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SELECTBIO Conferences Innovations in Microfluidics 2024: Rapid Prototyping, 3D-Printing

Innovations in Microfluidics 2024: Rapid Prototyping, 3D-Printing Agenda

Co-Located Conference Agendas

Innovations in Microfluidics 2024: Rapid Prototyping, 3D-Printing | 

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Monday, 6 May 2024


Conference Registration and Materials Pick-Up + Coffee in the Exhibit Hall


Albert FolchConference Chair

Welcome and Introduction by Conference Chairperson -- Scope of the Conference and Topics Covered
Albert Folch, Professor of Bioengineering, University of Washington, United States of America

Session Title: 3D-Printing of Microfluidics


Gregory NordinKeynote Presentation

High Resolution Negative Space 3D Printing for Microfluidics
Gregory Nordin, Professor, Brigham Young University, United States of America

While there is great interest in 3D printing for microfluidic device fabrication, a main challenge has been to achieve feature sizes that are in the truly microfluidic regime (<100 µm). A key issue is that microfluidic devices are comprised primarily of negative space features, which therefore dominate 3D printing resolution requirements, as compared to positive space features that are typical for many other 3D printing applications. Consequently, we have developed our own stereolithographic 3D printers and materials that are specifically tailored to meet these needs. We have shown 3D printed channels as small as 18 µm x 20 µm, and have recently reduced this to 2 µm x 2 µm. We have also developed active elements such as valves and pumps with the smallest valves having an active area of only 15 µm x 15 µm. In this presentation we discuss how such results are achieved and demonstrate miniaturized components including small (<1mm^3) fast (~1 ms) mixers and isoporous membranes with 7 µm pores. We also demonstrate integrated 3D printed devices such as for controllable cell chemotaxis. Advances in negative space 3D printing open the door to replacing expensive cleanroom fabrication processes with 3D printing, with the additional advantage of fast (~5-15 minute), parallel fabrication of many devices in a single print run due to their small size.


Noah MalmstadtKeynote Presentation

Title to be Confirmed.
Noah Malmstadt, Professor, Mork Family Dept. of Chemical Engineering & Materials Science, University of Southern California, United States of America


A High Resolution, SLA PDMS Resin and its Application in Microfluidic Organ Models
Joseph Potkay, Research Assistant Professor, University of Michigan, Clinical Research Engineer, VA Ann Arbor Healthcare System, United States of America

This presentation will cover our progress toward developing and characterizing a high resolution and biocompatible polydimethylsiloxane SLA 3D printing resin and its use to create various microfluidic structures including microfluidic artificial lungs.


Mid-Morning Coffee Break and Networking in the Exhibit Hall


Bonnie GrayKeynote Presentation

Additive Manufacturing for Microfluidic and Wearable Sensor Systems
Bonnie Gray, Professor of Engineering Science, Simon Fraser University, Canada

We are surrounded by sensors in our daily lives. These (usually) small, inobtrusive devices constantly capture data about our environment, and what we see, hear, and do. Sensors form the foundation for analysis systems and are an integral part of every closed-form system. Many sensors seek to provide more continuity for health and well-being via constant monitoring of important health parameters. Similarly, other sensors seek to address the health of other systems, such as preventing failures in the power grid. Sensors as discrete components may be difficult to integrate into low-profile systems, such as textile-based systems, for development of smart clothing. These and other sensors systems could benefit from 3D printing or other additive manufacturing methods, via the integration of conventional printing materials with new functional (e.g., sensing or actuating) printed materials. Sensors could thus be easily tailored and printed to individual needs and more easily integrated with other printed components. This presentation focuses on development of wearable and other printed sensors that are designed directly on textiles, or fabricated using 3D printing methods for easier integration with fluidic housings. We discuss the current state-of-the-art, and present examples of integrated textile-based and printing-based sensors. We investigate how advances in flexible devices and systems (electronics, sensors, actuators, microfluidics) and additive manufacturing (e.g., printing) can be adapted to low-profile, non-obtrusive, and personalized sensor systems.


Leanna LevineKeynote Presentation

Integration and DFM for Microfluidics
Leanna Levine, Founder & CEO, ALine, Inc., United States of America

Most microfluidic cartridges require integration of mixed materials and components to create the complete functional product architecture. This talk will address the key considerations for DFX while leveraging a range of prototyping techniques including 3D printing, CNC machining, Injection molding and Laminate Fluid Circuit Technology, to position a product for transfer to scale up with high volume manufacturing techniques.


