[HTML][HTML] Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process …
MD Poskus, T Wang, Y Deng, S Borcherding… - Microsystems & …, 2023 - nature.com
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process: printing …
MD Poskus, T Wang, Y Deng… - Microsystems & …, 2023 - europepmc.org
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process: printing …
MD Poskus, T Wang, Y Deng… - Microsystems & …, 2023 - pubmed.ncbi.nlm.nih.gov
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
[HTML][HTML] Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process …
MD Poskus, T Wang, Y Deng… - Microsystems & …, 2023 - ncbi.nlm.nih.gov
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process: printing …
MD Poskus, T Wang, Y Deng… - Microsystems & …, 2023 - ui.adsabs.harvard.edu
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process: printing …
MD Poskus, T Wang, Y Deng… - Microsystems & …, 2023 - search.proquest.com
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process: printing …
MD Poskus, T Wang, Y Deng… - Microsystems & …, 2023 - search.ebscohost.com
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
[引用][C] Fabrication of 3D-printed molds for polydimethylsiloxane-based microfluidic devices using a liquid crystal display-based vat photopolymerization process …
M Poskus, T Wang, Y Deng, S Borcherding… - Microsystems & …, 2023 - europepmc.org
Microfluidic platforms enable more precise control of biological stimuli and environment
dimensionality than conventional macroscale cell-based assays; however, long fabrication …
dimensionality than conventional macroscale cell-based assays; however, long fabrication …