Your search keyword '"Rouwkema, Jeroen"' showing total 4 results

1. Crossing frontiers in biomaterials and regenerative medicine. 8th World Biomaterials Congress, 28 May - 1 June, Amsterdam, The Netherlands.

Author

Malda J, Rouwkema J, Leeuwenburgh SC, Dhert WJ, and Kirkpatrick CJ

Subjects

Animals, Biocompatible Materials, Biomedical Engineering methods, Humans, Societies, Scientific organization & administration, Biomedical Engineering instrumentation, Biomedical Engineering trends, Regenerative Medicine trends

Published

2008

2. Engineering Photocrosslinkable Bicomponent Hydrogel Constructs for Creating 3D Vascularized Bone

Author

Kazemzadeh‐Narbat, Mehdi, Rouwkema, Jeroen, Annabi, Nasim, Cheng, Hao, Ghaderi, Masoumeh, Cha, Byung‐Hyun, Aparnathi, Mansi, Khalilpour, Akbar, Byambaa, Batzaya, Jabbari, Esmaiel, Tamayol, Ali, and Khademhosseini, Ali

Subjects

Engineering, Biomedical Engineering, Dental/Oral and Craniofacial Disease, Transplantation, Stem Cell Research - Nonembryonic - Human, Regenerative Medicine, Stem Cell Research, Bioengineering, Musculoskeletal, Animals, Bone Regeneration, Humans, Hydrogels, Nanoparticles, Osteogenesis, Tissue Engineering, bone tissue engineering, hydrogels, micropatterning, vascularization, Medicinal and Biomolecular Chemistry, Medical Biotechnology, Medical biotechnology, Biomedical engineering

Abstract

Engineering bone tissue requires the generation of a highly organized vasculature. Cellular behavior is affected by the respective niche. Directing cellular behavior and differentiation for creating mineralized regions surrounded by vasculature can be achieved by controlling the pattern of osteogenic and angiogenic niches. This manuscript reports on engineering vascularized bone tissues by incorporating osteogenic and angiogenic cell-laden niches in a photocrosslinkable hydrogel construct. Two-step photolithography process is used to control the stiffness of the hydrogel and distribution of cells in the patterned hydrogel. In addittion, osteoinductive nanoparticles are utilized to induce osteogenesis. The size of microfabricated constructs has a pronounced effect on cellular organization and function. It is shown that the simultaneous presence of both osteogenic and angiogenic niches in one construct results in formation of mineralized regions surrounded by organized vasculature. In addition, the presence of angiogenic niche improves bone formation. This approach can be used for engineered constructs that can be used for treatment of bone defects.

Published

2017

3. Sonic Hedgehog-activated engineered blood vessels enhance bone tissue formation.

Author

Rivron, Nicolas C., Raiss, Christian C., Jun Liu, Nandakumar, Anandkumar, Sticht, Carsten, Gretz, Norbert, Truckenmüller, Roman, Rouwkema, Jeroen, and van Blitterswijk, Clemens A.

Subjects

HEDGEHOG signaling proteins, BLOOD vessels, CARTILAGE, ENDOCHONDRAL ossification, PERFUSION

Abstract

Large bone defects naturally regenerate via a highly vascularized tissue which progressively remodels into cartilage and bone. Current approaches in bone tissue engineering are restricted by delayed vascularization and fail to recapitulate this stepwise differentiation toward bone tissue. Here, we use the morphogen Sonic Hedgehog (Shh) to induce the in vitro organization of an endothelial capillary network in an artificial tissue. We show that endogenous. Hedgehog activity regulates angiogenic genes and the formation of vascular lumens. Exogenous Shh further induces the in vitro development of the vasculature (vascular lumen formation, size, distribution). Upon implantation, the in vitro development of the vasculature improves the in vivo perfusion of the artificial tissue and is necessary to contribute to, and enhance, the formation of de novo mature bone tissue. Similar to the regenerating callus, the artificial tissue undergoes intramembranous and endochondral ossification and forms a trabecular-like bone organ including bone-marrow-like cavities. These findings open the door for new strategies to treat large bone defects by closely mimicking natural endochondral bone repair. [ABSTRACT FROM AUTHOR]

Published

2012

4. Engineering vascular development for tissue regeneration

Author

Nicolas Clemens Rivron, van Blitterswijk, Clemens, Rouwkema, Jeroen, and Faculty of Science and Technology

Subjects

medicine.anatomical_structure, Tissue engineering, Bone cell, Intramembranous ossification, medicine, Bone marrow, METIS-274369, Biology, Bone regeneration, Bone tissue, Endochondral ossification, Regenerative medicine, Cell biology

Abstract

Tissue engineering and regenerative medicine aim at restoring a damaged tissue by recreating in vitro or promoting its regeneratin in vovo. The vasculature is central to these therapies for the irrigation of the defective tissue (oxygen, nutrients or circulating regenerative cells) and as an inductive, trophic embedded organ. This thesis describes the in vitro formation of biological vascular networks for tissue engineering and regenerative medicine applications. In a first part, we show the in vitro formation of a vascularized tissue, using human mesenchymal stem cells and human umbilical vein endothelial cells for bone regeneration. Exogenous Sonic Hedgehog induced in vitro vascular development which was essential for the vasculature to robustly contribute to new bone tissue formation in vivo. The implant recapitulated a combination of intramembranous and endochondral ossification and matured into a bone organ including a large amount of trabecular bone, blood vessels and bone marrow cavities with apparent hematopoiesis. This approach, based on the regenerative paradigm of endochondral bone repair, opens new opportunities for the treatment of large bone defects. In a second part, we developed a microfabrication technique to form arrays of scaffold-free, three-dimensional, geometric tussies by sequential assembly. Using this method, we investigated a novel mechanism of vascular pattern formation in microfabricated tissue undergoing autonomous contraction and structural remodeling. Endogenous tissue contractility produced local tissue deformations and compactions and spatially regulated the VEGF production (gradient formation), the VEGFR2 expression and the formation of stereotyped patterns of blood capillaries. This experiment demonstrate the possibility to recapitulate and investigate tissue pattern formation mechanisms in microfabricated tissues. We propose that endogenous tissue contractility is a tissue-scale morphogenetic regulator of the angiogenic microenvironment and angiogenesis, a finding with wide implications in regenerative medicine and cancer biology. This thesis demonstrate possibilities to engineer vascularized tissue for (1) clinical applications (endochondral bone repair) and (2) as models to investigate mechanisms of vascular pattern formation.

Published

2010