08:00 | Conference Registration, Materials Pick-Up, Morning Coffee and Pastries |
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Session Title: Multi-Cellular Engineered Living Systems Summit |
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09:15 |  | Conference Chair Conference Chairperson's Welcome, Introduction and Topics Addressed
Roger Kamm, Cecil and Ida Green Distinguished Professor of Biological and Mechanical Engineering, Massachusetts Institute of Technology (MIT), United States of America
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09:30 |  | Keynote Presentation Tissue Organoids For Disease Modeling
Shay Soker, Professor of Regenerative Medicine and Chief Science Program Officer, Wake Forest Institute for Regenerative Medicine, United States of America
Traditional in vitro two dimensional (2D) cell cultures fail to recapitulate the microenvironment of in vivo tissues. They have three major differences from native tissue microenvironments: substrate topography, substrate stiffness, and most importantly, a 2D rather than three dimensional (3D) architecture. In contrast, 3D human tissue organoids replicate native tissue structure and function and thus are superior to traditional 2D cultures and animal models. These organoids can be studied in vitro for several weeks to allow intensive investigations. Besides their advantages in drug toxicity testing and for development of new drugs, the human tissue organoid platform serves as a model system to explore human tissue development and disease. Our recent research was focused on the use of human tissue organoids to study liver development and congenital diseases as well as other common diseases such as tissue fibrosis and cancer. Altogether our human tissue organoids system can be used for modeling of a wide verity of diseases and develop new personalized/precision medicine applications. |
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10:15 | Morning Coffee Break and Networking |
11:00 |  | Keynote Presentation Parkinson’s-On-a-Chip: Unravelling the Complexity of Neurodegenerative Diseases Using a Chip-based Midbrain Organoid Model
Peter Ertl, Professor of Lab-on-a-Chip Systems, Vienna University of Technology, Austria
One of the main limitations in neuroscience and in the modeling and understanding of neurodegenerative diseases is the lack of advanced experimental in vitro models that truly mimic the complexity of the human brain. With its ability to emulate microarchitectures and functional characteristics of native organs in vitro, induced pluripotent stem cell technology has enabled the generation of human midbrain organoids. To improve organoid reproducibility and iPSC differentiation, we have developed a sensor-integrated organ-on-a-chip platform allowing long-term cultivation and non-invasive monitoring of hMOs under an interstitial flow regime. Our results show that dynamic cultivation of iPSC-derived hMOs maintains high cellular viabilities and dopaminergic neuron differentiation over prolonged cultivation periods of up to 50 days, while neurotransmitter release of hMOs is detected using an electrochemical sensor array. |
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11:45 |  | Keynote Presentation Body on a Chip: Human Microscale Models for Drug Development
James Hickman, Professor, Nanoscience Technology, Chemistry, Biomolecular Science and Electrical Engineering, University of Central Florida; Chief Scientist, Hesperos, United States of America
The preclinical drug development process is inefficient at selecting drug candidates for human clinical trials, since only 11% of drug candidates selected for clinical trials exit with regulatory approval. Current technology is based on isolated human cells and animal surrogates. We believe that a “human” multiorgan model based on physiologically based pharmacokinetics-pharmacodynamic (PBPK-PD) models that house interconnected modules with tissue mimics of various organs. The system captures key aspects of human physiology that would potentially reduce drug attrition in clinical trials and decrease the cost of development. Integrated, multi-organ microphysiological systems (MPS) based on human tissues (also known as “body-on-a-chip”) could be important tools to improve the selection of drug candidates exiting preclinical trials for those drug most likely to earn regulatory approval from clinical trials. This methodology integrates microsystems fabrication technology and surface modifications with protein and cellular components, for initiating and maintaining self-assembly and growth into biologically, mechanically and electronically interactive functional multi-component systems.
