Impact of crystalline domains on long-term stability and mechanical performance of anisotropic silk fibroin sponges

IF 3.9 3区 医学 Q2 ENGINEERING, BIOMEDICAL
Elizabeth L. Aikman, Asha P. Rao, Yinhao Jia, Emily E. Fussell, Kayleigh E. Trumbull, Janani Sampath, Whitney L. Stoppel
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引用次数: 0

Abstract

Sponge-like materials made from regenerated silk fibroin biopolymers are a tunable and advantageous platform for in vitro engineered tissue culture and in vivo tissue regeneration. Anisotropic, three-dimensional (3D) silk fibroin sponge-like scaffolds can mimic the architecture of contractile muscle. Herein, we use silk fibroin solution isolated from the cocoons of Bombyx mori silkworms to form aligned sponges via directional ice templating in a custom mold with a slurry of dry ice and ethanol. Hydrated tensile mechanical properties of these aligned sponges were evaluated as a function of silk polymer concentration (3% or 5%), freezing time (50% or 100% ethanol), and post-lyophilization method for inducing crystallinity (autoclaving, water annealing). Hydrated static tensile tests were used to determine Young's modulus and ultimate tensile strength across sponge formulations at two strain rates to evaluate rate dependence in the calculated parameters. Results aligned with previous reports in the literature for isotropic silk fibroin sponge-like scaffolds, where the method by which beta-sheets were formed and level of beta-sheet content (crystallinity) had the greatest impact on static parameters, while polymer concentration and freezing rate did not significantly impact static mechanical properties. We estimated the crystalline organization using molecular dynamics simulations to show that larger crystalline regions may be responsible for strength at low strain amplitudes and brittleness at high strain amplitudes in the autoclaved sponges. Within the parameters evaluated, extensional Young's modulus is tunable in the range of 600–2800 kPa. Dynamic tensile testing revealed the linear viscoelastic region to be between 0% and 10% strain amplitude and 0.2–2 Hz frequencies. Long-term stability was evaluated by hysteresis and fatigue tests. Fatigue tests showed minimal change in the storage and loss modulus of 5% silk fibroin sponges for more than 6000 min of continuous mechanical stimulation in the linear regime at 10% strain amplitude and 1 Hz frequency. Furthermore, we confirmed that these mechanical properties hold when decellularized extracellular matrix is added to the sponges and when the mechanical property assessments were performed in cell culture media. We also used nano-computed tomography (nano-CT) and simulations to explore pore interconnectivity and tortuosity. Overall, these results highlight the potential of anisotropic, sponge-like silk fibroin scaffolds for long-term (>6 weeks) contractile muscle culture with an in vitro bioreactor system that provides routine mechanical stimulation.

结晶域对各向异性蚕丝纤维海绵的长期稳定性和机械性能的影响
由再生蚕丝纤维素生物聚合物制成的海绵状材料是体外工程组织培养和体内组织再生的一个可调且有利的平台。各向异性的三维(3D)丝纤维蛋白海绵状支架可以模拟收缩肌的结构。在这里,我们使用从蚕茧中分离出的丝纤维蛋白溶液,通过在定制模具中使用干冰和乙醇浆液进行定向冰模板,形成排列整齐的海绵。根据蚕丝聚合物浓度(3% 或 5%)、冷冻时间(50% 或 100%乙醇)和诱导结晶的冻后方法(高压灭菌、水退火)的不同,对这些排列整齐的海绵的水合拉伸机械性能进行了评估。水合静态拉伸试验用于测定两种应变速率下不同海绵配方的杨氏模量和极限拉伸强度,以评估计算参数的速率依赖性。结果与之前关于各向同性蚕丝纤维素海绵状支架的文献报道一致,即形成β片的方法和β片含量(结晶度)对静态参数的影响最大,而聚合物浓度和冷冻速率对静态机械性能的影响不大。我们利用分子动力学模拟对结晶组织进行了估计,结果表明,较大的结晶区域可能是高压蒸汽海绵在低应变振幅时具有强度和在高应变振幅时具有脆性的原因。在所评估的参数范围内,延伸杨氏模量可在 600-2800 kPa 的范围内进行调整。动态拉伸测试显示,线性粘弹性区域的应变振幅在 0% 至 10% 之间,频率为 0.2-2 赫兹。通过滞后和疲劳测试评估了长期稳定性。疲劳测试表明,在应变幅度为 10%、频率为 1 Hz 的线性状态下,5% 的蚕丝纤维素海绵在超过 6000 分钟的连续机械刺激下,其存储模量和损失模量的变化极小。此外,我们还证实,在海绵中添加脱细胞细胞外基质以及在细胞培养基中进行机械性能评估时,这些机械性能都能保持不变。我们还利用纳米计算机断层扫描(nano-Computed tomography,nano-CT)和模拟来探索孔隙的相互连接性和迂曲性。总之,这些结果凸显了各向异性海绵状蚕丝纤维支架的潜力,可通过提供常规机械刺激的体外生物反应器系统进行长期(大于 6 周)收缩肌培养。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of biomedical materials research. Part A
Journal of biomedical materials research. Part A 工程技术-材料科学:生物材料
CiteScore
10.40
自引率
2.00%
发文量
135
审稿时长
3.6 months
期刊介绍: The Journal of Biomedical Materials Research Part A is an international, interdisciplinary, English-language publication of original contributions concerning studies of the preparation, performance, and evaluation of biomaterials; the chemical, physical, toxicological, and mechanical behavior of materials in physiological environments; and the response of blood and tissues to biomaterials. The Journal publishes peer-reviewed articles on all relevant biomaterial topics including the science and technology of alloys,polymers, ceramics, and reprocessed animal and human tissues in surgery,dentistry, artificial organs, and other medical devices. The Journal also publishes articles in interdisciplinary areas such as tissue engineering and controlled release technology where biomaterials play a significant role in the performance of the medical device. The Journal of Biomedical Materials Research is the official journal of the Society for Biomaterials (USA), the Japanese Society for Biomaterials, the Australasian Society for Biomaterials, and the Korean Society for Biomaterials. Articles are welcomed from all scientists. Membership in the Society for Biomaterials is not a prerequisite for submission.
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