Dual‐chambered membrane bioreactor for coculture of stratified cell populations

Navarro, Javier; Swayambunathan, Jay; Janes, Morgan Elizabeth; Santoro, Marco; Mikos, Antonios G.; Fisher, John P.

doi:10.1002/bit.27164

Cited by 6 publications

(7 citation statements)

References 64 publications

(113 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…DCB provides adjacent flow lines within the chamber and the included membrane regulates stratification and flow mixing. This system can be exploited to produce cell population layers or gradients in scaffolds [ 125 ].…”

Section: Scaffolds For Skin Tissue Engineering and Cutting-edge Tementioning

confidence: 99%

Skin Wound Healing Process and New Emerging Technologies for Skin Wound Care and Regeneration

et al. 2020

View full text Add to dashboard Cite

Skin wound healing shows an extraordinary cellular function mechanism, unique in nature and involving the interaction of several cells, growth factors and cytokines. Physiological wound healing restores tissue integrity, but in many cases the process is limited to wound repair. Ongoing studies aim to obtain more effective wound therapies with the intention of reducing inpatient costs, providing long-term relief and effective scar healing. The main goal of this comprehensive review is to focus on the progress in wound medication and how it has evolved over the years. The main complications related to the healing process and the clinical management of chronic wounds are described in the review. Moreover, advanced treatment strategies for skin regeneration and experimental techniques for cellular engineering and skin tissue engineering are addressed. Emerging skin regeneration techniques involving scaffolds activated with growth factors, bioactive molecules and genetically modified cells are exploited to overcome wound healing technology limitations and to implement personalized therapy design.

show abstract

Section: Scaffolds For Skin Tissue Engineering and Cutting-edge Tementioning

confidence: 99%

Skin Wound Healing Process and New Emerging Technologies for Skin Wound Care and Regeneration

et al. 2020

View full text Add to dashboard Cite

show abstract

“…An interesting result came out from permeability tests which revealed the possibility to manage the direction of the radial flow simply by changing the height of the outlet of the IPC tube. Consequently, according to the desired application, one can precisely set the direction of the radial flow rate, without the use of specific devices [61] or the more approximating results of a computational simulation [62,63]. Recently, Tan et al presented a new calibration method for the permeability measuring set-ups by testing the outwards radial flow through two concentric annular slits [64].…”

Section: Discussionmentioning

confidence: 99%

Novel dual-flow perfusion bioreactor for in vitro pre-screening of nanoparticles delivery: design, characterization and testing

Pavia

Craparo

Capuana

et al. 2021

Bioprocess Biosyst Eng

View full text Add to dashboard Cite

An advanced dual-flow perfusion bioreactor with a simple and compact design was developed and evaluated as a potential apparatus to reduce the gap between animal testing and drug administration to human subjects in clinical trials. All the experimental tests were carried out using an ad hoc Poly Lactic Acid (PLLA) scaffold synthesized via Thermally Induced Phase Separation (TIPS). The bioreactor shows a tunable radial flow throughout the microporous matrix of the scaffold. The radial perfusion was quantified both with permeability tests and with a mathematical model, applying a combination of Darcy's Theory, Bernoulli's Equation, and Poiseuille's Law. Finally, a diffusion test allowed to investigate the efficacy of the radial flow using Polymeric Fluorescent Nanoparticles (FNPs) mimicking drug/colloidal carriers. These tests confirmed the ability of our bioreactor to create a uniform distribution of particles inside porous matrices. All the findings candidate our system as a potential tool for drug pre-screening testing with a cost and time reduction over animal models.

show abstract

“…Dual-chambered bioreactors developed by Javier Navarro et al allowed for better transport mechanisms owing to the dual action of convection and diffusion patterns. Two different cell populations were developed on the two sides of the membrane and successfully paved the way for the development of skin tissue in vitro, which consists of multiple morphologically distinct layers of cells of a similar lineage . This approach might also be helpful in the development of interface tissue engineering.…”

Section: Applicationmentioning

confidence: 99%

Surface Engineering of a Bioartificial Membrane for Its Application in Bioengineering Devices

et al. 2023

View full text Add to dashboard Cite

Membrane technology is playing a crucial role in cutting-edge innovations in the biomedical field. One such innovation is the surface engineering of a membrane for enhanced longevity, efficient separation, and better throughput. Hence, surface engineering is widely used while developing membranes for its use in bioartificial organ development, separation processes, extracorporeal devices, etc. Chemical-based surface modifications are usually performed by functional group/biomolecule grafting, surface moiety modification, and altercation of hydrophilic and hydrophobic properties. Further, creation of micro/nanogrooves, pillars, channel networks, and other topologies is achieved to modify physio-mechanical processes. These surface modifications facilitate improved cellular attachment, directional migration, and communication among the neighboring cells and enhanced diffusional transport of nutrients, gases, and waste across the membrane. These modifications, apart from improving functional efficiency, also help in overcoming fouling issues, biofilm formation, and infection incidences. Multiple strategies are adopted, like lysozyme enzymatic action, topographical modifications, nanomaterial coating, and antibiotic/antibacterial agent doping in the membrane to counter the challenges of biofilm formation, fouling challenges, and microbial invasion. Therefore, in the current review, we have comprehensibly discussed different types of membranes, their fabrication and surface modifications, antifouling/ antibacterial strategies, and their applications in bioengineering. Thus, this review would benefit bioengineers and membrane scientists who aim to improve membranes for applications in tissue engineering, bioseparation, extra corporeal membrane devices, wound healing, and others.

show abstract

Dual‐chambered membrane bioreactor for coculture of stratified cell populations

Cited by 6 publications

References 64 publications

Skin Wound Healing Process and New Emerging Technologies for Skin Wound Care and Regeneration

Skin Wound Healing Process and New Emerging Technologies for Skin Wound Care and Regeneration

Novel dual-flow perfusion bioreactor for in vitro pre-screening of nanoparticles delivery: design, characterization and testing

Surface Engineering of a Bioartificial Membrane for Its Application in Bioengineering Devices

Contact Info

Product

Resources

About