©MIMETAS

Monday, June 10, 2024 | 1:00 PM – 4:30 PM PT


Register for Track 1


Our field of Microphysiological Systems (MPS) is characterized by rapid evolution, with ongoing technological advancements driving our understanding of human biology and the development of predictive drug testing models, as well as applications in regenerative and personalized medicine. This rapid progress is made possible by the close collaboration between the academic and private sectors.

The Educational Session of the MPS meeting is designed to facilitate the interaction between young scientists and established leaders in both the academic and company environment in our field through a combination of hands-on experience and discussions. Moreover, young investigators in our field frequently face the decision of pursuing a career path in academia or industry.

In 2024, we are thrilled to introduce a novel format for the Educational Session. We plan to elevate the educational experience by presenting three distinct education sessions, each catering to different facets of our field:

  • Track 1 – Hands-On Experience. Building on the education session of the past two years, this track is designed for immersive learning. Attendees will have the opportunity to gain practical, hands-on experience with the latest Chips, microfluidic controllers, and other essential tools in the field. Through live demonstrations and interactive presentations, they will explore real-world experiments and gain insight into the latest developments in OOC and MPS technology.
    • Why you should attend. Young investigators in our field are often limited in the use and exposure to emerging technologies. This session, therefore, provides direct access to some of the newest and well-established technology existing today.

HOW SIGN-UP WORKS:

Participants may only sign up for four (4) sessions.

Please sign up for one session per time slot.

  • Session 1 will run from 1:10pm-1:50pm
  • Session 2 will run from 2:00pm-2:40pm
  • Session 3 will run from 2:50pm-3:30pm
  • Session 4 will run from 3:40pm-4:20pm


Presenters

AIM Biotech

AIM Inside: Mirror tissue ecosystems and dynamic transport using AIM Biotech’s vascularized BioAvatars

Predictive drug testing requires the development of true-to-life disease models that capture the complexity of entire tissue ecosystems, including barriers to drug administration and dynamic transport of therapeutics. Participants will learn how AIM Biotech approaches the design and implementation of humanized cell culture platforms, BioAvatars, that incorporate vascularized 3D microenvironments to achieve relevant cell-cell and cell-ECM interactions. Participants will gain hands on experience using the “plug-and-play” platforms, which allow gas exchange without the need for pumps or plate rocking.

Trainees will learn:


CN Bio

Utilizing the PhysioMimix platform to explore transport and metabolism through tissue barrier models

Understanding how to establish biologically-relevant in vitro models of tissue barriers and how to apply these models to better understand drug transport and metabolism by said barriers.

Trainees will learn:


Dynamic42 GmbH

Immunocompetent models of liver- and vasculature-on-chip systems for drug testing and disease modeling

Trainees will learn:


Emulate

Harnessing Organ-Chips to Model Immune Response in Inflammatory Disease and Cell Therapy

This hands-on course will focus on how researchers can incorporate resident and circulating immune cells into Organ-Chips to study inflammatory immune response and cell therapy efficacy. It will include guidance for translating workflows from 2D to 3D cell culture, as well as the advantages/limitations of immunocompetent Organ-Chip models.

In the hands-on portion, attendees will have the opportunity to learn how to handle Emulate Organ-chips, prepare chip samples, and operate the Human Emulation System from our Organ-chip experts.

Trainees will learn:

  1. How to set up organ-chip cultures using the Human Emulation System, and how to obtain chip samples for multiplex data generation
  2. How circulating immune cells can be incorporated into Organ-Chip model designs to study inflammatory immune response and immunotherapy efficacy.
  3. Building complexity: How to translate your workflow from 2D to 3D cell culture and incorporate immunocompetence into your Organ-Chip models.


innoVitro GmbH

Mechanobiology in drug testing: High throughput in vitro systems with controlled physiological environment

The trainees will get an introduction to basic principles in mechanobiology, exemplified with e.g. Frank-Starling mechanism and stretch-sensitive cellular components. In a hands-on-demonstration, they will handle multiwell systems (24 to 96 well format) to control and measure the mechanical conditions of cell cultures. In parallel, representative results of cell analyses will be displayed and discussed. Participants will explore different levels of physiological and super-physiological stretching of tissue-like structures with the mechanical properties of human tissue and see the effect of such stretch application macroscopically.