Networking Buffet Lunch in the Exhibit Hall -- Networking with Colleagues, Engage with Exhibitors and View Posters


Ryan SocholKeynote Presentation

3D-Printed Microfluidic Circuitry via Alternative Additive Manufacturing Strategies
Ryan Sochol, Associate Professor, University of Maryland, College Park, United States of America

Over the past decade, researchers have demonstrated that additive manufacturing—or “three-dimensional (3D) printing”—approaches provide powerful means for achieving integrated microfluidic circuits and systems.  Although the majority of developments in the area of 3D-printed microfluidic circuitry have relied on mesoscale “vat photopolymerization” techniques, such as “stereolithography”, there are a wide range of additive manufacturing approaches that offer utility for microfluidic circuit design, fabrication, and integration.  In this talk, Prof. Ryan D. Sochol will discuss how his Bioinspired Advanced Manufacturing (BAM) Laboratory is leveraging the capabilities of alternative additive manufacturing technologies—namely “PolyJet 3D Printing” and “Two-Photon Direct Laser Writing”—to realize 3D-printed microfluidic circuits for soft robotic applications… including a soft robotic “hand” that plays Nintendo.


Kloé Technology Spotlight Presentation


Mid-Afternoon Coffee Break and Networking in the Exhibit Hall


3D-Printed Epidermal Microfluidic Systems
Tyler Ray, Professor, University of Hawaii at Manoa, United States of America

An emerging class of wearable devices integrates microfluidic lab-on-chip designs with low-modulus materials, colorimetric assays, and electrochemical sensors to support the real-time, non-invasive analysis of sweat. Such skin-interfaced microfluidic systems offer powerful capabilities for personalized assessment of health, nutrition, and wellness through the non-invasive, real-time analysis of sweat. Initially simple systems of microfluidic channels, current devices comprise sophisticated networks channels, valves, and reservoirs with some embodiments employing multilayer design strategies. While these platforms exhibit powerful analytical capabilities, device fabrication requires time, labor, and resource-intensive cleanroom processing, which restricts the device design space (2D) and elongates the development time. Additive manufacturing processes, particularly stereolithography (SLA)-based printing, offer powerful pathways for overcoming these limitations by providing significant reductions in prototype development cost and cycle time while substantially expanding device capabilities with fully 3D device designs. Here, we present a simplified 3D-printing prototyping process to fabricate flexible, stretchable, epidermal microfluidic devices (‘3D-epifluidics’). Reducing fabrication time to [O]min, this approach enables the integration of spatially-engineered features including 3D-structured passive capillary valves, monolithic channels, and reservoirs with spatially-graded geometries. With geometric features comparable to established epifluidic devices (channels >50 µm), benchtop and on-body testing validate the performance of 3D-epifluidic devices.


Shuichi TakayamaKeynote Presentation

High-Throughput Lung Microphysiological Systems
Shuichi Takayama, Professor, Georgia Research Alliance Eminent Scholar, and Price Gilbert, Jr. Chair in Regenerative Engineering and Medicine Wallace H. Coulter Department of Biomedical Engineering, Georgia Institute of Technology & Emory University School of Medicine, United States of America

There is a need to better understand lung disease, accelerate drug discovery, and better predict human clinical trial outcomes and individualized drug responses. This presentation will describe efforts to develop microphysiological systems (MPSs) to accomplish this goal. Specific topics include the first microfluidic lung-on-a-chip developed at Michigan. A Transwell-96 based air-blood barriers that can be coupled with automated flow cytometry. And a 384 well format assay using lung Organoids with Reversed Biopolarity (lung-ORBs). Specific applications include single-ORB based high-throughput assays of SARS-CoV-2 infection and therapeutics, neutrophilic inflammation studies, and analyzing the injurious effects of fluid mechanical effects associated with lung stethoscope sounds.


Close of Day 1 of the Conference Programming


Networking Reception


Close of Day 1 of the Conference

Tuesday, 7 May 2024


Morning Coffee, Pastries and Networking in the Exhibit Hall


Expanding the Droplet-Microfluidics Toolkit with Electrokinetics
Robbyn Anand, Associate Professor, Iowa State University, United States of America

Droplet-based techniques have had a profound impact in biotechnology, owing to an ability to perform rapid and massively parallel reactions in minute fluid volumes. However, once droplets are formed, their composition can be altered through limited functions including the addition of reagents through droplet merging, which increases droplet volume, and through in-droplet mixing. Further, while droplet contents can be measured through, there remains a need for more versatile methods to probe droplets without significantly altering their contents. In this presentation, we describe a suite of in-droplet electrokinetic methods including de-mixing, mobility-based separations, desalting, and “salting”. Finally, we will share initial results for the measurement of the ionic content of droplets.


