Your search keyword '"Kamperman, Tom"' showing total 3 results

1. Single Cell Microgel Based Modular Bioinks for Uncoupled Cellular Micro- and Macroenvironments.

Author

Kamperman T, Henke S, van den Berg A, Shin SR, Tamayol A, Khademhosseini A, Karperien M, and Leijten J

Subjects

Animals, Cattle, Chondrocytes cytology, Humans, Mesenchymal Stem Cells cytology, Chondrocytes metabolism, Mesenchymal Stem Cells metabolism, Stem Cell Niche, Tissue Engineering

Abstract

Modular bioinks based on single cell microgels within distinct injectable prepolymers enable uncoupling of biomaterials' micro- and macroenvironments. These inks allow biofabrication of 3D constructs that recapitulate the multiscale modular design of native tissues with a single cell resolution. This approach represents a major step forward in endowing engineered constructs with the multifunctionality that underlies the behavior of native tissues., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

2. Engineering 3D parallelized microfluidic droplet generators with equal flow profiles by computational fluid dynamics and stereolithographic printing.

Author

Kamperman, Tom, Teixeira, Liliana Moreira, Salehi, Seyedeh Sarah, Kerckhofs, Greet, Guyot, Yann, Geven, Mike, Geris, Liesbet, Grijpma, Dirk, Blanquer, Sebastien, and Leijten, Jeroen

Subjects

*COMPUTATIONAL fluid dynamics, *MICROFLUIDICS, *DROPLETS, *MESENCHYMAL stem cells, *MICROFLUIDIC devices

Abstract

Microfluidic droplet generators excel in generating monodisperse micrometer-sized droplets and particles. However, the low throughput of conventional droplet generators hinders their clinical and industrial translation. Current approaches to parallelize microdevices are challenged by the two-dimensional nature of the standard fabrication methods. Here, we report the facile production of three-dimensionally (3D) parallelized microfluidic droplet generators consisting of stacked and radially multiplexed channel designs. Computational fluid dynamics simulations form the design basis for a microflow distributor that ensures similar flow rates through all droplet generators. Stereolithography is the selected technique to fabricate microdevices, which enables the manufacturing of hollow channels with dimensions as small as 50 μm. The microdevices could be operated up to 4 bars without structural damage, including deformation of channels, or leakage of the on-chip printed Luer-Lok type connectors. The printed microdevices readily enable the production of water-in-oil emulsions, as well as polymer containing droplets that act as templates for both solid and core–shell hydrogel microparticles. The cytocompatibility of the 3D printed device is demonstrated by encapsulating mesenchymal stem cells in hydrogel microcapsules, which results in the controllable formation of stem cell spheroids that remain viable and metabolically active for at least 21 days. Thus, the unique features of stereolithography fabricated microfluidic devices allow for the parallelization of droplet generators in a simple yet effective manner by enabling the realization of (complex) 3D designs. [ABSTRACT FROM AUTHOR]

Published

2020

3. 3D Printed Cartilage‐Like Tissue Constructs with Spatially Controlled Mechanical Properties.

Author

Melo, Bruna A. G., Jodat, Yasamin A., Mehrotra, Shreya, Calabrese, Michelle A., Kamperman, Tom, Mandal, Biman B., Santana, Maria H. A., Alsberg, Eben, Leijten, Jeroen, and Shin, Su Ryon

Subjects

TISSUE engineering, BIOMATERIALS, POLYMER networks, TISSUE mechanics, HUMAN stem cells, MESENCHYMAL stem cells, TISSUES, HYDROGELS

Abstract

Developing biomimetic cartilaginous tissues that support locomotion while maintaining chondrogenic behavior is a major challenge in the tissue engineering field. Specifically, while locomotive forces demand tissues with strong mechanical properties, chondrogenesis requires a soft microenvironment. To address this challenge, 3D cartilage‐like tissue is fabricated using two biomaterials with different mechanical properties: a hard biomaterial to reflect the macromechanical properties of native cartilage, and a soft biomaterial to create a chondrogenic microenvironment. To this end, a bath composed of an interpenetrating polymer network (IPN) of polyethylene glycol (PEG) and alginate hydrogel (MPa order compressive modulus) is developed as an extracellular matrix (ECM) with self‐healing properties. Within this bath supplemented with thrombin, human mesenchymal stem cell (hMSC) spheroids embedded in fibrinogen are 3D bioprinted, creating a soft microenvironment composed of fibrin (kPa order compressive modulus) that simulate cartilage's pericellular matrix and allow a fast diffusion of nutrients. The bioprinted hMSC spheroids present high viability and chondrogenic‐like behavior without adversely affecting the macromechanical properties of the tissue. Therefore, the ability to locally bioprint a soft and cell stimulating biomaterial inside of a mechanically robust hydrogel is demonstrated, thereby uncoupling the micro‐ and macromechanical properties of the 3D printed tissues such as cartilage. [ABSTRACT FROM AUTHOR]

Published

2019