Monday, 12 December 2022 | Please View Agenda for Plenary Session in the Lab-on-a-Chip Track Website |
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Tuesday, 13 December 2022 | Please View Agenda for Microfluidics-Lab-on-a-Chip Programming in the Lab-on-a-Chip Track Website |
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Wednesday, 14 December 202207:45 | Morning Coffee, Tea and Pastries in the Exhibit Hall | | Lab-on-a-Chip, Microfluidics, Organs-on-Chips -- Connecting the Dots |
| | | The MPS Field Radiating out from the Microfluidics Area |
| | | Chairperson: Dr. Claudia Gärtner, CEO, microfluidic ChipShop |
| | 08:00 | Microfluidic Encapsulation of Therapeutic Agents in Microdroplets and Nanoparticles Dong Pyo Kim, Yonsan Chaired Professor, Pohang University of Science And Technology (POSTECH), Korea South
Microdroplets (µ-droplet) and nanoparticles (NPs) have been attracted significant interest in the past decades to address different drug delivery challenges, including poor bioavailability, poor drug solubility, and lack of targeted delivery. Traditionally, µ-droplet and NPs are often produced using bulk methods. In comparison, microfluidics offers a new strategy for making µ-droplet and NPs with controlled shape and homogeneous size due to rapid mass transfer and precise control over reaction conditions. Herein, we present a continuous-flow method for effectively encapsulating various therapeutic agents (enzymes, chelators, magnetic nanoparticles, bio-imaging agents, etc.) into uniform size of polymeric µ-droplet and inorganic NPs by microfluidics. Furthermore, we controlled the mixing time between the reactants of carrier and the therapeutic agent by forming various flow patterns (chaotic, multiple-laminar flow) and developed a drug delivery system with an improved therapeutic effect through flow control. This work will contribute effective encapsulation of therapeutic agents in µ-droplet and NPs, which would be extended to biomedical applications. | 08:30 | Fluid Handling System for Lab-on-a-Chips Felipe Echeverri, CEO, Biorep Technologies, Inc., United States of America
Proven technology for dynamic perifusion studies can be adapted for Lab-on-a-Chip applications – A System Overview. | 09:00 | | Keynote Presentation Human Microphysiological Systems for Disease Modeling George Truskey, R. Eugene and Susie E. Goodson Professor of Biomedical Engineering, Duke University, United States of America
Microphysiological systems (MPS) are small scale three-dimensional models of key structural or functional units of human organs or tissues. Such systems can be used to model diseases and test therapeutics. The strengths and limitations of various models will be discussed with a focus on vascular models, including system design and the use of primary and stem cell derived cells. Applications of these systems to model genetic and acquired diseases and evaluate therapeutics will be described. |
| 09:30 | The Next Evolution in Microfluidic 3D Printing Hemdeep Patel, President, Co-Founder, CADworks3D
Over the last decade, 3D printing has changed the way designs are created, evaluated and iterated in all industries and in every facet of life. Since 2016, CADworks3D has been an active player in the world of microfluidics & bio-engineering by showcasing how 3D printers can radically improve the cycle of design, evaluation and iteration. The CADworks3D line of microfluidic 3D printers and 3D materials has users to test a wide range of devices from clear microfluidic encapsulated chips to master molds used for casting PDMS devices. Our newest open source ProFluidics 285D microfluidic 3D printer equipped with updated optics, a next generation projector and advanced software will allow users to reproduce features that are more true to the design. Furthermore, the tell sign of pixel burn and shadow that was characteristic of the previous generation 3D printers are now a thing of the past allowing users to create smoother, superior quality surfaces finish. The ProFluidics 285D will allow users to create high quality clear microfluidic devices and master molds for casting PDMS devices. | 10:00 | Engineering of Organotypic Tissue On-Chip Systems for Disease Modeling and Drug Testing Mehdi Nikkhah, Associate Professor of Bioengineering, Arizona State University, United States of America
Engineering of ex vivo Tissue-On-Chip Technologies and Microphysiological Systems has gained significant attention in recent years for a wide range of applications in disease modeling, drug screening, and personalized medicine. These technologies have immensely benefited the fields of experimental biology and medicine in the ability to address the limitations of animal models by providing precise control over cell-cell, cell-matrix, and cell-microenvironmental factors interactions. In the past few years, we have been extensively involved in the development of next-generation tissue on-chip technologies through the integration of microfluidic systems, 3D biomaterials, and patient-derived cells. We have successfully engineered and validated numerous disease-on-chip models, including tumor-on-chip and heart-on-chip technologies, to study cancer progression and cardiovascular abnormalities. Using these model systems, we have been able to mechanistically investigate how microenvironmental and genetic risk factors lead to disease progression. Additionally, we have shown the capabilities of these model systems for enhanced drug testing. This seminar will provide an overview of our major findings from these projects. | 10:30 | Organ-on-a-Chip - On the Path to the Promised Land… Claudia Gärtner, CEO, microfluidic ChipShop GmbH
