UHMWPE人工髋关节的接枝改性进展

doi:10.11896/cldb.19100073

Abstract
Figure/Table
References
Related Citation (15)

Download:

Full Text ( PDF ) (4866KB)
Export: BibTeX | EndNote (RIS)

Abstract With the aging of the population and the younger of the disease, the number of hip joint lesions, such as femoral head necrosis, arthritis, etc, has rised over the years, because of which the pain and inconvenience of the patients are increased. But an effective way for patients to eliminate pain, resume normal joint activity and function is provides by artificial hip replacement.
At present, the commonly used artificial hip joint is composed of liner made of Ultra?high molecular weight polyethylene(UHMWPE) and femoral head made of metal. UHMWPE has the advantages of good mechanical properties, wear resistance and biocompatibility, by contrary, UHMWPE is still the weakest component part in artificial joints, its wear particles are produced due to continuously contact friction with metals, which further leads to osteolysis and aseptic loosening, until inflammation.For this proble, UHMWPE is modified by filling nano?materials and irradiation crosslinking, and the post?treatment process is included. Although the wear resistance of UHMWPE is improved to a certain extent by the special structure of nano?filler and transformation from the linear UHMWPE to three?dimensional crosslinked network, the wear particles are not elimi?nated, the biocompatibility is not improved significantly, and the degree of modification is limited by the decline of mechanical properties. Subsequently, chemical grafting modification technology of UHMWPE is applied. By grafting, the lubrication, wear resistance of the matrix are improved, and the mechanical properties of matrix are affected faintly, the structure similar to natural cartilage is obtained, thus the service life of the artificial joint is prolonged.
In this paper, the principle of irradiation modification, grafting modification of UHMWPE and hydration lubrication of polymer brushes are introduced. Then, the grafting modification methods of 2?methacryloxyethyl phosphatidylcholine (MPC), sulfobetaine (SB), polyvinyl alcohol hydrogel (PVA?H) and other organic compounds on UHMWPE, and their effects on lubrication, friction and wear, biocompatibility are introduced in detail. The clinical results of UHMWPE, cross?linked UHMWPE and grafted UHMWPE are compared simply. Finally, the future research of hip pro?sthesis in the liner, femoral head and clinical application is expected.

Key words： artificial hip joint grafting hydration lubrication friction zwitterionic hydrogel

Published: 25 June 2021

CLC number:

TQ322.3

Fund:This work was financially supported by the Project of Hebei Science and Technology Department(18211235).

About author:: Huijuan Sun, Master of Materials Science, Chemical Engineer. She is currently a lecturer in Hengshui University and her research direction is the processing and application of macromolecule materials.

	Service
	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	SUN Huijuan

Cite this article:

SUN Huijuan. Progress in Graft Modification of Ultra-high Molecular Weight Polyethylene Artificial Hip Joint[J]. Materials Reports, 2021, 35(11): 11208-11214.

URL:

http://www.mater-rep.com/EN/10.11896/cldb.19100073 OR http://www.mater-rep.com/EN/Y2021/V35/I11/11208

