Our approach

The research proposed for Pillar 3 will be performed in 4 work packages.  

Work Package 3.1: Interactions between retinal/choroidal cells and ECM   

Work Package 3.2: Design and testing advanced cell/ECM constructs 

Work Package 3.3: Biosynthetic retinal organoids – in vitro   

Work Package 3.4: Transplantation – in vivo   

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Consortium and program Cell-based therapy

Key objectives

  • To investigate the fundamental interactions between retina, supramolecules and endothelial cells in vitro 
  • To generate and evaluate in vitro functional complex retinal cellular constructs using 3D cellular bioprinting 
  • To generate and evaluate in vitro the next generation retinal organoids including blood vessels, supramolecules and appropriate neural configuration 
  • To transplant retinal constructs and/or next generation retinal organoids in animal host retinas 

Our concept Cell-based therapy

In this pillar, we will develop and combine innovative therapeutic strategies to treat age-related macular degeneration (AMD) and inherited retinal diseases (IRD).

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Our concept Cell-based therapy

Therapies aiming to preserve cells are not an option anymore once a significant proportion of retinal cells have died. Replacing dead cells along with their cell-specific microenvironment (extra-cellular matrix, ECM) is then a last resort. This exciting but challenging endeavour is the core of Pillar 3. Our first goal is to gain fundamental new insights into the properties of, and interaction between, retinal, vascular cells and supramolecules in vitro, to discover the most optimal regenerative visual functionalities. Subsequently, the most promising cells and supramolecules will be used as tools to generate and evaluate in vitro complex retinal cellular constructs using 3D cellular bioprinting, and next-generation retinal organoids-in-a-dish. Finally, we will transplant selected cells, cellular constructs, or whole retinal organoids with their ECM supramolecular matrix into the subretinal space of rat host models, and evaluate the potential of restoration of visual function.  

  

Our approach

The research proposed for Pillar 3 will be performed in 4 work packages.  

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Our innovation

We will implement regenerative medicine approaches for retinal diseases, combining cutting-edge technologies and multidisciplinary expertise to restore vision.

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Our innovation

Regenerative medicine approaches for retinal diseases are still in their infancy, but will be revolutionary for blind patients who are currently without options. To achieve the highly sought-after goal of visual restoration requires input from the entire visual field from bench to bedside. In the vein of Lifelong Vision, this pillar uniquely brings together diverse disciplines in a single team. We will be pioneering combinations of cutting-edge technology, such as stem-cell derived cells and models, supramolecular construction and application, 3D cellular bioprinting of retinal constructs, organoid modelling, progressive eye surgery, and front-line measurements of vision in animals. Each step in Pillar 3 is an innovation in its own right, together the achievements will be truly disruptive.

WP leader

Stephan Huveneers

Associate Professor        Amsterdam UMC

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Stephan Huveneers

About me

I lead the Vascular Microenvironment and Integrity lab. My research focuses on the molecular mechanisms of endothelial cell adhesions and mechanotransduction in vascular biology.

Contribution to Lifelong VISION

The Huveneers lab studies angiogenesis using advanced fluorescence microscopy applied in 2D and 3D cultures and in in vivo models. His expertise in cell-cell and cell-ECM interactions in vascularized tissue will benefit the cellular research within Pillar 3 of Lifelong Vision.

Theo Smit

Professor of Translational Regenerative Medicine Amsterdam UMC

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Theo Smit

About me

My research focus is on the role of mechanics in biology, in particular embryonic development, growth, disease and repair.

Contribution to Lifelong VISION

In Pillar 3, a cellular therapy for age-related macula degeneration is developed. To support the differentiation of iPS cells into retinal epithelial cells, an electrospun scaffold of supramolecular polymers is required. Furthermore, translation of the basic technology into an advanced therapeutic medicinal product (ATMP) is required.

Team

Céline Koster

Postdoctoral researcher Amsterdam UMC

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Céline Koster

About me

I completed my PhD in the section of Ophthalmogenetics at the Amsterdam University Medical Centers in 2022. During my PhD project, I worked on the development of differentiation protocols from stem cells towards retinal pigment epithelium cells, the development of new animal models for retinal degenerative diseases and phenotyping strategies of these preclinical models. Currently, I work as a postdoctoral researcher at the Amsterdam UMC and test experimental therapies for retinal degenerative diseases, including stem cell-derived tissue transplantation and gene therapy approaches in preclinical models.

Contribution to Lifelong VISION

My expertise is crucial in testing experimental therapies in representative and robust preclinical models in Platform A.

Patricia Dankers

Professor in Biomedical Materials & Chemistry Eindhoven University of Technology

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Patricia Dankers

About me

Patricia Dankers is a professor in Biomedical Materials & Chemistry. Dankers leads a research group that aims at pursuing grand challenges in biomedical science, and in particular in the field of regenerative medicine, using a materials approach. Targeting the cell-material interface using supramolecular chemistry is one of the main research directions.

Your contribution to Lifelong VISION

Our group contributes to Pillar 3 through development of different functional materials to steer retinal cells.