Heterotopic mineral deposits in intact rat Achilles tendons are characterized by a unique fiber-like structure

IF 3.5 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Maria Pierantoni , Malin Hammerman , Isabella Silva Barreto , Linnea Andersson , Vladimir Novak , Hanna Isaksson , Pernilla Eliasson
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引用次数: 3

Abstract

Heterotopic mineralization entails pathological mineral formation inside soft tissues. In human tendons mineralization is often associated with tendinopathies, tendon weakness and pain. In Achilles tendons, mineralization is considered to occur through heterotopic ossification (HO) primarily in response to tendon pathologies. However, refined details regarding HO deposition and microstructure are unknown. In this study, we characterize HO in intact rat Achilles tendons through high-resolution phase contrast enhanced synchrotron X-ray tomography. Furthermore, we test the potential of studying local tissue injury by needling intact Achilles tendons and the relation between tissue microdamage and HO. The results show that HO occurs in all intact Achilles tendons at 16 weeks of age. HO deposits are characterized by an elongated ellipsoidal shape and by a fiber-like internal structure which suggests that some collagen fibers have mineralized. The data indicates that deposition along fibers initiates in the pericellular area, and propagates into the intercellular area. Within HO deposits cells are larger and more rounded compared to tenocytes between unmineralized fibers, which are fewer and elongated. The results also indicate that multiple HO deposits may merge into bigger structures with time by accession along unmineralized fibers. Furthermore, the presence of unmineralized regions within the deposits may indicate that HOs are not only growing, but mineral resorption may also occur. Additionally, phase contrast synchrotron X-ray tomography allowed to distinguish microdamage at the fiber level in response to needling. The needle injury protocol could in the future enable to elucidate the relation between local inflammation, microdamage, and HO deposition.

Abstract Image

完整大鼠跟腱异位矿物沉积具有独特的纤维样结构
异位矿化导致软组织内形成病理性矿物。在人类肌腱中,矿化通常与肌腱病、肌腱无力和疼痛有关。在跟腱中,矿化被认为是通过异位骨化(HO)发生的,主要是对肌腱病理的反应。然而,关于HO沉积和微观结构的详细信息尚不清楚。在这项研究中,我们通过高分辨率相位对比增强同步加速器X射线断层扫描来表征完整大鼠跟腱中的HO。此外,我们还测试了通过针刺完整的跟腱来研究局部组织损伤的潜力,以及组织微损伤与HO之间的关系。结果表明,HO发生在16周龄时所有完整的跟腱中。HO沉积物的特征是细长的椭圆形和纤维状的内部结构,这表明一些胶原纤维已经矿化。数据表明,沿着纤维的沉积始于细胞周围区域,并传播到细胞间区域。与未矿化纤维之间的肌腱细胞相比,HO沉积物中的细胞更大、更圆,未矿化纤维更少、更长。结果还表明,随着时间的推移,多个HO沉积物可能通过沿着未矿化纤维的加入而合并成更大的结构。此外,矿床中未矿化区域的存在可能表明HO不仅在生长,而且还可能发生矿物吸收。此外,相位对比同步加速器X射线断层扫描可以在纤维水平上区分对针刺的微观损伤。未来,针刺损伤方案可以阐明局部炎症、微损伤和HO沉积之间的关系。
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来源期刊
Journal of Structural Biology: X
Journal of Structural Biology: X Biochemistry, Genetics and Molecular Biology-Structural Biology
CiteScore
6.50
自引率
0.00%
发文量
20
审稿时长
62 days
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