Lenneman Cameron M, Rose Emily M, Strawska Brooke A, Tyszkiewicz Natalie A, Dean-Christie Karen, Katz Erin, Roche Joseph M, de Morree Antoine, Roche Renuka, Tulapurkar Mohan E, Roche Joseph A
Physical Therapy Program. Department of Health Care Sciences. Eugene Applebaum College of Pharmacy and Health Sciences. Wayne State University. Detroit, MI, USA.
Department of Laboratory Animal Resources (DLAR). Wayne State University. Detroit, MI, USA.
bioRxiv. 2024 May 3:2024.04.30.591971. doi: 10.1101/2024.04.30.591971.
There are currently no proven methods to reverse muscle loss in humans, which is caused by trauma (e.g., volumetric muscle loss, VML), genetic neuromuscular diseases (e.g., muscular dystrophies, MDs), and accelerated senescence (e.g., sarcopenia). Since muscle tissue is capable of regeneration through muscle satellite cells (MuSCs), the implantation of autologous (or other) donor MuSCs and MuSC-derived myoblasts into host muscles can promote donor-cell-derived myogenesis. Direct injection or implantation of MuSCs or MuSC-derived myoblasts into host muscles only promotes minimal donor-cell-derived myogenesis, whereas implantation of MuSCs/myoblasts along with associated muscle tissue (muscle fibers, extracellular matrix, neurovascular pathways, etc.) gives better results.
We aim to leverage the benefits of constraining donor myogenic cells within a template that resembles muscle tissue. In this paper, we present a workflow for basic and translational studies aimed at promoting donor-cell-derived myogenesis to increase functional muscle mass in mice. Our workflow involves preparing a slurry of 10% sodium alginate mixed with myogenic cells in cell culture media, extruding the cell-containing slurry into 10% calcium lactate to form tubes, and implanting the cellularized alginate tubes into host muscle.
Our data suggest that, the extruded alginate tubes can tolerate a peak stress of 1892 ± 527 mN, that the elastic range is at ~75-125% strain beyond initial length, and that the Young's modulus (stiffness) is 14.17 ± 1.68 %/mm. Importantly, these mechanical properties render the alginate tubes suitable for a published technique known as minimally-invasive muscle embedding (MIME) that was developed by us to implant myogenic material into host muscle. MIME involves threading donor myogenic tissue into a needle track created within a host muscle. Cellularized alginate tubes implanted into the tibialis anterior muscle of previously euthanized mice had numerous hematoxylin-stained structures similar to nuclear staining, supporting the idea that our alginate tubes can support cell seeding. Alginate tubes that were seeded with MuSCs, incubated in MuSC/myoblast growth (i.e., proliferation) media for two days, incubated in myotube differentiation media for six days, and then minced and reseeded in new dishes, were able to promote in vitro myoblast outgrowth over several days.
This pilot study is limited in its translational scope because it was performed in vitro and with previously euthanized mice. Additional studies are needed to confirm that cellularized alginate tubes can promote the de novo development of donor-cell-derived muscle fibers, which can contribute to contractile force production.
Alginate tubes with MuSC/myoblasts can be generated by a simple extrusion method. The alginate tubes have sufficient mechanical strength to tolerate insertion into a host muscle, in a minimally-invasive manner, through a needle track. The cellularized alginate tubes demonstrate myogenic potential since they are capable of being maintained in culture conditions for several days, after which they can still facilitate myoblast outgrowth in a dish.
目前尚无经证实的方法可逆转人类因创伤(如体积性肌肉损失,VML)、遗传性神经肌肉疾病(如肌肉萎缩症,MDs)和加速衰老(如肌肉减少症)导致的肌肉损失。由于肌肉组织能够通过肌肉卫星细胞(MuSCs)进行再生,将自体(或其他)供体MuSCs和MuSC衍生的成肌细胞植入宿主肌肉可促进供体细胞源性肌生成。将MuSCs或MuSC衍生的成肌细胞直接注射或植入宿主肌肉仅能促进极少的供体细胞源性肌生成,而将MuSCs/成肌细胞与相关肌肉组织(肌纤维、细胞外基质、神经血管通路等)一起植入则效果更佳。
我们旨在利用将供体成肌细胞限制在类似肌肉组织的模板中的益处。在本文中,我们提出了一个基础和转化研究的工作流程,旨在促进供体细胞源性肌生成以增加小鼠的功能性肌肉质量。我们的工作流程包括在细胞培养基中制备与成肌细胞混合的10%海藻酸钠浆液,将含细胞的浆液挤出到10%乳酸钙中形成管子,并将细胞化的海藻酸酯管植入宿主肌肉。
我们的数据表明,挤出的海藻酸酯管可承受1892±527 mN的峰值应力,弹性范围在初始长度之外约75 - 125%应变,杨氏模量(刚度)为14.17±1.68%/mm。重要的是,这些力学性能使海藻酸酯管适用于我们开发的一种称为微创肌肉嵌入(MIME)的已发表技术,该技术用于将成肌材料植入宿主肌肉。MIME包括将供体成肌组织穿入在宿主肌肉内创建的针道中。植入先前安乐死小鼠胫前肌的细胞化海藻酸酯管有许多苏木精染色的结构,类似于核染色,支持我们的海藻酸酯管可支持细胞接种的观点。接种了MuSCs的海藻酸酯管,在MuSC/成肌细胞生长(即增殖)培养基中孵育两天,在肌管分化培养基中孵育六天,然后切碎并重新接种到新培养皿中,能够在数天内促进体外成肌细胞生长。
这项初步研究的转化范围有限,因为它是在体外和使用先前安乐死的小鼠进行的。需要进一步的研究来确认细胞化的海藻酸酯管是否能促进供体细胞源性肌纤维的从头发育,这可能有助于产生收缩力。
含有MuSC/成肌细胞的海藻酸酯管可通过简单的挤压方法生成。海藻酸酯管具有足够的机械强度,能够以微创方式通过针道插入宿主肌肉。细胞化的海藻酸酯管显示出成肌潜力,因为它们能够在培养条件下维持数天,之后仍能在培养皿中促进成肌细胞生长。
