Abstract
SummaryAt the core of translational challenges in tissue engineering is the mechanistic understanding of the underpinning biological processes and the complex relationships among components at different levels, which is a challenging task due to the limitations of current tissue culture and assessment methodologies. Therefore, we proposed a novel scale‐down strategy to deconstruct complex biomatrices into elementary building blocks, which were resembled by thin modular substrate and then evaluated separately in miniaturised bioreactors using various conventional microscopes. In order to investigate cell colonisation within porous substrate in this proof‐of‐concept study, TEM specimen supporters (10–30 μm thick) with fine controlled open pores (100∼600 μm) were selected as the modular porous substrate and suspended in 3D printed bioreactor systems. Noninvasive imaging of human dermal fibroblasts cultured on these free‐standing substrate using optical microscopes illustrated the complicated dynamic processes used by both individual and coordinated cells to bridge and segment porous structures. Further in situ analysis via SEM and TEM provided high‐quality micrographs of cell–cell and cell–scaffold interactions at microscale, depicted cytoskeletal structures in stretched and relaxed areas at nanoscale. Thus this novel scaled‐down design was able to improve our mechanistic understanding of tissue formation not only at single‐ and multiple‐cell levels, but also at micro‐ and nanoscales, which could be difficult to obtain using other methods.
Highlights
Tissue engineering (TE) is defined as an interdisciplinary field that applies the principles of engineering and life sciences toward the manufacturing of biological substitutes to restore,C 2017 The Authors
Due to the obvious advantages such as commercially available, low price, suitable thickness (10–30 μm) and most importantly, fine controlled open pore structures with differing shapes and varying sizes, transmission electron microscope (TEM) specimen supporters were selected as the thin modular porous substrate, which were suspended in 3D cell culture and imaging systems (3D CCISs) fabricated using 3D printing technology
Micrographs of the exemplary Human dermal fibroblasts (HDFs) cultured on the thin modular substrate were captured at multiple- and single-cell levels using optical microscopes during cell culture; in situ analysis was conducted at micro- and nanoscales after cell culture via scanning electron microscope (SEM) and TEM with higher resolutions (Clarke, 1973; VernonParry, 2000)
Summary
Tissue engineering (TE) is defined as an interdisciplinary field that applies the principles of engineering and life sciences toward the manufacturing of biological substitutes to restore,C 2017 The Authors. The modular substrate are situated within miniaturised bioreactors, so the cells cultivated on these thin substrate can be imaged noninvasively using common optical microscopes As this scale-down design has a complete control of the structural features on the modular substrate as well as the biochemical and biomechanical properties in the miniaturised bioreactors, their regulatory functions on the cultivated cells can be investigated separately. In this proof-of-concept (PoC) study, one of the important elementary components of 3D porous matrices, open pore structure, was investigated using this scale-down strategy. The 3D CCISs were employed as a valuable platform to yield mechanistic insights of the aforementioned relationships especially cell–cell and cell–scaffold interactions and the underpinning biological processes during tissue formation at nano- and microscales
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