1	Zhang R M, Liu Z Q, Zhou Q X, et al. China Safety Science Journal,2018,28(8),75(in Chinese).
	张睿明,柳忠起,周前祥,等.中国安全科学学报,2018,28(8),75.
2	Chen K, Yang X H, Zhang D K, et al. Wear,2017,376,329.
3	Newman J M, Khlopas A, Chughtai M, et al. The Journal of Hip Surgery,2017,1(1),14.
4	Kumar E G M, Kumar G M Y, Noorudheen M. International Journal of Research in Orthopaedics,2018,4(2),333.
5	Altay M, Demirkale i, ?atma M F, et al. Indian Journal of Orthopaedics,2018,52(4),374.
6	Lyman S, Lee Y Y, Franklin P D, et al. Clinical Orthopaedics and Rela?ted Research,2016,474(6),1472.
7	Le Manach Y, Collins G, Bhandari M, et al. Jama,2015,314(11),1159.
8	Rutherford M, Khan R J K, Fick D P, et al. International Orthopaedics,2019,43(4),71.
9	Oommen A T, Krishnamoorthy V P, Poonnoose P M, et al. Indian Journal of Orthopaedics,2015,49(2),181.
10	Ishihara K. Polymer Journal,2015,47(9),585.
11	Ai C C, Jiang J, Chen S Y. Fudan University Journal of Medical Sciences,2016,43(6),717(in Chinese).
	艾承冲,蒋佳,陈世益.复旦学报(医学版),2016,43(6),717.
12	Gul R M, Fung K, Doshi B N, et al. Journal of Orthopaedic Research,2017,35(11),2551.
13	Heath D E, Cooper S L. Journal of Biomaterials Science, Polymer Edition,2017,28(10?12),1051.
14	Chukov D I, Stepashkin A A, Maksimkin A V, et al. Composites Part B: Engineering,2015,76,79.
15	Gu J W, Li N, Tian L D, et al. RSC Advances,2015,5(46),36334.
16	Wroblewski B M, Siney P D, Fleming P A. Charnley low?frictional torque arthroplasty of the hip, Springer, Cham Publishing, Switzerland,2016.
17	Wang H L, Xu L, Li R, et al. Applied Surface Science,2016,382,162.
18	Bian Y Y, Zhou L, Zhou G, et al. Journal of the Mechanical Behavior of Biomedical Materials,2018,82,87.
19	Niemczewska?Wójcik M. Measurement,2017,107,89.
20	Jalali?Vahid D, Jagatia M, Jin Z M, et al. Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology,2001,215(4),363.
21	Li B Y, Li M J, Fan C, et al. Composites Science and Technology,2015,106,68.
22	Sakai N, Yarimitsu S, Sawae Y, et al. Biosurface and Biotribology,2019,5(1),13.
23	Porte E, Cann P, Masen M. Journal of the Mechanical Behavior of Biomedical Materials,2019,90,284.
24	Su D S, Perathoner S, Centi G. Chemical Reviews,2013,113(8),5782.
25	Chen W, Duan H T, Gu K L, et al. Polymer Materials Science & Engineering,2015,31(8),62(in Chinese).
	陈雾,段海涛,顾卡丽,等.高分子材料科学与工程,2015,31(8),62.
26	Luo Y L, Zhao Z X. Polymer Bulletin,1999(4),88(in Chinese).
	罗延龄,赵振兴.高分子通报,1999(4),88.
27	Tamboli S M, Mhaske S T, Kale D D. Indian Journal of Chemical Technology,2004,11,853.
28	Sirimamilla A, Rimnac C M. Journal of the Mechanical Behavior of Biomedical Materials,2019,91,366.
29	Ansari F, Ries M D, Pruitt L. Journal of the Mechanical Behavior of Biomedical Materials,2016,53,329.
30	Kurtz S M. UHMWPE biomaterials handbook, William Andrew Publi?shing, USA,2016.
31	Medel F J, Pena P, Cego?ino J, et al. Journal of Biomedical Materials Research Part B,2007,83(2),380.
32	Gul R M, Fung K, Doshi B N, et al. Journal of Orthopaedic Research,2017,35(11),2551.
33	Bellare A, Dorfman R, Samuel A, et al. Journal of the Mechanical Behavior of Biomedical Materials,2016,61,493.
34	Oral E, Neils A L, Doshi B N, et al. Journal of Biomedical Materials Research Part B: Applied Biomaterials,2016,104(2),316.
35	Wang H L, Xu L, Hu J T, et al. Radiation Physics and Chemistry,2015,115,88.
36	Moro T, Kawaguchi H, Ishihara K, et al. Biomaterials,2009,30(16),2995.
37	Ma S, Zhang X Q, Yu B, et al. NPG Asia Materials,2019,11(1),24.
38	Kyomoto M, Moro T, Konno T, et al. Journal of Materials Science: Materials in Medicine,2007,18(9),1809.
39	Ishikawa Y, Hiratsuka K I, Sasada T. Wear,2006,261(5),500.
40	Briscoe W H, Titmuss S, Tiberg F, et al. Nature,2006,444(7116),191.
41	Xiong D S, Deng Y L, Wang N, et al. Applied Surface Science,2014,298,56.
42	Tanaka M, Iwasaki Y. Acta Biomaterialia,2016,40,54.
43	Chantasirichot S, Inoue Y, Ishihara K. Polymer,2015,61,55.
44	Lewis A L, Stratford P W. Journal of Long?Term Effects of Medical Implants,2017,27(2?4),233.
45	Wang W, Lee C, Pastuszka M, et al. Pharmaceutics,2019,11(5),221.
