TY - JOUR
T1 - Beyond mobile phone displays
T2 - Flat panel display technology for biomedical applications
AU - Mameli, Alfredo
AU - Akkerman, Hylke B.
AU - González-Lana, Sandra
AU - Castro-Abril, Héctor
AU - Le Cann, Kim
AU - Lampert, Angelika
AU - Gelinck, Gerwin H.
AU - Kronemeijer, Auke Jisk
AU - van Breemen, Albert J.J.M.
PY - 2023/5/15
Y1 - 2023/5/15
N2 - Organ-on-Chips (OoCs) have emerged as a human-specific experimental platform for preclinical research and therapeutics testing that will reduce the cost of pre-clinical drug development, provide better physiological relevance and replace animal testing. Yet, the lack of standardization and cost-effective fabrication technologies can hamper wide-spread adoption of OoCs. In this work we validate the use of flat panel display (FPD) technology as an enabling and cost-effective technology platform for biomedical applications by demonstrating facile integration of key OoC modules like microfluidics and micro electrode arrays (MEAs) in the standardized 96-well plate format. Individual and integrated modules were tested for their biological applicability in OoCs. For microelectrode arrays we demonstrate 90–95% confluency, 3 days after cell seeding and >70% of the initial mitochondrial cell activity for microfluidic devices. Thus highlighting the biocompatibility of these modules fabricated using FPD technology. Furthermore, we provide two examples of monolithically integrated microfluidics and microelectronics, i.e. integrated electronic valves and integrated MEAs, that showcase the strength of FPD technology applied to biomedical device fabrication. Finally, the merits and opportunities provided by FPD technology are discussed through examples of advanced structures and functionalities that are unique to this enabling platform.
AB - Organ-on-Chips (OoCs) have emerged as a human-specific experimental platform for preclinical research and therapeutics testing that will reduce the cost of pre-clinical drug development, provide better physiological relevance and replace animal testing. Yet, the lack of standardization and cost-effective fabrication technologies can hamper wide-spread adoption of OoCs. In this work we validate the use of flat panel display (FPD) technology as an enabling and cost-effective technology platform for biomedical applications by demonstrating facile integration of key OoC modules like microfluidics and micro electrode arrays (MEAs) in the standardized 96-well plate format. Individual and integrated modules were tested for their biological applicability in OoCs. For microelectrode arrays we demonstrate 90–95% confluency, 3 days after cell seeding and >70% of the initial mitochondrial cell activity for microfluidic devices. Thus highlighting the biocompatibility of these modules fabricated using FPD technology. Furthermore, we provide two examples of monolithically integrated microfluidics and microelectronics, i.e. integrated electronic valves and integrated MEAs, that showcase the strength of FPD technology applied to biomedical device fabrication. Finally, the merits and opportunities provided by FPD technology are discussed through examples of advanced structures and functionalities that are unique to this enabling platform.
KW - Flat panel display technology
KW - Large-area scalable manufacturing
KW - Microfluidics
KW - Organ-on-chip
UR - http://www.scopus.com/inward/record.url?scp=85159119156&partnerID=8YFLogxK
U2 - 10.1016/j.mee.2023.112016
DO - 10.1016/j.mee.2023.112016
M3 - Article
AN - SCOPUS:85159119156
SN - 0167-9317
VL - 277
JO - Microelectronic Engineering
JF - Microelectronic Engineering
M1 - 112016
ER -