PLG-g-TA/RGD Enzyme-catalyzed Crosslinked Hydrogel for Adhesion and Three-dimensional Culture of Hyaline Chondrocytes †

doi:10.7503/cjcu20190148

Abstract

Abstract:

A novel enzyme-catalyzed cross-linking hydrogel based on poly(L-glutamic acid)-g-tyramine/cRGDfk cyclic peptide(PLG-g-TA/RGD) was prepared for the investigation of adhesion and the three-dimensional culture of hyaline chondrocytes. PLG-g-TA/RGD polymers could form a hydrogel by self-crosslinking of the tyrosine group rapidly in the presence of horseradish peroxidase(HRP) and hydrogen peroxide(H₂O₂). The further research results showed that both the gelation time and gel mechanical strength were significantly enhance with the presence of cRGDfk. More hyaline chondrocytes adhered to the surface of the cRGDfk containing hydrogel compared to the control group after incubation of 3 d. The proliferation efficiency of hyaline chondrocyte in PLG-g-TA/RGD hydrogel was significantly higher than PLG-g-TA formed hydrogel after culture with 1, 4 and 7 d, respectively. The results of the cells indicated that the obtained materials exhibited a good cell compatibility. Above all, the introduction of cRGDfk promotes the adhesion and proliferation of hyaline chondrocytes, and showed the potential application of the original PLG-g-TA/RGD hydrogel in the field of three-dimensional cell culture.

Key words: Cyclicpeptide, Enzyme-catalyzed cross-linking, Cell adhesion, Three-dimensional cell culture, Poly(L-glutamic acid)-g-tyramine

CLC Number:

O631

TrendMD:

WEN Jing, XU Zhimin, QI Desheng, WANG Jiayu, YU Shuangjiang, HE Chaoliang, HAN Bing. PLG-g-TA/RGD Enzyme-catalyzed Crosslinked Hydrogel for Adhesion and Three-dimensional Culture of Hyaline Chondrocytes ^†[J]. Chem. J. Chinese Universities, 2019, 40(9): 2020.

Figures/Tables 10

Sample	PLG degree of polymerization	TA content (%)	RGD grafting rate(%)
PLG-g-TA	90	9.4	0
PLG-g-TA/RGD	90	9.4	0.8

Fig.1 1H NMR spectra of the polymer a. BLG-NCA, CDCl3-d; b. PBLG, TFA-d; c. PLG, D2O; d. PLG-g-TA, D2O; e. PLG-g-TA/RGD, D2O. a—k are the peaks corresponding to the positions in Scheme 2.

Fig.2 Gel-forming photographs of PLG-g-TA(A) and PLG-g-TA/RGD(B) polymer solution after enzyme-catalyzed reaction

Fig.3 Gelation time of PLG-g-TA/RGD polymers solution(HRP concentration was fixed at 3.2 Unit/mL as the polymer concentration changes, and the molar ratio of H2O2 to TA was fixed 0.4)(A), PLG-g-TA polymers solution(as the polymer concentration changes, the HRP concentration was fixed at 3.2 Unit/mL, and the molar ratio of H2O2 to TA was fixed at 0.4)(B) and rheological diagram of PLG-g-TA/RGD and PLG-g-TA hydrogels(the final concentration of the polymer was 40.0 g/L, the HRP concentration was fixed at 3.2 Unit/mL, and the molar ratio of H2O2 to TA was fixed at 0.4)(C)

Fig.4 P1 generation of rabbit hyaline chondrocytes

Fig.5 Cell compatibility of the co-culture of the hydrogel leaching solution and L929 cells for 48 h(n=3)(A), proliferation of hyaline chondrocytes cells in hydrogel(n=3)(B) * P<0.05; ** P<0.01; *** P<0.001.

Fig.6 Adhesion behavior of cells on the surface of PLG-g-TA hydrogel(A) and adhesion behavior of cells on the PLG-g-TA/RGD hydrogel(B)

Fig.7 Staining of chondrocytes cultured in hydrogels for 7 d Live cells were stained green by Calcein-AM, dead cells were dyed red by PI. (A) Chondrocytes survived inside the PLG-g-TA/RGD hydrogel; (B) chondrocytes survived within the PLG-g-TA hydrogel.