46	Sasso E D, Bagno A, Scuri S T G, et al. Annual Review of Biomedical Engineering,2019,21,85.
47	Azuma T, Ohmori R, Teramur A Y, et al. Colloids and Surfaces B: Biointerfaces,2017,159,655.
48	Zhao J, Chai Y D, Zhang J, et al. Acta Biomaterialia,2015,16,94.
49	Xie G Y, Ma C P, Zhang X Q, et al. Colloids and Surfaces B: Biointerfaces,2017,157,166.
50	Ishihara K. Journal of Biomedical Materials Research Part A,2019,107(5),933.
51	Bito K, Hasebe T, Maegawa S, et al. Acta Biomaterialia,2019,87,187.
52	Tang B Z, Abd?El?Aziz A S, Craig S, et al. Phosphorus?Based Polymers: From Synthesis to Applications, Royal Society of Chemistry Publishing, UK,2014.
53	Kyomoto M, Moro T, Yamane S, et al. Journal of Biomedical Materials Research Part A,2014,102(9),3012.
54	Moro T, Takatori Y, Kyomoto M, et al. Journal of Orthopaedic Research,2014,32(3),369.
55	Moro T, Takatori Y, Ishihara K, et al. Nature Materials,2004,3(11),829.
56	Takatori Y, Moro T, Kamogawa M, et al. Journal of Artificial Organs,2013,16(2),170.
57	Kyomoto M, Moro T, Yamane S, et al. Biomaterials,2014,35(25),6677.
58	Kyomoto M, Moro T, Yamane S, et al. Biomaterials,2017,112,122.
59	Kyomoto M, Moro T, Yamane S, et al. Journal of the Mechanical Beha?vior of Biomedical Materials,2018,79,203.
60	Yarimitsu S, Moro T, Kyomoto M, et al. Proceedings of the Institution of Mechanical Engineers,Part H: Journal of Engineering in Medicine,2015,229(7),506.
61	Moro T, Takatori Y, Tanaka S, et al. Journal of Orthopaedic Research,2017,35(9),2007.
62	Kurtz S M, Gawel H A, Patel J D. Clinical Orthopaedics and Related Research??,2011,469(8),2262.
63	Ye T T, Deng Q Y, Ma D L, et al. International Journal of Modern Phy?sics B,2019,33(1?3),1940056.
64	Sawano H, Warisawa S, Ishihara S. Wear,2010,268(1?2),233.
65	Zou H B, Chen N N, Shi M X, et al. Applied Microbiology and Biotechnology,2016,100(9),3865.
66	Wei X Z, Kong X, Wang S X, et al. Journal of Functional Materials,2014,45(2),2007(in Chinese).
	魏秀珍,孔新,王松雪,等.功能材料,2014,45(2),2007.
67	Gallardo A, Martínez?Campos E, García C, et al. Biomacromolecules,2017,18(5),1521.
68	Li Z S, Li J F, Liu H, et al. Chemical Industry and Engineering Progress,2018,37(12),4719(in Chinese).
	李兆双,李建芳,刘鹤,等.化工进展,2018,37(12),4719.
69	Laschewsky A. Polymers,2014,6(5),1544.
70	Yan S P, Zhang C, Lyu H. Journal of Functional Polymers,2019,32(4),1(in Chinese).
	闫树鹏,张冲,吕华.功能高分子学报,2019,32(4),1.
71	Kwon H J, Lee Y, Seon G M, et al. Acta Biomaterialia,2017,61,169.
72	Iqbal Z, Kim S, Moyer J, et al. Journal of Biomaterials Applications,2019,34(2),297.
73	Li Q, Imbrogno J, Belfort G, et al. Journal of Applied Polymer Science,2015,132(21),41781.
74	Tanaka M, Ogawa Y, Hirata Y, et al. Sensors and Materials,2019,31(1),33.
75	Deng Y L, Xiong D S, Wang K. Journal of Materials Science: Materials in Medicine,2013,24(9),2085.
76	Mu R H, Lai X J, Wang L, et al. Chemical Industry and Engineering Progress,2019,38(7),3377(in Chinese).
	穆瑞花,赖小娟,王磊,等.化工进展,2019,38(7),3377.
77	Deng Y L, Xiong D S, Shao S L. Materials Science and Engineering: C,2013,33(3),1339.
78	Deng Y L, Xiong D S, Wang K. Journal of the Mechanical Behavior of Biomedical Materials,2014,35,18.
79	Lim C M, Hur J, Jang H, et al. Acta Biomaterialia,2019,85,180.
80	Lim C M, Seo J, Jang H, et al. Applied Surface Science,2018,452,102.
81	Park H H, Ko S C, Oh G W, et al. Carbohydrate Polymers,2018,198,197.
82	Gong G S, Liu J B, Zhong Y P, et al. Chemical Industry and Engineering Progress,2016,35(8),2507(in Chinese).
	龚桂胜,刘景勃,钟玉鹏,等.化工进展,2016,35(8),2507.
83	Chen K, Zhang D K, Cui X T, et al. RSC Advances,2015,5(31),24215.
84	Chen K, Zhang D K, Yang X H, et al. Soft Materials,2016,14(4),244.
85	Xia B, Xie M J, Yang B C. Journal of Biomedical Materials Research Part A,2013,101(1),54.
86	Xie M J, Yu Z L, Yang B C. Chemical Research and Application,2016,28(5),644(in Chinese).
	谢美菊,余自力,杨帮成.化学研究与应用,2016,28(5),644.
87	Aziz G, De Geyter N, Declercq H, et al. Surface and Coatings Techno?logy,2015,271,39.
88	Deng Y L, Xiong D S. Journal of Polymer Research,2015,22(10),195.