Your search keyword '"Sarah Spitz"' showing total 4 results

1. Development of a multi-sensor integrated midbrain organoid-on-a-chip platform for studying Parkinson’s disease

Author

Sarah Spitz, Silvia Bolognin, Konstanze Brandauer, Julia Füßl, Patrick Schuller, Silvia Schobesberger, Christian Jordan, Barbara Schädl, Johannes Grillari, Heinz D. Wanzenboeck, Torsten Mayr, Michael Harasek, Jens C. Schwamborn, and Peter Ertl

Abstract

Due to its ability to recapitulate key pathological processes in vitro, midbrain organoid technology has significantly advanced the modeling of Parkinson’s disease over the last few years. However, some limitations such as insufficient tissue differentiation and maturation, deficient nutrient supply, and low analytical accessibility persist, altogether restricting the technology from reaching its full potential. To overcome these drawbacks, we have developed a multi-sensor integrated organ-on-a-chip platform capable of monitoring the electrophysiological, respiratory, and dopaminergic activity of human midbrain organoids. Our study showed that microfluidic cultivation resulted in a marked reduction in necrotic core formation, improved tissue differentiation as well as the recapitulation of key pathological hallmarks. Non-invasive monitoring employing an orthogonal sensing strategy revealed a clear time dependency in the onset of Parkinson’s disease-related phenotypes, reflecting the complex progression of the neurodegenerative disorder. Furthermore, drug-mediated rescue effects were observed after treatment with the repurposed compound 2-hydroxypropyl β-cyclodextrin, highlighting the platform’s potential in the context of drug screening applications as well as personalized medicine.

Published

2022

2. Microvasculature-on-a-Chip: Bridging the interstitial blood-lymph interface via mechanobiological stimuli

Author

Barbara Bachmann, Heinz Redl, Haddadi Sisakht B, Sarah Spitz, Wolfgang Holnthoner, Wanzenboeck Hd, Michael Harasek, Craig T. Jordan, Patrick Schuller, and Peter Ertl

Subjects

Immune system, Lymphatic system, medicine.anatomical_structure, Interstitial space, Chemistry, In vivo, Drug delivery, Cell, medicine, Lymph, Interstitial fluid flow, Cell biology

Abstract

After decades of simply being referred to as the body’s sewage system, the lymphatic system has recently been recognized as a key player in numerous physiological and pathological processes. As an essential site of immune cell interactions, the lymphatic system is a potential target for next-generation drug delivery approaches in treatments for cancer, infections, and inflammatory diseases. However, the lack of cell-based assays capable of recapitulating the required biological complexity combined with unreliable in vivo animal models currently hamper scientific progress in lymph-targeted drug delivery. To gain more in-depth insight into the blood-lymph interface, we established an advanced chip-based microvascular model to study mechanical stimulation’s importance on lymphatic sprout formation. Our microvascular model’s key feature is the co-cultivation of spatially separated 3D blood and lymphatic vessels under controlled, unidirectional interstitial fluid flow while allowing signaling molecule exchange similar to the in vivo situation. We demonstrate that our microphysiological model recreates biomimetic interstitial fluid flow, mimicking the route of fluid in vivo, where shear stress within blood vessels pushes fluid into the interstitial space, which is subsequently transported to the nearby lymphatic capillaries. Results of our cell culture optimization study clearly show an increased vessel sprouting number, length, and morphological characteristics under dynamic cultivation conditions and physiological relevant mechanobiological stimulation. For the first time, a microvascular on-chip system incorporating microcapillaries of both blood and lymphatic origin in vitro recapitulates the interstitial blood-lymph interface.

Published

2021

3. Establishment of a human three-dimensional chip-based chondro-synovial co-culture joint model for reciprocal cross-talk studies in arthritis research

Author

R. Byrne, Hans P. Kiener, B. E. M. Bachmann, Wolfgang Holnthoner, I Olmos Calvo, J Holinka, S. Schobesberger, Ariane Fischer, Peter Ertl, Reinhard Windhager, Stefan Toegel, Sarah Spitz, Heinz Redl, Florian Sevelda, Mario Rothbauer, and E. Reihs

Subjects

Chemistry, Cartilage, Arthritis, Inflammation, medicine.disease, Cell biology, medicine.anatomical_structure, Rheumatoid arthritis, Synovial joint, Joint capsule, Organoid, medicine, medicine.symptom, Synovial membrane

Abstract

Rheumatoid arthritis is characterised by a progressive, intermittent inflammation at the synovial membrane, which ultimately leads to the destruction of the synovial joint. The synovial membrane, which is the joint capsule’s inner layer, is lined with fibroblast-like synoviocytes that are the key player supporting persistent arthritis leading to bone erosion and cartilage destruction. While microfluidic models that model molecular aspects of bone erosion between bone-derived cells and synoviocytes have been established, RA’s synovial-chondral axis has yet not been realised using a microfluidic 3D model based on human patient in vitro cultures. Consequently, we established a chip-based three-dimensional tissue co-culture model that simulates the reciprocal cross-talk between individual synovial and chondral organoids. We now demonstrate that chondral organoids, when co-cultivated with synovial organoids, induce a higher degree of cartilage physiology and architecture and show differential cytokine response compared to their respective monocultures highlighting the importance of reciprocal tissue-level cross-talk in the modelling of arthritic diseases.

Published

2021

4. Cultivation and characterization of human midbrain organoids in sensor integrated microfluidic chips

Author

Jens Christian Schwamborn, Christian Jordan, Silvia Bolognin, Sarah Spitz, Mudiwa Nathasia Muwanigwa, Cristian Zanetti, Michael Harasek, Lisa M. Smits, Peter Ertl, and Emanuel Berger

Subjects

Interstitial flow, Midbrain, Brain development, Computer science, Microfluidics, Organoid, Induced pluripotent stem cell, Dopaminergic neuron differentiation, Cell biology

Abstract

1.ABSTRACTWith its ability to emulate microarchitectures and functional characteristics of native organs in vitro, induced pluripotent stem cell (iPSC) technology has enabled the generation of a plethora of organotypic constructs, including that of the human midbrain. However, reproducibly engineering and differentiating such human midbrain organoids (hMOs) under a biomimetic environment favorable for brain development still remains challenging. This study sets out to address this problem by combining the potential of iPSC technology with the advantages of microfluidics, namely its precise control over fluid flow combined with sensor integration. Here, we present a novel sensor-integrated platform for the 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.

Published

2019