Abstract
Clinical results obtained when degradable polymer-based medical devices are used in breast reconstruction following mastectomy are promising. However, it remains challenging to develop a large scaffold structure capable of providing both sufficient external mechanical support and an internal cell-like environment to support breast tissue regeneration. We propose an internal-bra-like prototype to solve both challenges. The design combines a 3D-printed scaffold with knitted meshes and electrospun nanofibers and has properties suitable for both breast tissue regeneration and support of a silicone implant. Finite element analysis (FEA) was used to predict the macroscopic and microscopic stiffnesses of the proposed structure. The simulations show that introduction of the mesh leads to a macroscopic scaffold stiffness similar to the stiffness of breast tissue, and mechanical testing confirms that the introduction of more layers of mesh in the modular design results in a lower elastic modulus. The compressive modulus of the scaffold can be tailored within a range from hundreds of kPa to tens of kPa. Biaxial tensile testing reveals stiffening with increasing strain and indicates that rapid strain-induced softening occurs only within the first loading cycle. In addition, the microscopic local stiffness obtained from FEA simulations indicates that cells experience significant heterogeneous mechanical stimuli at different places in the scaffold and that the local mechanical stimulus generated by the strand surface is controlled by the elastic modulus of the polymer, rather than by the scaffold architecture. From in vitro experiments, it was observed that the addition of knitted mesh and an electrospun nanofiber layer to the scaffold significantly increased cell seeding efficiency, cell attachment, and proliferation compared to the 3D-printed scaffold alone. In summary, our results suggest that the proposed design strategy is promising for soft tissue engineering of scaffolds to assist breast reconstruction and regeneration.
Highlights
Breast cancer is one of the commonest cancer forms globally, with approximately 2.2 million new cases in 2020.1 Typical treatment involves partial or complete surgical removal of the breast followed by reconstructive surgery.[2,3] Reconstructive surgery often includes the insertion of silicone implants, autologous tissue flaps, or injection of adipose tissue
This fibrous structure, which forms a 3D network in the breast often denoted as suspensory ligaments or Cooper’s ligaments, develops both as thicker bundles to suspend the breast and as fine, hair-like fibers that infiltrate through the adipose tissue region
The results suggest that the local mechanical stimulus generated by the strand surface is controlled by the elastic modulus of the polymer rather than the scaffold architecture
Summary
Breast cancer is one of the commonest cancer forms globally, with approximately 2.2 million new cases in 2020.1 Typical treatment involves partial or complete surgical removal of the breast followed by reconstructive surgery.[2,3] Reconstructive surgery often includes the insertion of silicone implants, autologous tissue flaps, or injection of adipose tissue. The use of a mesh to add scaffold units together permits formation of a small device for lumpectomy reconstruction where only a small amount of tissue has been removed, a larger device to be used in conjunction with a silicone breast implant, or a larger strap-like device up to a bra-like prototype to aid in breast construction (Figure 1). It has successfully been shown that a tissue chamber or a scaffold can be utilized to prevent tissue resorption by shielding the fragile adipose tissue from external deformation using polymers with a long degradation time such as poly(ε-caprolactone) (PCL), or nondegradable acrylic chambers.[12−17]
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