2️⃣ Precision manufacturing drives reliability.
Microfluidic parts now need micrometer-level tolerances.
CNC machining of high-grade plastics offers unmatched consistency and contamination control.
Microfluidic parts now need micrometer-level tolerances.
CNC machining of high-grade plastics offers unmatched consistency and contamination control.
November 12, 2025 at 1:53 AM
2️⃣ Precision manufacturing drives reliability.
Microfluidic parts now need micrometer-level tolerances.
CNC machining of high-grade plastics offers unmatched consistency and contamination control.
Microfluidic parts now need micrometer-level tolerances.
CNC machining of high-grade plastics offers unmatched consistency and contamination control.
In this app note, learn how MIMETAS’ OrganoReady® Blood Vessel models enable high-throughput, human-relevant toxicity screening in 3D microfluidic blood vessel systems. Ultimately, this supports the development of safer therapeutics and better treatment strategies.
🔗 shorturl.at/gtn5M
🔗 shorturl.at/gtn5M
November 11, 2025 at 2:42 PM
In this app note, learn how MIMETAS’ OrganoReady® Blood Vessel models enable high-throughput, human-relevant toxicity screening in 3D microfluidic blood vessel systems. Ultimately, this supports the development of safer therapeutics and better treatment strategies.
🔗 shorturl.at/gtn5M
🔗 shorturl.at/gtn5M
Ruifeng Zheng, Pengjie Zhou, Pit Hofmann, Fatima Rani, Juan A. Cabrera, Frank H. P. Fitzek: System Modeling of Microfluidic Molecular Communication: A Markov Approach https://arxiv.org/abs/2511.07245 https://arxiv.org/pdf/2511.07245 https://arxiv.org/html/2511.07245
November 11, 2025 at 6:31 AM
Ruifeng Zheng, Pengjie Zhou, Pit Hofmann, Fatima Rani, Juan A. Cabrera, Frank H. P. Fitzek: System Modeling of Microfluidic Molecular Communication: A Markov Approach https://arxiv.org/abs/2511.07245 https://arxiv.org/pdf/2511.07245 https://arxiv.org/html/2511.07245
ORANGE BIOMED TO SHOWCASE ADVANCED MICROFLUIDIC A1C TEST AT MEDICA 2025, DRIVING THE FUTURE OF DIABETES CARE
rcnamericactri.blogspot.com/2025/11/oran...
rcnamericactri.blogspot.com/2025/11/oran...
ORANGE BIOMED TO SHOWCASE ADVANCED MICROFLUIDIC A1C TEST AT MEDICA 2025, DRIVING THE FUTURE OF DIABETES CARE
rcnamericactri.blogspot.com
November 10, 2025 at 6:08 PM
ORANGE BIOMED TO SHOWCASE ADVANCED MICROFLUIDIC A1C TEST AT MEDICA 2025, DRIVING THE FUTURE OF DIABETES CARE
rcnamericactri.blogspot.com/2025/11/oran...
rcnamericactri.blogspot.com/2025/11/oran...
using a microfluidic device, Tang lab student Kevin Zhang found that even when large wounds are created by chopping cells in half, the membrane closes up in about 100 seconds.
pubmed.ncbi.nlm.nih.gov/33810789/
pubmed.ncbi.nlm.nih.gov/33810789/
Microfluidic guillotine reveals multiple timescales and mechanical modes of wound response in Stentor coeruleus - PubMed
While events local to the wound site have been the focus of many single-cell wound repair studies, our results suggest that large-scale mechanical behaviors may be of greater importance to single-cell wound repair than previously thought. The work here advances our understanding of the wound respons …
pubmed.ncbi.nlm.nih.gov
November 10, 2025 at 5:47 PM
using a microfluidic device, Tang lab student Kevin Zhang found that even when large wounds are created by chopping cells in half, the membrane closes up in about 100 seconds.
pubmed.ncbi.nlm.nih.gov/33810789/
pubmed.ncbi.nlm.nih.gov/33810789/
2️⃣ Vapor Polishing Unlocks Clarity
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
November 10, 2025 at 5:20 PM
2️⃣ Vapor Polishing Unlocks Clarity
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
November 10, 2025 at 6:00 AM
I keep thinking about soft robotics. A like plausible 20 minutes into the future microfluidic/pneumatic air cushioned character sounds like a fun design challenge.
November 9, 2025 at 7:09 PM
I keep thinking about soft robotics. A like plausible 20 minutes into the future microfluidic/pneumatic air cushioned character sounds like a fun design challenge.
Organ Chips are microfluidic devices, developed at the Wyss, that are lined with living human cells that recapitulate the complex structures and functions of human organs. Emulate, Inc. is leveraging this tech to enable faster, better, & cheaper therapeutic development & insights into human health.
