.7	30.0
CMC?PMA?PDA@PP	11.0	50.7	14.9	23.4

Sample	Atomic fraction of N₁_s(%)
Sample	398.6 eV	399.9 eV	401.6 eV	402.4 eV
PDA@PP	7.4	69.5	23.1	—
CMC?PDA@PP	9.5	60.3	30.2	—
PMA?PDA@PP	15.6	48.7	5.7	30.0
CMC?PMA?PDA@PP	11.0	50.7	14.9	23.4

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