Melt Electrowriting of Multi-layered Scaffolds for osteochondral defect repair (MEMS)

The MEMS project aims to optimize and functionalize 3D-printed MEW scaffolds for effective, off-the-shelf regeneration of osteochondral defects, enhancing tissue repair without exogenous cells.

Subsidie

€ 150.000

2023

Projectdetails

Introduction

An osteochondral (OC) defect is a focal area of joint damage that involves both the articular cartilage and the underlying subchondral bone. Such joint damage is strongly associated with the development of premature osteoarthritis, motivating the development of novel strategies to regenerate OC defects.

3D Printing in Regenerative Medicine

3D printing is enabling the manufacturing of geometrically complex biomaterial implants with user-defined compositions and architectures. These implants can potentially be used as single-stage, off-the-shelf scaffolds for treating complex injuries.

Despite significant progress in this field, 3D printed scaffolds capable of regenerating OC defects remain elusive. This can potentially be linked to the spatial resolution possible using traditional additive manufacturing techniques.

Melt Electrowriting (MEW) Technique

The melt electrowriting (MEW) technique has recently emerged as a novel additive manufacturing platform capable of producing polymeric scaffolds with fiber diameters in the submicron range in a highly controllable manner.

We have recently developed MEW scaffolds that support superior bone regeneration compared to scaffolds produced using traditional additive manufacturing techniques. Furthermore, we have generated preliminary data demonstrating that multi-layered scaffolds generated by MEW are capable of enhancing the repair of critically sized OC defects in a pre-clinical large animal model.

MEMS Project Objectives

The MEMS project aims to further enhance the regenerative capacity of these MEW OC scaffolds by:

Optimising their architecture.
Functionalizing their surface with extracellular matrix (ECM) components supportive of tissue-specific regeneration.

Expected Outcome

The output of MEMS will be an off-the-shelf implant capable of directing endogenous OC defect regeneration without the need for delivering exogenous cells to the defect site.

Financiële details & Tijdlijn

Financiële details

Subsidiebedrag	€ 150.000
Totale projectbegroting	€ 150.000

Tijdlijn

Startdatum	1-10-2023
Einddatum	31-3-2025
Subsidiejaar	2023

Partners & Locaties

Projectpartners

THE PROVOST, FELLOWS, FOUNDATION SCHOLARS & THE OTHER MEMBERS OF BOARD, OF THE COLLEGE OF THE HOLY & UNDIVIDED TRINITY OF QUEEN ELIZABETH NEAR DUBLINpenvoerder

Land(en)

Ireland

Vergelijkbare projecten binnen European Research Council

Project	Regeling	Bedrag	Jaar	Actie
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A 3D-printable biomimetic bone regeneration material PRIOBONE aims to validate a novel 3D-printable, bone-mimetic material for critical-size bone defects, offering a customizable, cost-effective solution to improve healing outcomes.	ERC Proof of...	€ 150.000	2024	Details
Additive Micromanufacturing: Multimetal Multiphase Functional Architectures AMMicro aims to develop robust 3D MEMS devices using localized electrodeposition and advanced reliability testing to enhance damage sensing and impact protection for diverse applications.	ERC Starting...	€ 1.498.356	2023	Details
Regenerative Stenting for Osteoporotic Vertebral Fracture Repair RESTORE aims to revolutionize osteoporotic vertebral fracture treatment by using 3D-printed biodegradable stents and thermoresponsive hydrogels for personalized bone regeneration and repair.	ERC Consolid...	€ 2.039.473	2024	Details

ERC Advanced...

Restoring the structural collagen network in the regeneration of cartilage

Re-COLL aims to develop durable implants for damaged joints by engineering anisotropic collagen networks through biofabrication and in vitro models, enhancing tissue regeneration and stability.