Human Organs-on-Chips
Organ Chips are microfluidic devices lined with living human cells for drug development, disease modeling, and personalized medicine. Launched in 2014, Wyss startup Emulate, Inc., is leveraging the…
buff.ly
November 9, 2025 at 4:06 PM
Organ Chips are microfluidic devices, developed at the Wyss, that are lined with living human cells that recapitulate the complex structures and functions of human organs. Emulate, Inc. is leveraging this tech to enable faster, better, & cheaper therapeutic development & insights into human health.
Electron‐Mediator‐Free Microfluidic Photocatalytic Coenzyme Regeneration with 100% Conversion Efficiency within 126 S
Electron‐Mediator‐Free Microfluidic Photocatalytic Coenzyme Regeneration with 100% Conversion Efficiency within 126 S
Discover a groundbreaking mediator-free photocatalytic method for coenzyme NAD(P)H regeneration using BiOBr nanosheets in a microfluidic chip. This study achieves 100% NAD + to NADH conversion in 126 s, maintaining >87% efficiency over 32 h. Explore how photocatalysis and microfluidics combine to offer a sustainable, scalable solution for green chemistry.
Abstract
Microfluidic systems enhance photocatalytic efficiency through superior mass/energy transfer and precise parameter control. Here, an electron-mediator-free microfluidic platform is designed for photocatalytic coenzyme NAD(P)H regeneration by integrating ultrathin BiOBr nanosheets. This architecture enables direct electron–proton coupling, achieving 100% NAD + conversion within 126 s with exceptional selectivity (72.30%) for bioactive 1,4-NADH. Continuous operation over 32 h shows no activity decay, demonstrating unparalleled stability. This study establishes a benchmark for designing integrated photocatalytic systems and highlights their broad potential for applications in biocatalysis, synthetic biology, and renewable energy.
advanced.onlinelibrary.wiley.com
November 9, 2025 at 8:56 AM
Electron‐Mediator‐Free Microfluidic Photocatalytic Coenzyme Regeneration with 100% Conversion Efficiency within 126 S
Engineering a Multilayer Microfluidic Airway-On-A-Chip with Tunable GelMA Hydrogel for Physiologically Relevant Aerosol Exposure Studies https://www.biorxiv.org/content/10.1101/2025.11.06.687056v1
November 8, 2025 at 4:46 PM
Engineering a Multilayer Microfluidic Airway-On-A-Chip with Tunable GelMA Hydrogel for Physiologically Relevant Aerosol Exposure Studies https://www.biorxiv.org/content/10.1101/2025.11.06.687056v1
Engineering a Multilayer Microfluidic Airway-On-A-Chip with Tunable GelMA Hydrogel for Physiologically Relevant Aerosol Exposure Studies https://www.biorxiv.org/content/10.1101/2025.11.06.687056v1
November 8, 2025 at 4:46 PM
Engineering a Multilayer Microfluidic Airway-On-A-Chip with Tunable GelMA Hydrogel for Physiologically Relevant Aerosol Exposure Studies https://www.biorxiv.org/content/10.1101/2025.11.06.687056v1
Blood Clot Dx is a microfluidic chip device that can non-invasively monitor a patient’s blood for evidence of clotting in real time. The first application will be in patients with MPM, an aggressive lung cancer. Eventually, this could be used to detect blood clots in a variety of contexts.
Blood Clot Dx
An ultra-sensitive triage test that identifies patients at risk for blood clots before they happen, enabling proactive treatment to reduce complications and deaths across a wide range of conditions.
buff.ly
November 8, 2025 at 3:59 PM
Blood Clot Dx is a microfluidic chip device that can non-invasively monitor a patient’s blood for evidence of clotting in real time. The first application will be in patients with MPM, an aggressive lung cancer. Eventually, this could be used to detect blood clots in a variety of contexts.
Microfluidic platform for biomimetic tissue design and multiscale rheological characterization
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
https://arxiv.org/abs/2511.04319
arXiv abstract link
arxiv.org
November 8, 2025 at 9:06 AM
Microfluidic platform for biomimetic tissue design and multiscale rheological characterization
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
2️⃣ Vapor Polishing Unlocks Clarity
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
November 7, 2025 at 11:25 PM
2️⃣ Vapor Polishing Unlocks Clarity
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
We presented our latest achievement on the topic of Microfluidic Diffracted X-ray Tracking Method at MicroTAS 2025.
#MicroTas2025 #microfluidics #labonachip
#MicroTas2025 #microfluidics #labonachip
MicroTAS 2025で発表しました(2025/11/05)
We are pleased to announce that Dr. Hirai recently participated in the MicroTAS2025 in Adelaide, Australia on 2-6 November, 2025. Our lab. had the honor of presenting the following research: Presentation Title: Microfluidic Platform for Multiple Sequential Chemical Stimuli with Bidirectional Flow: Enabling Diffracted X-ray Tracking Method of TRPV1 DynamicsAuthors: Kaito Shimizu, Yusuke Asagoe, Hirofumi Shimizu, and (Presenter) …
mdde.me.kyoto-u.ac.jp
November 7, 2025 at 2:17 PM
We presented our latest achievement on the topic of Microfluidic Diffracted X-ray Tracking Method at MicroTAS 2025.
