SubsidieMeestersDissecting Macrophage Mechanobiology to Engineer Immuno-Regenerative Biomaterials
MACxercise aims to enhance implant integration by investigating how macrophages respond to mechanical cues in bioresorbable biomaterials, fostering advancements in tissue regeneration.
Projectdetails
Introduction
There is an increasing clinical demand for sophisticated medical implants and the scientific field of implant technology is exponentially growing. The main challenge is to harness the immune response to such an implant. In this research, we use the immune response to our advantage by using bioresorbable synthetic biomaterials that are gradually replaced by living tissue inside the body.
Role of Macrophages
One of the key immune cells are macrophages, which are the gatekeepers for successful implant integration. Strategies to harness the macrophage response focus on isolated biomaterial design features, such as biochemical or microstructural modifications.
Importance of Mechanobiology
One major neglected factor is how macrophages sense and respond to mechanical loads, such as cyclic stretch, or macrophage mechanobiology. Without an in-depth understanding of macrophage mechanobiology, rational engineering of biomaterials is not possible, leading to unpredictable outcomes and ineffective trial-and-error work.
Objectives of MACxercise
With MACxercise, I will leverage my unique multi-disciplinary expertise in bioengineering, biomaterial science, and macrophage biology to address these scientific challenges from a new angle in which macrophage mechanobiology is placed center stage.
Main Aim
The Main Aim of the MACxercise program is to systematically dissect how macrophages respond to dynamic mechanical cues and to establish how this affects biomaterial-driven tissue regeneration.
Transformative Strength
The transformative strength of MACxercise lies in the concerted spatial and temporal manipulation of the macrophage microenvironment, using sophisticated engineering tools to decouple the mechanical and physical cues to systematically pinpoint how synergistic or conflicting cues dictate key macrophage functions in the biomaterial microenvironment.
Vision
With MACxercise, my vision is to catalyze the establishment of an exciting new research field across the boundaries of biomaterial science, immunology, mechanobiology, and tissue engineering.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.499.950 |
| Totale projectbegroting | € 1.499.950 |
Tijdlijn
| Startdatum | 1-6-2022 |
| Einddatum | 31-5-2027 |
| Subsidiejaar | 2022 |
Partners & Locaties
Projectpartners
- TECHNISCHE UNIVERSITEIT EINDHOVENpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
ENGINEERING CELLULAR SELF‐ORGANISATION BY CONTROLLING THE IMMUNO-MECHANICAL INTERPLAYThis project aims to reduce scarring in bone regeneration by engineering synthetic immune-mechanical niches to enhance cell self-organization and matrix formation, improving healing outcomes. | ERC Advanced... | € 2.490.725 | 2023 | Details |
Engineering soft microdevices for the mechanical characterization and stimulation of microtissuesThis project aims to advance mechanobiology by developing soft robotic micro-devices to study and manipulate 3D tissue responses, enhancing understanding of cell behavior and potential cancer treatments. | ERC Advanced... | € 3.475.660 | 2025 | Details |
Monocyte-to-Macrophage Trajectories After Lung Injury: Spatio-temporal investigation, molecular regulation & functional implications for lung regeneration and immunityThis project aims to elucidate the diverse roles and regulatory mechanisms of inflammatory monocyte-derived macrophages in lung injury and repair, using advanced mouse models and human organoid systems. | ERC Consolid... | € 1.999.863 | 2025 | Details |
Intelligent Device and Computational Software to Control Mechanical Stress and Deformation for Biological TestingISBIOMECH aims to develop a novel intelligent system for controlling mechanical environments in biological testing, enhancing in-vitro therapies and drug discovery for various pathologies. | ERC Proof of... | € 150.000 | 2023 | Details |
Physical basis of Collective Mechano-Transduction: Bridging cell decision-making to multicellular self-organisationThis project investigates how mechanical forces in tissue microenvironments influence gene expression and multicellular behavior, aiming to bridge biophysics and biochemistry for improved disease therapies. | ERC Starting... | € 1.499.381 | 2022 | Details |
ENGINEERING CELLULAR SELF‐ORGANISATION BY CONTROLLING THE IMMUNO-MECHANICAL INTERPLAY
This project aims to reduce scarring in bone regeneration by engineering synthetic immune-mechanical niches to enhance cell self-organization and matrix formation, improving healing outcomes.
Engineering soft microdevices for the mechanical characterization and stimulation of microtissues
This project aims to advance mechanobiology by developing soft robotic micro-devices to study and manipulate 3D tissue responses, enhancing understanding of cell behavior and potential cancer treatments.
Monocyte-to-Macrophage Trajectories After Lung Injury: Spatio-temporal investigation, molecular regulation & functional implications for lung regeneration and immunity
This project aims to elucidate the diverse roles and regulatory mechanisms of inflammatory monocyte-derived macrophages in lung injury and repair, using advanced mouse models and human organoid systems.
Intelligent Device and Computational Software to Control Mechanical Stress and Deformation for Biological Testing
ISBIOMECH aims to develop a novel intelligent system for controlling mechanical environments in biological testing, enhancing in-vitro therapies and drug discovery for various pathologies.
Physical basis of Collective Mechano-Transduction: Bridging cell decision-making to multicellular self-organisation
This project investigates how mechanical forces in tissue microenvironments influence gene expression and multicellular behavior, aiming to bridge biophysics and biochemistry for improved disease therapies.
Vergelijkbare projecten uit andere regelingen
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Smart 4D biodegradable metallic shape-shifting implants for dynamic tissue restorationBIOMET4D aims to revolutionize reconstructive surgery with shape-morphing implants for dynamic tissue restoration, enhancing regeneration while reducing costs and invasiveness. | EIC Pathfinder | € 4.039.541 | 2022 | Details |
Bacteria Biofilm as bio-factory for tissue regenerationBIOACTION aims to transform biofilm-associated infections into a resource for tissue regeneration using functionalized bio-hydrogels and engineered liposomes, enhancing implant technology and health outcomes. | EIC Pathfinder | € 2.903.862 | 2023 | Details |
Smart 4D biodegradable metallic shape-shifting implants for dynamic tissue restoration
BIOMET4D aims to revolutionize reconstructive surgery with shape-morphing implants for dynamic tissue restoration, enhancing regeneration while reducing costs and invasiveness.
Bacteria Biofilm as bio-factory for tissue regeneration
BIOACTION aims to transform biofilm-associated infections into a resource for tissue regeneration using functionalized bio-hydrogels and engineered liposomes, enhancing implant technology and health outcomes.