Design, fabrication, and characterization of a multimodal reconfigurable bioreactor for bone tissue engineering

Margherita Montorsi; Giada G Genchi; Daniele De Pasquale; Giorgio De Simoni; Edoardo Sinibaldi; Gianni Ciofani

doi:10.1002/bit.28100

Design, fabrication, and characterization of a multimodal reconfigurable bioreactor for bone tissue engineering

Biotechnol Bioeng. 2022 Jul;119(7):1965-1979. doi: 10.1002/bit.28100. Epub 2022 Apr 15.

Authors

Margherita Montorsi^{1

2}, Giada G Genchi¹, Daniele De Pasquale¹, Giorgio De Simoni³, Edoardo Sinibaldi⁴, Gianni Ciofani¹

Affiliations

¹ Istituto Italiano di Tecnologia, Smart Bio-Interfaces, Pontedera, Italy.
² Scuola Superiore Sant'Anna, The BioRobotics Institute, Pontedera, Italy.
³ CNR, Nanoscience Institute, NEST Laboratory, Pisa, Italy.
⁴ Istituto Italiano di Tecnologia, Bioinspired Soft Robotics, Genova, Italy.

Abstract

In the past decades, bone tissue engineering developed and exploited many typologies of bioreactors, which, besides providing proper culture conditions, aimed at integrating those bio-physical stimulations that cells experience in vivo, to promote osteogenic differentiation. Nevertheless, the highly challenging combination and deployment of many stimulation systems into a single bioreactor led to the generation of several unimodal bioreactors, investigating one or at mostly two of the required biophysical stimuli. These systems miss the physiological mimicry of bone cells environment, and often produced contrasting results, thus making the knowledge of bone mechanotransduction fragmented and often inconsistent. To overcome this issue, in this study we developed a perfusion and electroactive-vibrational reconfigurable stimulation bioreactor to investigate the differentiation of SaOS-2 bone-derived cells, hosting a piezoelectric nanocomposite membrane as cell culture substrate. This multimodal perfusion bioreactor is designed based on a numerical (finite element) model aimed at assessing the possibility to induce membrane nano-scaled vibrations (with ~12 nm amplitude at a frequency of 939 kHz) during perfusion (featuring 1.46 dyn cm^-2 wall shear stress), large enough for inducing a physiologically-relevant electric output (in the order of 10 mV on average) on the membrane surface. This study explored the effects of different stimuli individually, enabling to switch on one stimulation at a time, and then to combine them to induce a faster bone matrix deposition rate. Biological results demonstrate that the multimodal configuration is the most effective in inducing SaOS-2 cell differentiation, leading to 20-fold higher collagen deposition compared to static cultures, and to 1.6- and 1.2-fold higher deposition than the perfused- or vibrated-only cultures. These promising results can provide tissue engineering scientists with a comprehensive and biomimetic stimulation platform for a better understanding of mechanotransduction phenomena beyond cells differentiation.

Keywords: biomimetic stimulations; bone tissue engineering; multimodal bioreactor; reconfigurability.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Bioreactors
Bone and Bones
Cell Differentiation
Cells, Cultured
Mechanotransduction, Cellular
Osteogenesis*
Tissue Engineering* / methods
Tissue Scaffolds / chemistry