#MicroTas2025 #microfluidics #labonachip
#MicroTas2025 #microfluidics #labonachip
Lingyun Ding, Terry Wang, Marcus Roper: Thin gap approximations for microfluidic device design https://arxiv.org/abs/2511.03956 https://arxiv.org/pdf/2511.03956 https://arxiv.org/html/2511.03956
November 7, 2025 at 6:47 AM
Lingyun Ding, Terry Wang, Marcus Roper: Thin gap approximations for microfluidic device design https://arxiv.org/abs/2511.03956 https://arxiv.org/pdf/2511.03956 https://arxiv.org/html/2511.03956
Majid Layachi, Remi Merindol, Laura Casanellas: Microfluidic platform for biomimetic tissue design and multiscale rheological characterization https://arxiv.org/abs/2511.04319 https://arxiv.org/pdf/2511.04319 https://arxiv.org/html/2511.04319
November 7, 2025 at 6:43 AM
Majid Layachi, Remi Merindol, Laura Casanellas: Microfluidic platform for biomimetic tissue design and multiscale rheological characterization https://arxiv.org/abs/2511.04319 https://arxiv.org/pdf/2511.04319 https://arxiv.org/html/2511.04319
This work was primarily led by Joris Sprakel, and it was a pleasure to see this develop! Feeback is appreciated! Please note the cool microfluidic protein-DNA single molecule assay 😃
November 7, 2025 at 5:39 AM
This work was primarily led by Joris Sprakel, and it was a pleasure to see this develop! Feeback is appreciated! Please note the cool microfluidic protein-DNA single molecule assay 😃
Microfluidic platform for biomimetic tissue design and multiscale rheological characterization
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
https://arxiv.org/abs/2511.04319
arXiv abstract link
arxiv.org
November 7, 2025 at 4:35 AM
Microfluidic platform for biomimetic tissue design and multiscale rheological characterization
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
https://arxiv.org/pdf/2511.04319
Majid Layachi, Remi Merindol, Laura Casanellas.
2️⃣ Vapor Polishing Unlocks Clarity
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
November 7, 2025 at 1:17 AM
2️⃣ Vapor Polishing Unlocks Clarity
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
This process reflows the plastic’s surface, achieving <4 µin Ra and near-optical transparency.
Perfect for diagnostic windows, microfluidic paths, and optical sensors that demand visual clarity.
Wearable microfluidic sensors using advanced 3D structures enable real-time, noninvasive sweat analysis, offering precise monitoring of biomarkers for health, sports, and environmental applications. doi.org/g99dk6
Microfluidic sensors enable real-time sweat analysis
Eccrine sweat is a water-like fluid secreted by eccrine sweat glands that comprises various kinds of biochemical components such as electrolytes, metabolites, organic molecules, and drugs.
medicalxpress.com
November 6, 2025 at 5:34 PM
Wearable microfluidic sensors using advanced 3D structures enable real-time, noninvasive sweat analysis, offering precise monitoring of biomarkers for health, sports, and environmental applications. doi.org/g99dk6
Wearable microfluidic sensors using advanced 3D structures enable precise, real-time monitoring of sweat biomarkers, supporting noninvasive health tracking across medical, sports, and wellness applications. doi.org/g99dk6
Microfluidic sensors enable real-time sweat analysis
Eccrine sweat is a water-like fluid secreted by eccrine sweat glands that comprises various kinds of biochemical components such as electrolytes, metabolites, organic molecules, and drugs.
medicalxpress.com
November 6, 2025 at 5:32 PM
Wearable microfluidic sensors using advanced 3D structures enable precise, real-time monitoring of sweat biomarkers, supporting noninvasive health tracking across medical, sports, and wellness applications. doi.org/g99dk6
A Microfluidic Platform for Whole-Membrane Integrity Profiling in Live Neuronal Cells #NeuroDegeneration 🧪🧠
https://www.researchsquare.com/article/rs-7278474/latest
https://www.researchsquare.com/article/rs-7278474/latest
November 6, 2025 at 5:02 PM
A Microfluidic Platform for Whole-Membrane Integrity Profiling in Live Neuronal Cells #NeuroDegeneration 🧪🧠
https://www.researchsquare.com/article/rs-7278474/latest
https://www.researchsquare.com/article/rs-7278474/latest
A Microfluidic Platform for Whole-Membrane Integrity Profiling in Live Neuronal Cells #SingleCell 🧪🧬🖥️
https://www.researchsquare.com/article/rs-7278474/latest
https://www.researchsquare.com/article/rs-7278474/latest
November 6, 2025 at 5:00 PM
A Microfluidic Platform for Whole-Membrane Integrity Profiling in Live Neuronal Cells #SingleCell 🧪🧬🖥️
https://www.researchsquare.com/article/rs-7278474/latest
https://www.researchsquare.com/article/rs-7278474/latest