The use of three-dimensional (3D) cell cultures has become increasingly popular in the contexts of drug discovery, disease modelling, and tissue engineering, as they aim to replicate in vivo-like conditions. To achieve this, new hydrogels are being developed to mimic the extracellular matrix. Testing the ability of these hydrogels is crucial, and the presented 3D-printed microfluidic perfusion system offers a novel solution for the parallel cultivation and evaluation of four separate 3D cell cultures. This system enables easy microscopic monitoring of the hydrogel-embedded cells and significantly reduces the required volumes of hydrogel and cell suspension. This cultivation device is comprised of two 3D-printed parts, which provide four cel...
Recently, 3-dimensional in vitro cell cultures have gained much attention in biomedical sciences bec...
The need for efficient and reproducible cell culture is necessary for the development of novel biol...
Engineering physiologically relevant in vitro models of human organs remains a fundamental challenge...
The use of three-dimensional (3D) cell cultures has become increasingly popular in the contexts of d...
Breakthroughs in health care over the coming decades may well consist of cell based therapeutics, po...
The application of hydrogels as a matrix for 3-dimensional cell cultures has become an indispensable...
This study presents a novel approach for threedimensional (3D) cell culture using a two-component sy...
Hydrogel-based artificial scaffolds play a vital role in shifting in vitro models from two-dimension...
The advent of 3D printing technologies promises to make microfluidic organ-on-chip technologies more...
This protocol describes a simple but robust microfluidic assay combining three-dimensional (3D) and ...
Mammalian cells cultured on 2D surfaces in microfluidic channels are increasingly used in drug devel...
Abstract New and more biologically relevant in vitro models are needed for use in drug development, ...
3D cell culture and microfluidics both represent powerful tools for replicating critical components ...
Cells cultured on 2-Dimensional (2D) and 3-Dimensional (3D) substrates generally display significant...
Most of in vivo tissue cells reside in 3D extracellular matrix (ECM) with fluid flow. To better stud...
Recently, 3-dimensional in vitro cell cultures have gained much attention in biomedical sciences bec...
The need for efficient and reproducible cell culture is necessary for the development of novel biol...
Engineering physiologically relevant in vitro models of human organs remains a fundamental challenge...
The use of three-dimensional (3D) cell cultures has become increasingly popular in the contexts of d...
Breakthroughs in health care over the coming decades may well consist of cell based therapeutics, po...
The application of hydrogels as a matrix for 3-dimensional cell cultures has become an indispensable...
This study presents a novel approach for threedimensional (3D) cell culture using a two-component sy...
Hydrogel-based artificial scaffolds play a vital role in shifting in vitro models from two-dimension...
The advent of 3D printing technologies promises to make microfluidic organ-on-chip technologies more...
This protocol describes a simple but robust microfluidic assay combining three-dimensional (3D) and ...
Mammalian cells cultured on 2D surfaces in microfluidic channels are increasingly used in drug devel...
Abstract New and more biologically relevant in vitro models are needed for use in drug development, ...
3D cell culture and microfluidics both represent powerful tools for replicating critical components ...
Cells cultured on 2-Dimensional (2D) and 3-Dimensional (3D) substrates generally display significant...
Most of in vivo tissue cells reside in 3D extracellular matrix (ECM) with fluid flow. To better stud...
Recently, 3-dimensional in vitro cell cultures have gained much attention in biomedical sciences bec...
The need for efficient and reproducible cell culture is necessary for the development of novel biol...
Engineering physiologically relevant in vitro models of human organs remains a fundamental challenge...