Innovation examples

Thyroid Hormone & Brain Development: animal-free models for human safety assessment
Innovation examples
HealthInnovationIn vitro

Thyroid Hormone & Brain Development: animal-free models for human safety assessment

The environment can have a significant impact on a child's health even before birth. Brain development begins in the first trimester and continues until the age of 25, with thyroid hormone playing a critical role. During early pregnancy, the fetus depends on the mother's thyroid hormone, and a disruption in the thyroid hormone balance can lead to cognitive and motor impairments in the child. As part of the VHP4Safety project, we are developing in vitro tests to measure the developmental neurotoxic effects caused by disturbances thyroid hormone concentrations. Current testing guidelines do not always include testing for neurodevelopmental effects, highlighting the need for new non-animal methods. At the Erasmus Medical Center, human cell lines representing brain cell types are cultured to study the effect of chemicals on the thyroid hormone balance. RIVM uses human stem cells to create neuron-astrocyte networks that mimic brain development. By combining these different assays and models, we are creating a comprehensive human-based testing strategy to assess developmental neurotoxicity. These advances are a critical step toward eliminating animal testing while protecting the health and environment of future generations.
02:5312 days ago
Cultured human skin for burn research
Innovation examples
HealthIn vitro

Cultured human skin for burn research

Burns are often accompanied by a dysregulated immune response, which can lead to systemic inflammation, impaired immunity, and excessive scarring. A deeper understanding of the mechanisms behind burns—where wound healing and inflammatory reactions are severely disrupted—holds the key to improving patient outcomes. Patrick Mulder, a postdoctoral researcher at the Burn Research Lab in Beverwijk, the Netherlands, works with his colleagues to develop animal-free skin models based on human cells and patient-derived tissues. Using these innovative, human-relevant models, he aims to provide greater insight into the body’s response to burns and studies the effects of existing and new treatments on wound healing. Click on the info button for the full version of the video.
00:2932 days ago
An iPSC-derived blood-brain barrier to model neurodegeneration
Innovation examples
HealthIn vitroOrgan-on-Chip

An iPSC-derived blood-brain barrier to model neurodegeneration

The blood-brain barrier is a layer of cells that protects our brain from harmful compounds. However, due to this tight barrier, many drugs to treat neurological diseases cannot enter the brain either. There are currently no good models to test these types of drugs. Henrique Nogueira Pinto is a PhD candidate at the Vrije Universiteit in Amsterdam. He is developing a blood-brain barrier model coupled to mini-brains. With this model, he aims to more reliably test how drugs can be transported over the blood-brain barrier and what their effect on the brain is. Click on the info button for the full version of the video. Click here (https://fluidsbarrierscns.biomedcentral.com/articles/10.1186/s12987-022-00316-0#Sec3) for a review of the current status of in vitro models for the blood-brain barrier.
01:0532 days ago
Organoids for studying (personalised) antiviral treatments
Innovation examples
HealthIn vitro

Organoids for studying (personalised) antiviral treatments

Giulia is a scientist in clinical virology with a PhD from OrganoVIR Labs at Amsterdam UMC. Her research aims to improve antiviral testing using human organoids—tiny, lab-grown tissues that mimic real human organs. The COVID-19 pandemic highlighted the urgent need for effective antiviral treatments, as traditional pre-clinical testing on animal models has only a 5% success rate in clinical trials. By utilising human organoids, Giulia enhances the accuracy of antiviral research. She specializes in infecting organoids from the airway, gut, and brain with various patient-derived viruses, allowing for more realistic modelling of viral infections. Her work also sets the stage for personalised medicine in the context of viral infections. By isolating viruses and stem cells from patients suffering from severe infections, she can test tailored treatments that are more likely to succeed. With this, she aims to revolutionise antiviral testing and improve treatment outcomes for patients. Click on the info button for the full version of the video.
00:5232 days ago
Stem cell derived Vessels-on-Chip to study brain disorders
Innovation examples
HealthIn vitroOrgan-on-Chip

Stem cell derived Vessels-on-Chip to study brain disorders

Dennis Nahon is a PhD candidate in the Department of Anatomy and Embryology at the Leiden University Medical Center. In his research, under supervision of Dr. Valeria Orlova (https://www.orlovalab.com/) and Prof. Dr. Christine Mummery, he aims to mimic a blood vessel in the brain by combining different stem cell derived cell types, in a 3D Vessel-on-Chip model. Here, an example of these in vitro blood vessels is shown in which certain brain cells known as astrocytes (in white) interact with the blood vessels (in red). This model paves the way for investigating brain vessels outside the human body, while reducing the need for animal models.
01:537 months ago
 From 2D hiPSC culture to developing a 3D vessel-on-chip
Innovation examples
In vitroOrgan-on-Chip

From 2D hiPSC culture to developing a 3D vessel-on-chip

Theano Tsikari is a 2nd year PhD student at the Orlova group at LUMC. As part of the LymphChip consortium, her project focuses on the development of immunocompetent organ-on-chip models of the cardiovascular system, and especially the integration of tissue-resident macrophages and lymphatic vasculature using human induced pluripotent stem cells. In this video, you can follow her as she presents you the backbone of her project, a 3D hiPSC-derived vessel-on-chip model, that has been previously developed in the Orlova group and can be employed for the generation of advanced in vitro models of vascular diseases.
01:297 months ago
Unified organoid system for modeling heart and kidney interaction on-a-chip
Innovation examples
In vitroOrgan-on-Chip