The perspective from a microfluidic and fabrication company. | 11:00 | | Keynote Presentation Liraglutide Protects Human Beta-Cell Function From Cytokine- And Immune Cell-Induced Stress In Human In Vitro Models of T1D Matthias von Herrath, Vice President and Senior Medical Officer, Novo Nordisk, Professor, La Jolla Institute, United States of America
GLP-1 receptor agonists (GLP-1 RA) are hypothesized to preserve beta-cell function and enhance insulin secretion in type 1 diabetes (T1D). We evaluated the effects of the GLP-1 RA, liraglutide, on reaggregated, uniform primary human islets under T1D-relevant stress. We established three high-throughput-compatible islet-immune injury models: a cytokine-induced stress assay, an activated peripheral blood mononuclear cell-islet co-culture, and an islet-HLA-A2-restricted preproinsulin-specific cytotoxic T lymphocyte co-culture. In all models, the decline in beta-cell health manifested as increased basal and decreased glucose-stimulated insulin release and decreased total insulin content. Liraglutide prevented loss of stimulated insulin secretion under cytokine- and immune-mediated stress, most notably by preserving the first-phase insulin response and decreasing immune cell infiltration and cytokine secretion. Our results corroborate the therapeutic potential of liraglutide for the preservation of beta-cell function at the time of T1D onset, provide further evidence of a GLP1-related anti-inflammatory effect, and support the utility of biomimetic islet-immune assays. |
| 11:30 | | Keynote Presentation Cancer-on-a-Chip Model of Colorectal Cancer Progression Shannon Mumenthaler, Assistant Professor of Medicine & Biomedical Engineering, University of Southern California, Ellison Institute, United States of America
The highly complex and evolving nature of cancer makes it challenging to study. Here we describe a microfluidic organ-on-chip platform, incorporating tissue-tissue interfaces and physical forces, to support novel interrogations of colorectal cancer progression. We will cover advancements made through combining organoids and an organ-on-chip model with high content imaging and mass spectrometry-based metabolomics, which provide measurements that capture spatial and temporal cancer cell dynamics. This work reveals important interactions between colorectal cancer cells and their microenvironment, which can be used to prevent or delay cancer progression. |
| 12:00 | Janus Base Nano-matrix Enabled Cartilage-on-a-Chip for Drug Screening Applications Yupeng Chen, Associate Professor, University of Connecticut, United States of America
To achieve biomimetic microenvironment for engineered tissues, it is important to have biomaterial scaffolds to support cell anchorage and functions. However, conventional solid scaffolds are not injectable so they have limitations for applications in “difficult-to-reach” locations, such as microchannels of tissues-on-chips or deep-tissue damage; hydrogels are semisolid materials so they don’t have solid surface for cell anchorage which could be a limitation in space. To overcome this challenge, we have developed a family of self-assembled scaffolds, named Janus base nano-matrices (JBNms). JBNms are formed by the self-assembly between Janus base nanotubes (JBNts, non-covalent nanotubes mimicking DNA base pairs) and extracellular matrix proteins (such as matrilin, a cartilage specific protein). We have also found that the JBNm presented synergistic functions from JBNts and matrilin, which can create a microenvironment selectively promoting chondrogenesis and stem cell differentiation. Moreover, the JBNm-enabled cartilage-on-a-chip demonstrated significantly improved reusability and longevity. These JBNm cartilage-on-chips can be used for disease modeling and drug screening for a variety of situations. | 12:30 | | Keynote Presentation The NIH Microphyiological Systems Program: In Vitro 3D Models for Safety and Efficacy Studies Danilo Tagle, Director, Office of Special Initiatives, National Center for Advancing Translational Sciences at the NIH (NCATS), United States of America
Approximately 30% of drugs have failed in human clinical trials due to
adverse reactions despite promising pre-clinical studies, and another
60% fail due to lack of efficacy. A number of these failures can be
attributed to poor predictability of human response from animal and 2D
in vitro models currently being used in drug development. To address
this challenges in drug development, the NIH Tissue Chips or
Microphysiological Systems program is developing alternative innovative
approaches for more predictive readouts of toxicity or efficacy of
candidate drugs. Tissue chips are bioengineered 3D microfluidic
platforms utilizing chip technology and human-derived cells and tissues
that are intended to mimic tissue cytoarchitecture and functional units
of human organs and systems. In addition to drug development, these
microfabricated devices are useful for modeling human diseases, and for
studies in precision medicine and environment exposures. Presentation
will elaborate in the development and utility of microphysiologicals
sytems and in the partnerships with various stakeholders for its
implementation. |
| 13:00 | Networking Luncheon in the Exhibit Hall -- Network with the Exhibitors, View Posters and Engage with Colleagues | | Please View the Agenda for the Afternoon Session Under the POC Diagnostic Track Website Agenda |
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