I will describe such systems being constructed at Hesperos and at UCF that are guided in their design by a PBPK model. They are “self-contained” in that they can operate independently and do not require external pumps as is the case with man other microphysiological systems. They are “low cost”, in part, because of the simplicity and reliability of operation. They maintain a ratio of fluid (blood surrogate) to cells that is more physiologic than in many other in vitro systems allowing the observation of the effects of not only drugs but their metabolites. While systems can be sampled to measure the concentrations of drugs, metabolites, or biomarkers, they also can be interrogated in situ for functional responses such as electrical activity, force generation, or integrity of barrier function. Operation up to 28 days has been achieved allowing observation of both acute and chronic responses with serum free media. We have worked with various combinations of internal organ modules (liver, fat, neuromuscular junction, skeletal muscle, cardiac, bone marrow, blood vessels and brain) and barrier tissues (eg skin, GI tract, blood brain barrier, lung, and kidney). The use of microelectrode arrays to monitor electrically active tissues (cardiac and neuronal) and micro cantilevers (muscle) have been demonstrated. Most importantly these technical advances allow prediction of both a drug’s potential efficacy and toxicity (side-effects) in pre-clinical studies. This talk will also give results of six workshops held at NIH to explore what is needed for validation and qualification of these new systems. |
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12:30 | Lunch |
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Session Title: Organoids and 3D-Culture - Technologies and Applications |
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14:30 |  | Keynote Presentation Microfluidics For Interrogating Intact Tumor Biopsies
Albert Folch, Professor of Bioengineering, University of Washington, United States of America
The intricate microarchitecture of tissues – the “tissue microenvironment” – is a strong determinant of tissue function. Microfluidics offers an invaluable tool to precisely stimulate, manipulate, and analyze the tissue microenvironment in live tissues and engineer mass transport around and into small tissue volumes. Such control is critical in clinical studies, especially where tissue samples are scarce (e.g. tumor biopsies), in analytical sensors, where testing smaller amounts of analytes results in faster, more portable sensors, and in biological experiments, where accurate control of the cellular microenvironment is needed (e.g. organ-on-a-chip). Microfluidics also provides inexpensive multiplexing strategies to address the pressing need to test large quantities of drugs and reagents on a single biopsy specimen, increasing testing accuracy, relevance, and speed while reducing overall diagnostic cost. I will discuss the development of our platforms for cancer diagnostics that allow for multiplexed functional drug testing on live, intact tissues in various formats: 1) tumor slices; 2) core needle biopsies; and 3) cuboids (precision-sliced tumor fragments that retain viability and the tumor microenvironment for several days). These platforms are currently under commercial development by startup OncoFluidics. |
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15:00 | Ex Vivo Immuno-Oncology Dynamic Environment For Tumor Biopsies
Jeffrey Borenstein, Group Leader, Synthetic Biology; Director, Biomedical Engineering Center, Draper, United States of America
We present the design, construction and testing of a microfluidic perfused tumor microenvironment platform capable of evaluating the efficacy of immune checkpoint inhibitors with circulating immune cells in mouse and human tumor biopsy fragments. |
15:30 | Afternoon Coffee Break |
16:15 | Modeling Immune Mediated Beta Cell Destruction in Human Type 1 Diabetes with Organoids
Matthias von Herrath, Vice President and Senior Medical Officer, Novo Nordisk, Professor, La Jolla Institute, United States of America
In the past 15 years we have been studying the pathology of human type 1 diabetes with access to donor pancreata through the human pancreatic organ donor consortium (nPOD). These studies have led to several findings, for example that certain cytokines are generated by beta cells themselves, sometimes under stress, and also that there are probably key factors that render beta cells susceptible to immune attacks. Mechanistically, the importance and meaning of these observations needs to be addressed in a suitable and easily manipulable in vitro system consisting of human islets and immune cells. We have built such a system in collaboration with the company InSphero and will discuss emerging findings. |
16:45 | | Keynote Presentation Vascular Networks on a Chip and Their Applications
Roger Kamm, Cecil and Ida Green Distinguished Professor of Biological and Mechanical Engineering, Massachusetts Institute of Technology (MIT), United States of America
Due to the capacity of vascular endothelial cells to self-assemble into 3D vascular networks in a conducive hydrogel, it is now possible to grow microvasculature within microfluidic chips comparable to in vivo capillary beds in both morphology and function. These systems have numerous applications including vascularized organs-on-chip, studies of transport across the vascular endothelium, and models of disease. This presentation will focus on the growth of these networks and quantitative analysis of their morphology and transport properties. Results will be discussed showing networks grown from several different sources of endothelial cells that stabilize over 4-7 days, and can then be maintained in some cases for periods of over one month. Various accessory cells are used, including fibroblasts, pericytes and mesenchymal stem cells, and these contribute to changes in matrix composition and mechanics over time. Examples will be used to illustrate some of the potential applications of these vascularized models, selected from metastatic cancer, the blood-brain barrier, and cerebral amyloid angiopathy.
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17:15 | Close of Day 1 of the Conference |