The trainees will learn:

  1. The importance of the cellular mechanical environment for physiological drug responses
  2. Basic principles and considerations of in vitro mechanobiology (e.g. elasticity, plasticity, physiological stress and stretch levels)
  3. Hands-on experience with 24-96 well cell culture systems for physiological mechanical stimulation and the measurement of contractile responses


InSphero AG

Adding immune competence to 3D in vitro disease models – Finding the sweet spot between biological complexity and scalability by using Akura Technology

This hands-on course will focus on InSphero’s approaches on how immune competence can be added to 3D in vitro models for drug testing and disease modelling. Based on applications in the field of liver safety, metabolic diseases, and immune oncology, InSphero’s concepts of biological complexity, reproducibility and scalability will be explained. We will show examples on:

  • How innate and adaptive immune response can be modelled in the Akura™ 96 Spheroid Microplates.
  • How immune mediated drug-induced liver toxicity of, for example, bispecific antibodies can be modelled in the Akura™ Twin Microplate, the simplest and most scalable organ-organ crosstalk platform.
  • How immune cell attachment to 3D tissues can be modelled in the Akura™ Immune Flow Platform, a long-term immune cell perfusion platform.

After the theoretical part, trainees will have the opportunity to perform medium exchange in all 3 platforms and thereby getting a feeling for scalability and automation-compatibility of the individual systems.

The trainees will learn:

  1. Different concepts and designs to study immune competence in vitro.
  2. How engineering helps to overcome biological challenges.
  3. Impressions of scalability and automation in industrial settings.


MIMETAS

Using MPS for high-throughput phenotypic screening

This hands-on course will focus on a high-throughput MPS platform, the OrganoPlate, for phenotypic screening. We will review the important considerations in setting up a high-throughput screen with 6 different example phenotypic assays including angiogenesis, immune cell migration, gut barrier disruption, neurite outgrowth, fibrosis, and vascular barrier disruption. Participants will gain hands-on experience working with the Mimetas OrganoPlate and perfusion system.

The trainees will learn:

  1. Considerations in designing high-throughput phenotypic assays for MPS
  2. How to handle a high-throughput MPS platform


NeuCyte, Inc.

Development of AD/ADRD MPS Platforms for Drug Screening

Combining iPSC-derived cells in defined ratios to establish AD/ADRD models for therapeutic discovery.

The trainees will learn generation of AD/ADRD 3D NeuroImmune models, assessment of reproducibility, development of 3D assays.


Organ-on-Chip Centre Twente (OoCCT), University of Twente

The Translational Organ-on-Chip Platform (TOP): An introduction to ISO-driven modular microfluidics for organs-on-chip research

In this hands-on, educational training session, participants will gain experience with the operation and design of ISO-driven, modular organ-on-chip platforms. We will give instructions on user-friendly application of ISO 22916:2022 and allow attendees to directly work with examples of TOP, our ISO compliant platform, and exemplary modules relevant to experimental end-goals. Participants will come away with a better understanding of the need for standardization within the field of organ-on-chip and of how to apply existing standards using the TOP Design Rules (TDRs), a strict subset of ISO-defined standards.

The trainees will learn:

  1. How to apply open design standards to organ-on-chip designs
  2. Design requirements and interfacing methods for modular microfluidics
  3. Benefits of modular microfluidics for experiments and experimental end-points
  4. Stakeholder roles in the development of TOP and organ-on-chip standards


Ossiform

Development of a novel 3D printed b-TCP scaffold for mimicking bone in vitro

3D cell culturing scaffolds for in vitro bone research as an alternative to animal models.

