[Healing of Critical-Size Bone Defects with Tricalcium Phosphate Hydrogel: Evaluation of Hydrogel as a Scaffold for Stem Cells and BMP-2].

IF 0.4 4区医学 Q4 ORTHOPEDICS

Acta chirurgiae orthopaedicae et traumatologiae Cechoslovaca Pub Date : 2024-01-01 DOI:10.55095/ACHOT2024/049

M Korbel, L Novotný, L Jandová, P Šponer

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引用次数: 0

Abstract

Purpose of the study: The preclinical study aimed to compare the healing of segmental bone defects treated with biodegradable hyaluronic acid and tricalcium phosphate-based hydrogel with the established autologous spongioplasty. Another aim was to evaluate the hydrogel as a scaffold for osteoinductive growth factor of bone morphogenetic protein-2 (BMP-2) and stem cells.

Material and methods: The study was conducted in an in vivo animal model. A standardized rabbit model of a 15 mm long segmental bone defect of left radius was used. A total of 40 animals were divided into 5 groups of 8 individuals. In the KO- (negative control) group, the created defect was left to heal spontaneously. In the KO+ (positive control) group, the defect was filled with morselized bone autograft prepared from the resected segment. In the study group A, the defect was filled with hydrogel based on hyaluronic acid derivative and tricalcium phosphate. In the study group B, the defect was filled with hydrogel based on hyaluronic acid derivative, tricalcium phosphate and bone marrow aspirate. In the study group C, the defect was filled with hydrogel based on hyaluronic acid derivative, tricalcium phosphate, bone marrow aspirate and BMP-2. Healing was assessed using radiographs at 1, 6, and 12 weeks postoperatively and histology specimens were collected at 16 weeks postoperatively.

Results: Altogether 35 rabbits survived (KO- 7, KO+ 7, A 7, B 6, C 8) until the end of the study. As concerns the radiographic assessment, the best results were achieved by the groups KO+ and C, where new bone formation across the entire width of the bone defect was clearly seen at 6 and 12 weeks and the osteotomy line was completely healed too. At 12 weeks, complete bone remodelling was observed in all animals in the group KO+, whereas in the group C, bone remodelling was fully completed in 5 animals and partially completed in 3 animals. In terms of histological assessment, however, the best results were achieved by the group C, where the bone defect was completely remodelled into lamellar bone in 7 specimens, while in 1 specimen it healed with bony callus formation. In the group KO+, the defect was healed in 4 specimens by cartilaginous callus with loci of remodelling into bony callus, in 2 specimens the bony callus was predominant with cartilaginous callus areas, and only one defect was completely remodelled into lamellar bone.

Discussion: Compared to autografts that manifest osteogenic, osteoinductive and osteoconductive properties, the biodegradable hyaluronic acid and tricalcium phosphate-based hydrogel has osteoconductive properties only. Thus, it was also tested in our study as a scaffold for bone marrow cells and BMP-2 osteoinductive growth factor. Thanks to its semi-liquid properties, the biodegradable hyaluronic acid and tricalcium phosphate-based hydrogel is a promising material for use in 3D printing.

Conclusions: The preclinical study in an in vivo animal model confirmed the beneficial effect of the biodegradable hyaluronic acid and tricalcium phosphate-based hydrogel on the healing of critical-size segmental bone defects. Better healing of these defects was also confirmed for filling composed of hydrogel and BMP-2 osteoinductive growth factor. The benefit of bone marrow aspirate mixed with hydrogel was not confirmed.

Key words: bone defect, non-union, rabbit, hyaluronic acid, calcium phosphate, stem cells, BMP-2, scaffold, bone healing, spongioplasty.

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磷酸三钙水凝胶修复临界尺寸骨缺损：水凝胶作为干细胞和BMP-2支架的评价

研究目的：本临床前研究旨在比较生物可降解透明质酸和磷酸三钙基水凝胶与已建立的自体海绵成形术治疗节段性骨缺损的愈合情况。另一个目的是评估水凝胶作为骨形态发生蛋白-2 （BMP-2）骨诱导生长因子和干细胞的支架。材料与方法：采用活体动物模型。采用标准化兔左桡骨段性骨缺损模型。40只动物被分成5组，每组8只。在KO-（阴性对照）组中，留下的缺损自行愈合。在KO+（阳性对照）组中，用切除节段制备的块状自体骨移植物填充缺损。A组用透明质酸衍生物和磷酸三钙为基础的水凝胶填充缺损。B组采用透明质酸衍生物、磷酸三钙和骨髓抽液为基础的水凝胶填充缺损。C组采用透明质酸衍生物、磷酸三钙、骨髓抽液和BMP-2为基础的水凝胶填充缺损。术后1周、6周和12周采用x线片评估愈合情况，术后16周采集组织学标本。结果：共有35只家兔（KO- 7、KO+ 7、a7、b6、c8）存活至研究结束。在影像学评估方面，KO+组和C组取得了最好的结果，在6周和12周时，可以清楚地看到整个骨缺损宽度的新骨形成，截骨线也完全愈合。12周时，KO+组所有动物骨重建完全，而C组5只动物骨重建完全，3只动物骨重建部分完成。组织学评价方面，C组效果最好，7例骨缺损完全重塑为板层骨，1例骨缺损愈合形成骨痂。在KO+组中，4例骨缺损以软骨骨痂愈合，并有骨痂重塑位点，2例骨痂以软骨骨痂区为主，仅有1例骨缺损完全重塑为板层骨。讨论：与具有成骨、骨诱导和骨导电性的自体移植物相比，可生物降解的透明质酸和磷酸三钙基水凝胶仅具有骨导电性。因此，在我们的研究中也测试了它作为骨髓细胞和BMP-2骨诱导生长因子的支架。由于其半液体的特性，可生物降解的透明质酸和磷酸三钙基水凝胶是一种很有前途的3D打印材料。结论：在体内动物模型的临床前研究证实了可生物降解透明质酸和磷酸三钙基水凝胶对临界尺寸节段性骨缺损愈合的有益作用。水凝胶和BMP-2骨诱导生长因子的充填也能较好地修复这些缺损。骨髓抽吸液与水凝胶混合的益处尚未得到证实。关键词：骨缺损，骨不连，兔，透明质酸，磷酸钙，干细胞，BMP-2，支架，骨愈合，海绵成形术。

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来源期刊

Acta chirurgiae orthopaedicae et traumatologiae Cechoslovaca ORTHOPEDICS-

CiteScore

0.70

自引率

25.00%

发文量

期刊介绍： Editorial Board accepts for publication articles, reports from congresses, fellowships, book reviews, reports concerning activities of orthopaedic and other relating specialised societies, reports on anniversaries of outstanding personalities in orthopaedics and announcements of congresses and symposia being prepared. Articles include original papers, case reports and current concepts reviews and recently also instructional lectures.