Flexible support material maintains disc height and supports the formation of hydrated tissue engineered intervertebral discs in vivo

IF 3.4 3区 医学 Q1 ORTHOPEDICS
JOR Spine Pub Date : 2024-08-05 DOI:10.1002/jsp2.1363
Alikhan B. Fidai, Byumsu Kim, Marianne Lintz, Sertac Kirnaz, Pravesh Gadjradj, Blake I. Boadi, Maho Koga, Ibrahim Hussain, Roger Härtl, Lawrence J. Bonassar
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Abstract

Background

Mechanical augmentation upon implantation is essential for the long-term success of tissue-engineered intervertebral discs (TE-IVDs). Previous studies utilized stiffer materials to fabricate TE-IVD support structures. However, these materials undergo various failure modes in the mechanically challenging IVD microenvironment. FlexiFil (FPLA) is an elastomeric 3D printing filament that is amenable to the fabrication of support structures. However, no present study has evaluated the efficacy of a flexible support material to preserve disc height and support the formation of hydrated tissues in a large animal model.

Methods

We leveraged results from our previously developed FE model of the minipig spine to design and test TE-IVD support cages comprised of FPLA and PLA. Specifically, we performed indentation to assess implant mechanical response and scanning electron microscopy to visualize microscale damage. We then implanted FPLA and PLA support cages for 6 weeks in the minipig cervical spine and monitored disc height via weekly x-rays. TE-IVDs cultured in FPLA were also implanted for 6 weeks with weekly x-rays and terminal T2 MRIs to quantify tissue hydration at study endpoint.

Results

Results demonstrated that FPLA cages withstood nearly twice the deformation of PLA without detrimental changes in mechanical performance and minimal damage. In vivo, FPLA cages and stably implanted TE-IVDs restored native disc height and supported the formation of hydrated tissues in the minipig spine. Displaced TE-IVDs yielded disc heights that were superior to PLA or discectomy-treated levels.

Conclusions

FPLA holds great promise as a flexible and bioresorbable material for enhancing the long-term success of TE-IVD implants.

Abstract Image

柔性支撑材料可保持椎间盘高度,并支持体内水合组织工程椎间盘的形成。
背景:植入后的机械增强对组织工程椎间盘(TE-IVDs)的长期成功至关重要。以往的研究利用较硬的材料来制造 TE-IVD 支撑结构。然而,这些材料在具有机械挑战性的 IVD 微环境中会出现各种失效模式。FlexiFil(FPLA)是一种弹性三维打印长丝,可用于制造支撑结构。然而,目前还没有研究评估过柔性支撑材料在大型动物模型中保持椎间盘高度和支持水合组织形成的功效:我们利用之前开发的迷你猪脊柱有限元模型的结果,设计并测试了由 FPLA 和 PLA 组成的 TE-IVD 支撑笼。具体来说,我们采用压痕法评估植入物的机械响应,并用扫描电子显微镜观察微观损伤。然后,我们在小鼠颈椎中植入FPLA和PLA支撑笼6周,并每周通过X光片监测椎间盘高度。在FPLA中培养的TE-IVD也被植入6周,每周进行一次X光检查和终端T2 MRI检查,以量化研究终点时的组织水合情况:结果表明,FPLA保持架可承受近两倍于聚乳酸的变形,而机械性能不会发生有害变化,且损伤极小。在体内,FPLA保持架和稳定植入的TE-IVDs恢复了原生椎间盘高度,并支持水合组织在迷你猪脊柱中的形成。移位的 TE-IVDs 所产生的椎间盘高度优于 PLA 或椎间盘切除术处理过的水平:FPLA作为一种灵活的生物可吸收材料,在提高TE-IVD植入物的长期成功率方面大有可为。
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来源期刊
JOR Spine
JOR Spine ORTHOPEDICS-
CiteScore
6.40
自引率
18.90%
发文量
42
审稿时长
10 weeks
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