Unified organoid system for modeling heart and kidney interaction on-a-chip

Beatrice Gabbin is a PhD candidate at the Anatomy and Embryology Department of the Leiden University Medical Center. Her project is shared with the Nephrology Department and focusses on the study of the cardiorenal axis in vitro. Both heart and kidneys have vital functions in the human body and reciprocally influence each other’s behavior: pathological changes in one can damage the other. There are already multiple independent in vitro (human) models of heart and kidney, but none have so far captured their dynamic crosstalk. The aim of the project is therefore to develop a microfluidic system which can be used to study heart and kidney interaction in vitro. For this purpose, cardiac microtissues and kidney organoids derived from human induced pluripotent stem cells are generated and loaded onto a 3D perfusion chip for their dynamic co-culture. This system enables the study the cardiac and kidney interaction with a high level of control. The validation of a unified organoid system will enable the investigation of diseases involving the two organs and their potential treatments. Read more via the link in the video and https://doi.org/10.1016/j.mtbio.2023.100818.
01:367 months ago
Modelling COVID-19-induced thrombosis using blood-perfused Vessels-on-Chips
Innovation examples
HealthIn vitroOrgan-on-Chip

Modelling COVID-19-induced thrombosis using blood-perfused Vessels-on-Chips

A subset of hospitalized COVID-19 patients develops severe symptoms like microthrombosis and multiple organ-failure, worsening survival rates. The most inner layer of cells of a blood vessel, the endothelial cells, play a central role in the development of these complications. Their dysfunction can be replicated in advanced cell culture models like our blood-perfused Vessel-on-Chip to further understand disease mechanisms. In this short highlight, Huub Weener from the University of Twente shows how the technique works and what these models contribute to our knowledge of COVID-19.
02:017 months ago
Human based 3D liver models
Innovation examples
HealthToxicologyInnovationIn vitro

Human based 3D liver models

Human-based in vitro models are increasingly being used in the hepatology field. And in addition to the obvious ethical arguments, they offer several advantages over the classical animal models. One of them is the ability to perform mechanistic research at the molecular level in a well-controlled setting and reduce species differences. These liver-based in vitro models can range from simple monolayer cultures of hepatocytes to the liver-on-chips systems in which all liver cells are cultured in a 3D configuration on a microfluidic platform. Liver-based in vitro models must be selected on a case-by-case basis and should fit the purpose of the research, which might go from fundamental to translational research.
01:0418 months ago
Platform for in vitro airborne inhalation testing
Innovation examples
HealthToxicologyInnovationIn vitro

Platform for in vitro airborne inhalation testing

The air-liquid interface (ALI) technique uses lung cells cultured on a tiny polymer membrane in a cup. On one side of the membrane is a liquid containing the medium necessary for the cells to survive, while the other side is in contact with air. This is similar to the situation in the human lung. The compound to be tested is administered via an aerosol, vapor, or gas to mimic the situation in human lungs. By monitoring different parameters in the cell model before and after the compound is added, it is possible to measure the effects on lung cells. Depending on the test to be carried out, the lung cells can come from different regions in the respiratory tract and even from a variety of people, including individuals who smoke a lot or have specific diseases such as chronic obstructive pulmonary disease or asthma. In vitro ALI inhalation testing (https://doi.org/10.1021/acs.est.7b00493) adds value for e.g. pre-clinical trials and research in the pharmaceutical industry and testing (new) compounds for the chemical sector and beyond. The advantages of ALI inhalation testing are that it is a non-animal method, it reduces the use of in vivo experiments, pre-clinical testing with human-derived cell models is more realistic and limits clinical trial failures and it provides faster and more efficient testing of compound
04:1318 months ago
Using skin and mucosa models to replace animal testing
Innovation examples
HealthIn vitroOrgan-on-Chip

Using skin and mucosa models to replace animal testing

The skin and mucosa are important tissues that differ between species in health and disease. The group of Sue Gibbs works on the development of advanced in vitro models that mimic these two tissues, specialising in immunity models and organ-on-a-chip technologies. They use skin models to study for example melanoma, skin allergies, eczema, burns and healing wounds. Dental models are used for the safety of materials used in dentistry, for example to test the quality of the implant and false tooth when it comes to attaching to the soft tissue. Their ambition is to expand into the field of multi-organ technology to make even more relevant models for the human skin and mucosa. Click on the link in the video to watch more or read the interview with Sue he[https://vu.nl/en/research/more-about/using-skin-and-mucosa-models-to-replace-animal-testing]re.
00:3022 months ago
Using data and computational modelling in biomedical research
Innovation examples
HealthInnovationIn silico

Using data and computational modelling in biomedical research

Bioinformatics and systems biology hold great promise to translate the wealth of biological data into meaningful knowledge about human health and disease. The group of Bas Teusink helps biologists to deal with high throughput data, for example metabolomics (how cell metabolism works) and proteomics (how protein networks work) from patient material or cell cultures. This can help to better understand disease mechanisms and aid drug targeting or personalised medicine. In the future, combining data from different models (in vitro, in vivo and human data) could become a digital model of humans, or a “ digital twin”. Click on the link in the video to watch more or read the interview with Bas (and Jaap Heringa) he[https://vu.nl/en/research/more-about/using-data-and-computational-modelling-in-biomedical-research]re.
00:3022 months ago