ERC Advanced Grant

€ 2.500.000

2024

Project	Regeling	Bedrag	Jaar	Actie
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.	EIC Pathfinder	€ 4.039.541	2022	Details
High-throughput ultrasound-based volumetric 3D printing for tissue engineering SONOCRAFT aims to revolutionize myocardial cell construct bioprinting by combining rapid volumetric printing with ultrasonic manipulation to create functional cardiac models for drug testing and disease research.	EIC Pathfinder	€ 2.999.625	2025	Details
Haalbaarheid R&D DME collageenpleisters en scaffolds HCM Medical onderzoekt de haalbaarheid van het ontwikkelen van kosteneffectieve collageenpleisters en scaffolds via DME-extractie voor regeneratieve geneeskunde.	Mkb-innovati...	€ 20.000	2020	Details
Piezo-driven theramesh: A revolutionary multifaceted actuator to repair the injured spinal cord Piezo4Spine aims to create a groundbreaking 3D bioprinted mesh therapy for spinal cord injury that enhances neural repair through targeted mechanotransduction and gene therapy.	EIC Pathfinder	€ 3.537.120	2023	Details
SyCap Mechano Avalanche Medical ontwikkelt een duurzaam kunststof implantaat voor kraakbeendefecten in de knie, gericht op middelbare leeftijd patiënten.	Mkb-innovati...	€ 20.000	2022	Details

Projectdetails

Introduction

3D Printing in Regenerative Medicine

Melt Electrowriting (MEW) Technique

MEMS Project Objectives

Expected Outcome

Financiële details & Tijdlijn

Financiële details

Tijdlijn

Partners & Locaties

Projectpartners

Land(en)

Vergelijkbare projecten binnen European Research Council

Restoring the structural collagen network in the regeneration of cartilage

High Throughput Modelling and Measurement of Human Epithelial Models using Electrospun Conducting Polymers For Unlocking Data-Driven Drug Discovery

A 3D-printable biomimetic bone regeneration material

Additive Micromanufacturing: Multimetal Multiphase Functional Architectures

Regenerative Stenting for Osteoporotic Vertebral Fracture Repair

Restoring the structural collagen network in the regeneration of cartilage

High Throughput Modelling and Measurement of Human Epithelial Models using Electrospun Conducting Polymers For Unlocking Data-Driven Drug Discovery

A 3D-printable biomimetic bone regeneration material

Additive Micromanufacturing: Multimetal Multiphase Functional Architectures

Regenerative Stenting for Osteoporotic Vertebral Fracture Repair

Vergelijkbare projecten uit andere regelingen

Smart 4D biodegradable metallic shape-shifting implants for dynamic tissue restoration

High-throughput ultrasound-based volumetric 3D printing for tissue engineering

Haalbaarheid R&D DME collageenpleisters en scaffolds

Piezo-driven theramesh: A revolutionary multifaceted actuator to repair the injured spinal cord

SyCap Mechano

Smart 4D biodegradable metallic shape-shifting implants for dynamic tissue restoration

High-throughput ultrasound-based volumetric 3D printing for tissue engineering

Haalbaarheid R&D DME collageenpleisters en scaffolds

Piezo-driven theramesh: A revolutionary multifaceted actuator to repair the injured spinal cord

SyCap Mechano

Projectdetails

Introduction

3D Printing in Regenerative Medicine

Melt Electrowriting (MEW) Technique

MEMS Project Objectives

Expected Outcome

Financiële details & Tijdlijn

Financiële details

Tijdlijn

Partners & Locaties

Projectpartners

Land(en)

Vergelijkbare projecten binnen European Research Council

Restoring the structural collagen network in the regeneration of cartilage

High Throughput Modelling and Measurement of Human Epithelial Models using Electrospun Conducting Polymers For Unlocking Data-Driven Drug Discovery

A 3D-printable biomimetic bone regeneration material

Additive Micromanufacturing: Multimetal Multiphase Functional Architectures

Regenerative Stenting for Osteoporotic Vertebral Fracture Repair

Restoring the structural collagen network in the regeneration of cartilage

High Throughput Modelling and Measurement of Human Epithelial Models using Electrospun Conducting Polymers For Unlocking Data-Driven Drug Discovery

A 3D-printable biomimetic bone regeneration material

Additive Micromanufacturing: Multimetal Multiphase Functional Architectures

Regenerative Stenting for Osteoporotic Vertebral Fracture Repair

Vergelijkbare projecten uit andere regelingen

Smart 4D biodegradable metallic shape-shifting implants for dynamic tissue restoration

High-throughput ultrasound-based volumetric 3D printing for tissue engineering

Haalbaarheid R&D DME collageenpleisters en scaffolds

Piezo-driven theramesh: A revolutionary multifaceted actuator to repair the injured spinal cord

SyCap Mechano

Smart 4D biodegradable metallic shape-shifting implants for dynamic tissue restoration

High-throughput ultrasound-based volumetric 3D printing for tissue engineering

Haalbaarheid R&D DME collageenpleisters en scaffolds

Piezo-driven theramesh: A revolutionary multifaceted actuator to repair the injured spinal cord

SyCap Mechano