The trainees will learn the importance of relevant tissue models (soft vs hard tissues), how our scaffolds effectively mimic our bones in composition and structure, and applicability of our scaffolds and how they compare to animal models/animal-derived alternatives.


SynVivo Inc.

Vascularized Organ-on-Chip models for drug safety and efficacy testing

Vascularized Organ-on-Chip models provide realistic assessment of drug delivery, cell-cell, cell-drug interactions, and their underlying mechanisms toward the identification of toxicity and efficacy responses during drug development. This session will present the latest approaches to produce and standardize vascularized on-Chip models as cellular platforms for drug safety and efficacy testing, or in pathological models. Discussion includes Vasculature, Tumor, Lung ALI, Blood Brain Barrier, and Inflammation-on-Chip models.

The trainees will learn:

  1. Functionalizing the organ-on-chip model to mimic in vivo microenvironments.
  2. Standardizing your model- Understand what biological questions your model can answer.
  3. Assay Readouts to assess vascular injury induced by drugs or inflammation
  4. Hands-on demonstration of chips, syringe pumps for flow, and TEER-on-Chip devices and impedance analyzers.


TissUse GmbH

Bridging the Gap: Hands-On Training on Connecting Barrier and Parenchymal Organ Models for Permeation and Drug Metabolism Research

The trainees will learn:

  1. General handling of the HUMIMIC Chips
    • Chip2 (co-culture of up to 2 organ models)
    • Chip3 (co-culture of up to 3 organ models)
    • Chip4 (co-culture of up to 4 organ models)
  2. Load the Chips with
    • Cell culture insert for barrier models
    • Cell suspension for 2D culture or matrix based organ models
    • Spheroids
    • 3D Matrix
  3. Practice how to perform a medium exchange
  4. Connect HUMIMIC Chips to the Starter (Control Unit)
  5. Time for questions and discussions


University of Central Florida & Hesperos Inc.

Design and application of pumpless function based multiorgan systems for disease modeling and therapeutic evaluation

The hands-on course will focus on the use and design of multiorgan systems with interchangeable organ components specific to the application at hand. Trainees will learn about integration of functional bioMEMs devices, as well as biomarker investigation capabilities on an interconnected microfluidic human-on-a-chip device, and the subsequent ability to translate these data to clinically relevant readouts.

The trainees will learn:

  1. How surface patterning can provide advantages for functional cell culture
  2. The ability of pumpless multiorgan devices to model various diseases
  3. Application of multiorgan devices for testing drug efficacy as well as off target toxicity
  4. The importance of functional readouts for greater clinical translatability


University of Twente

Combining cell microencapsulation approaches with organs-on-chips towards highly defined micro-environments

This hands-on course will focus on the development of complex 3D tissue models on-chip that allows biomimicry of compartmentalised cellular microenvironments, thereby enabling tight control over cell cell and/or cell ECM interactions. To this end, we will demonstrate how to use microfluidic droplet generators to homogeneously fabricate spherical cellular micro-compartments. These highly defined cellular micro-niches show unprecedent tunability of chemical/physical cues and are highly compatible with defined spatial cell assembly within microfluidic 3D culture systems. More specifically, we will present a case study reporting how this methodology can be applied in a bone-on-chip platform to generate compartments and separate distinct cellular populations on-chip.

The trainees will learn:

  1. Learn about cell micro-encapsulation techniques that can be combined with organ-on-chip platforms, which permit a tight control over the number of encapsulated cells per microgel.
  2. Applied case studies illustrating a micro-encapsulation technique that is compatible with either cell centring within the microgel or creating cell niches within hollow microspheres (by e.g., non-invasive microgel digestion).
  3. Identify possibilities for high-throughput cell micro-encapsulation methods that allows for scale-up processes.