Abstract
Aliphatic polyesters are the synthetic polymers most commonly used in the development of resorbable medical implants/devices. Various three-dimensional (3D) scaffolds have been fabricated from these polymers and used in adipose tissue engineering. However, their systematic evaluation altogether lacks, which makes it difficult to select a suitable degradable polymer to design 3D resorbable implants and/or devices able to effectively mimic the properties of adipose tissue. Additionally, the impact of sterilization methods on the medical devices, if any, must be taken into account. We evaluate and compare five different medical-grade resorbable polyesters with l-lactide content ranging from 50 to 100 mol% and exhibiting different physiochemical properties depending on the comonomer (d-lactide, ε-caprolactone, glycolide, and trimethylene carbonate). The salt-leaching technique was used to prepare 3D microporous scaffolds. A comprehensive assessment of physical, chemical, and mechanical properties of the scaffolds was carried out in PBS at 37 °C. The cell-material interactions and the ability of the scaffolds to promote adipogenesis of human adipose tissue-derived stem cells were assessed in vitro. The diverse physical and mechanical properties of the scaffolds, due to the different composition of the copolymers, influenced human adipose tissue-derived stem cells proliferation and differentiation. Scaffolds made from polymers which were above their glass transition temperature and with low degree of crystallinity showed better proliferation and adipogenic differentiation of stem cells. The effect of sterilization techniques (electron beam and ethylene oxide) on the polymer properties was also evaluated. Results showed that scaffolds sterilized with the ethylene oxide method better retained their physical and chemical properties. Overall, the presented research provides (i) a detailed understanding to select a degradable polymer that has relevant properties to augment adipose tissue regeneration and can be further used to fabricate medical devices/implants; (ii) directions to prefer a sterilization method that does not change polymer properties.
Highlights
Regeneration of adipose tissue aims to repair and maintain damaged tissue after trauma, injury, mastectomy, or surgical resection [1,2]
Scanning electron microscopy (SEM) and Micro-CT results revealed that scaffolds had interconnected pores and porous architecture (Fig. 2), which is a prerequisite for functional tissue engineering 3D construct, allowing cellular infiltration and migration into the pores, and mimicking tissue-like microenviron ment
In contrast to PLLA, PDLA, and PLGA, the Tg of PCLA and poly(Llactide-co-trimethylene carbonate) (PLATMC) was below 37 ◦C, scaffolds made of these polymers were more pliable and softer
Summary
Regeneration of adipose tissue aims to repair and maintain damaged tissue after trauma, injury, mastectomy, or surgical resection [1,2]. Adipose tissue has a complex cell environment with a highly vascularized matrix [3,4] and because of this cellular heterogeneity, the regeneration of adipose tissue in a large volume defect remains a challenge. 3D scaffolds fabricated from degradable synthetic polymers can be a successful solution for adipose tissue regeneration thanks to the possi bility to modify the structure, composition and molar mass of the polymer. This allows the mechanical properties and the degradation profile to be tuned while versatility in designing the 3D scaffolds is enabled [6,7,8]
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