Nokhbatolfoghahaei Hanieh, Bastami Farshid, Farzad-Mohajeri Saeed, Rezai Rad Maryam, Dehghan Mohammad Mehdi, Bohlouli Mahboubeh, Farajpour Hekmat, Nadjmi Nasser, Khojasteh Arash
Dental Research Center, Research Institute of Dental Sciences, Shahid Beheshti University of Medical Sciences, Tehran, Iran.
Oral and Maxillofacial Surgery Department, School of Dentistry, Shahid Beheshti University of Medical Sciences, Tehran, Iran.
J Biomed Mater Res B Appl Biomater. 2022 Jul;110(7):1675-1686. doi: 10.1002/jbm.b.35028. Epub 2022 Feb 15.
In vivo bioreactors serve as regenerative niches that improve vascularization and regeneration of bone grafts. This study has evaluated the masseter muscle as a natural bioreactor for βTCP or PCL/βTCP scaffolds, in terms of bone regeneration. The effect of pedicle preservation, along with sole, or MSC- or rhBMP2-combined application of scaffolds, has also been studied. Twenty-four mongrel dogs were randomly placed in six groups, including βTCP, βTCP/rhBMP2, βTCP/MSCs, PCL/βTCP, PCL/βTCP/rhBMP2, and PCL/βTCP/MSCs. During the first surgery, the scaffolds were implanted into the masseter muscle for being prefabricated. After 2 months, each group was divided into two subgroups prior to mandibular bone defect reconstruction; one with a preserved vascularized pedicle and one without. After 12 weeks, animals were euthanized, and new bone formation was evaluated using histological analysis. Histological analysis showed that all β-TCP scaffold groups had resulted in significantly greater rates of new bone formation, either with a pedicle surgical approach or non-pedicle surgical approach, comparing to their parallel groups of βTCP/PCL scaffolds (p ≤ .05). Pedicled β-TCP scaffold groups that were treated with either rhBMP2 (48.443% ± 0.250%) or MSCs (46.577% ± 0.601%) demonstrated the highest rates of new bone formation (p ≤ .05). Therefore, masseter muscle can be used as a local in vivo bioreactor with potential clinical advantages in reconstruction of human mandibular defects. In addition, scaffold composition, pedicle preservation, and treatment with MSCs or rhBMP2, influence new bone formation and scaffold degradation rates in the prefabrication technique.
体内生物反应器作为再生微环境,可改善骨移植的血管化和再生。本研究评估了咬肌作为β - TCP或PCL/β - TCP支架的天然生物反应器在骨再生方面的作用。还研究了带蒂保留以及单独或与MSC或rhBMP2联合应用支架的效果。将24只杂种犬随机分为六组,包括β - TCP、β - TCP/rhBMP2、β - TCP/MSC、PCL/β - TCP、PCL/β - TCP/rhBMP2和PCL/β - TCP/MSC。在第一次手术中,将支架植入咬肌进行预制。2个月后,在进行下颌骨缺损重建之前,每组再分为两个亚组;一个保留带血管蒂,一个不保留。12周后,对动物实施安乐死,并通过组织学分析评估新骨形成情况。组织学分析表明,与βTCP/PCL支架的平行组相比,所有β - TCP支架组无论采用带蒂手术方法还是不带蒂手术方法,新骨形成率均显著更高(p≤0.05)。用rhBMP2(48.443%±0.250%)或MSC(46.577%±0.601%)处理的带蒂β - TCP支架组新骨形成率最高(p≤0.05)。因此,咬肌可作为局部体内生物反应器,在人类下颌骨缺损重建中具有潜在的临床优势。此外,支架组成、带蒂保留以及用MSC或rhBMP2处理,会影响预制技术中的新骨形成和支架降解率。