Mandy EschKeynote Presentation

Title to be Confirmed.
Mandy Esch, Project Leader, National Institute of Standards and Technology (NIST), United States of America


Sunitha NagrathKeynote Presentation

Micro Innovations Defining the New Frontiers of Liquid Biopsy
Sunitha Nagrath, Professor of Chemical Engineering and Biomedical Engineering, University of Michigan-Ann Arbor, United States of America

Microfluidic technologies were always at the forefront of innovations in liquid biopsies. There were several corner stone microfluidic technologies that enabled sensitive and yet specific identification of blood-based biomarkers. The confluence of technology advancement and rapid developments in molecular characterization techniques pushed the boundaries of liquid biopsies thus enhancing the clinical utility of blood biopsies. Several such key enabling technologies will be presented. How isolation of circulating tumor cells using novel microfluidic technologies can enable precision diagnostics will be demonstrated with the example clinical case studies.


Mid-Morning Coffee Break and Networking in the Exhibit Hall


David JunckerKeynote Presentation

Custom and Mass Manufacturing of High Resolution Microfluidics by Low Cost SLA 3D Printing
David Juncker, Professor and Chair, McGill University, Canada

I will present our work on stereolithography DLP and LCD 3D printing for microfluidics and notably how it elevated and transformed capillaric circuits (CC); CCs are structurally-encoded pre-programmed capillary microfluidics operating without moving part, peripherals nor computer, and powered by the free surface energy of paper. Capillaric circuits are hierarchically built from basic elements such as microchannels, resistances, pumps, valves (incl. stop-, trigger-, retention-, retention burst-, and domino-valves) and more complex sub-systems such as microfluidic chain reactions for scalable, algorithmic liquid handling operations. The progression from replica molding to digital manufacturing – i.e. from a digital file to functional device thanks to new hydrophilic inks – will be illustrated with various designs, notably the ELISA chip for point-of-care diagnostics. The potential of ultra-low cost LCD 3D printers and custom inks for microfluidics will be illustrated via microfluidic mixers, active valves, ELISA chips, and by mass manufacturing thousands of organ-on-chip devices in a single run. SLA 3D printing together with tailored inks pave the way for high-resolution distributed manufacturing of ready-to-use microfluidic systems (e.g. CCs with structurally encoded algorithms ) anywhere, by anyone who can spare US$300 to buy an LCD 3D printer.


3D-Printing in the Microfluidics Field -- Current Status
Albert Folch, Professor of Bioengineering, University of Washington, United States of America


Networking Buffet Lunch in the Exhibit Hall -- Networking with Colleagues, Engage with Exhibitors and View Posters


Jianping FuKeynote Presentation

Bioengineered Human Embryo and Organ Models
Jianping Fu, Professor, Mechanical Engineering, Biomedical Engineering, Cell & Developmental Biology, University of Michigan-Ann Arbor, United States of America

Early human development remains mysterious and difficult to study.  Recent advances in developmental biology, stem cell biology, and bioengineering have contributed to a significant interest in constructing controllable, stem cell-based models of human embryo and organs (embryoids / organoids).  The controllability and reproducibility of these human development models, coupled with the ease of genetically modifying stem cell lines, the ability to manipulate culture conditions and the simplicity of live imaging, make them robust and attractive systems to disentangle cellular behaviors and signaling interactions that drive human development.  In this talk, I will describe our effort in using human pluripotent stem cells (hPSCs) and bioengineering tools to develop controllable models of the peri-implantation embryonic development and early neural development.  The peri-implantation human embryoids recapitulate early post-implantation developmental landmarks successively, including amniotic cavity formation, amniotic ectoderm-epiblast patterning, primordial germ cell specification, development of the primitive streak, and yolk sac formation.  I will further discuss an hPSC-based, microfluidic neural tube-like structure (or µNTLS), whose development recapitulates some critical aspects of neural patterning in both brain and spinal cord regions and along both rostral-caudal and dorsal-ventral axes.  The µNTLS is further utilized for studying development of different neuronal lineages, revealing pre-patterning of axial identities of neural crest progenitors and functional roles of neuromesodermal progenitors and caudal gene CDX2 in spinal cord and trunk neural crest development.  We have further developed dorsal-ventral patterned, microfluidic forebrain-like structures (µFBLS) with spatially segregated dorsal and ventral regions and layered apicobasal cellular organizations that mimic human embryonic brain development in pallium and subpallium areas, respectively.  Together, both µNTLS and µFBLS offer 3D lumenal tissue architectures with an in vivo-like spatiotemporal cell differentiation and organization, useful for studying human neurodevelopment and disease.


Enhancing the Hemocompatibility of 3D-Printable Silicone Elastomers for Artificial Lung Applications
Riya Aggarwal, Student Researcher, Potkay Laboratory, University of Michigan - Ann Arbor, United States of America

In this study, we investigate the nonthrombogenic effects of imbuing our polydimethylsiloxane (PDMS) based 3D-printable resin with hydrophilic molecules with the goal of reducing the body’s natural coagulation response to foreign materials, coming closer to mimicking the native blood interface.

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