References 32

[1]	Aamodt J. M., Grainger D. W ., Biomater. 2016, 86, 68— 82
[2]	Frantz C., Stewart K. M., Weaver V. M., ,J. Cell Sci., 2010, 123( 24), 4195— 4200
[3]	Theocharis A. D., Skandalis S. S., Gialeli C., Karamanos N. K., ,Adv. Drug Deliv. Rev., 2016, 97, 4— 27
[4]	Berrier A. L., Yamada K. M., ,J. Cellular Physio., 2010, 213( 3), 565— 573
[5]	Zhu C., Ma X., Xian L., Zhou Y., Fan D., ,Biomed. Mater. Eng., 2014, 24( 6), 1999— 2005
[6]	Bracaglia L. G., Fisher J. P., ,Adv. Healthc. Mater., 2015, 4( 16), 2475— 2487
[7]	Orive G., Santos E., Poncelet D., Hernández R. M., Pedraz J. L., Wahlberg L. U., De Vos. P., Emerich D., ,Trends. Pharmacol. Sci., 2015, 36( 8), 537— 546
[8]	El-Sherbiny I. M., Yacoub M. H., ,Glob. Cardiol. Sci. Pract., 2013, 2013( 3), 316— 342
[9]	Wade R. J., Bassin E. J., Gramlich W. M., Burdick J. A., ,Adv. Mater., 2015, 27( 8), 1356— 1362
[10]	Nam S., Stowers R., Lou J., Xia Y., Chaudhuri O ., Biomaterial 2019, 200, 15— 24
[11]	Rossi F., Van G. M., ,. Tissue. Eng. Part A 2014, 20( 15/16), 2043— 2051
[12]	Cui G. L., Dan N. H., Dan W. H., ,Chem. J. Chinese Universities, 2017,38( 2), 318— 325
	(崔国廉, 但年华, 但卫华. 高等学校化学学报, 2017, 38(2), 318— 325)
[13]	Collier J. H., Segura T ., Biomaterial 2011, 32( 18), 4198— 4204
[14]	Bellis S. L ., Biomaterial 2011, 32( 18), 4205— 4210
[15]	Hosseinkhani H., Hiraoka Y., Li C. H., Chen Y. R., Yu D. S., Hong P. D., Ou K. L., ,ACS Chem. Neurosci., 2013, 4( 8), 1229— 1235
[16]	Yu G. H., Ji J., Wang A. D., Shen J. C., ,Chem. J. Chinese Universities, 2005,26( 6), 1156— 1161
	(余贯华, 计剑, 王东安, 沈家骢. 高等学校化学学报, 2005, 26(6), 1156— 1161)
[17]	Sacchetti A., Mauri E., Sani M., Masi M., Rossi F., ,. Tetrahedron Letters 2014, 55( 50), 6817— 6820
[18]	Gould S. T., Darling N. J., Anseth K. S., ,Acta Biomater., 2012, 8( 9), 3201— 3209
[19]	Qu C., Bao Z., Zhang X., Wang Z., Ren J., Zhou Z., Tian M., Cheng X., Chen X., Feng C., ,Int. J. Biol. Macromol., 2019, 125, 78— 86
[20]	Dhillon J., Young S. A., Sherman S. E., Bell G. I., Amsden B. G., Hess D. A., Flynn L. E ., J. Biomed. Mater. Res. A 2019, 107( 3), 571— 585
[21]	Kung F. C., ,Biomed. Mater. Eng., 2018, 29( 2), 241— 251
[22]	Adibi-Motlagh B., Lotfi A. S., Rezaei A., Hashemi E ., Mater. Sci. Eng. C: Mater. Biol. Appl., 2018, 82, 323— 329
[23]	Hersel U., Dahmen C., Kessler H ., Biomaterial 2003, 24( 24), 4385— 4415
[24]	Xu Q., Zhang Z., Xiao C., He C., Chen X ., Biomacromol. 2017, 18( 4), 1411— 1418
[25]	Lee J. W., Kim H., Lee K. Y., ,Carbohydr. Polym., 2016, 139, 82— 89
[26]	Liu Y. F., Fan Z. H., Wang Y. Y., Yu L. M., ,J. Biomed. Eng., 2015, 32( 2), 387— 392
[27]	An H., Lee J. W., Lee H. J., Seo Y., Park H., Lee K. Y., ,Carbohydr. Polym., 2018, 197, 422— 430
[28]	Ren K. X., He C. L., Cheng Y. L., Chen X. S., ,Polym. Chem., 2014, 5( 17), 5069— 5076
[29]	Xie Y. T., Yin J. B., Zhao C. W., Chen X. S., ,Chem. J. Chinese Universities, 2008,29( 1), 197— 200
	(谢勇涛, 尹静波, 赵长稳, 陈学思. 高等学校化学学报, 2008, 29(1), 197— 200)
[30]	Zhang Z., He C L.,Xu Q. H., Zhuang X. L.,Chen X. S., . Acta Polymerica Sinica, 2018, ( 1), 99— 108
	( 张震, 贺超良, 徐清华, 庄秀丽, 陈学思 . 高分子学报, 2018, ( 1), 99— 108)
[31]	Ren K. X., Cui H., Xu Q. H., He C. L., Li G., Chen X. S ., Biomacromol 2016, 17( 12), 3862— 3871
[32]	GB/T16886.5-2003, Biological Evaluation of Medical Devices, Part 5:Test for in vitro Cytotoxicity, Standards Press of China,Beijing, 2003
	(GB/T16886. 5-2003,医疗器械生物学评价, 第5部分: 体外细胞毒性试验, 北京: 中国标准出版社, 2003)