Designer matrices for intestinal stem cell and organoid culture

Gjorevski, Nikolce; Sachs, Norman; Manfrin, Andrea; Giger, Sonja; Bragina, Maiia E.; Ordóñez‐Morán, Paloma; Clevers, Hans; Lütolf, Matthias P.

doi:10.1038/nature20168

Cited by 1,053 publications

(1,047 citation statements)

References 44 publications

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“…These biomaterials have been developed to either allow for cell culture on their surfaces (Two-dimensional (2D) hydrogels), or to allow for encapsulation within the material (Three-dimensional (3D) hydrogels). 3D hydrogel models have been used to independently tune biophysical and biochemical cues to determine their impact on intestinal stem cell organoid growth, 1 cancer cell invasion, 9 and drug response. 10 Moreover, the dynamics of microenvironments have been captured in some 3D models by using photoinitiated polymerization to change the hydrogel modulus and ligand density 11 and by creating patterns within a hydrogel to control the spatial arrangement of biochemical cues within the matrix to direct cell phenotype.…”

Section: Introductionmentioning

confidence: 99%

Complementary, Semiautomated Methods for Creating Multidimensional PEG-Based Biomaterials

Brooks

Jansen

Gencoglu

et al. 2018

ACS Biomater. Sci. Eng.

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Tunable biomaterials that mimic selected features of the extracellular matrix (ECM), such as its stiffness, protein composition, and dimensionality, are increasingly popular for studying how cells sense and respond to ECM cues. In the field, there exists a significant trade-off for how complex and how well these biomaterials represent the in vivo microenvironment, versus how easy they are to make and how adaptable they are to automated fabrication techniques. To address this need to integrate more complex biomaterials design with high-throughput screening approaches, we present several methods to fabricate synthetic biomaterials in 96-well plates and demonstrate that they can be adapted to semiautomated liquid handling robotics. These platforms include 1) glass bottom plates with covalently attached ECM proteins, and 2) hydrogels with tunable stiffness and protein composition with either cells seeded on the surface, or 3) laden within the three-dimensional hydrogel matrix. This study includes proof-of-concept results demonstrating control over breast cancer cell line phenotypes via these ECM cues in a semi-automated fashion. We foresee the use of these methods as a mechanism to bridge the gap between high-throughput cell-matrix screening and engineered ECM-mimicking biomaterials.

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Section: Introductionmentioning

confidence: 99%

Complementary, Semiautomated Methods for Creating Multidimensional PEG-Based Biomaterials

Brooks

Jansen

Gencoglu

et al. 2018

ACS Biomater. Sci. Eng.

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“…A very recent study by Gjorevski et al describes the use of fully-defined, degradable PEG-based gels, enriched with fibronectin or laminin-111, for intestinal stem cell (ISC) and organoid culture. [1] Enzymatically degradable hydrogels did not support ISC expansion and non-degradable matrices were needed. However, for organoid development matrix softening through ester-based hydrolysis of hybrid PEG gels was required.…”

Section: Degradabilitymentioning

confidence: 99%

Mechanotransduction and Growth Factor Signalling to Engineer Cellular Microenvironments

Cipitria

Salmerón-Sánchez

2017

Adv Healthcare Materials

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Engineering cellular microenvironments involves biochemical factors, the extracellular matrix (ECM) and the interaction with neighbouring cells. This progress report provides a critical overview of key studies that incorporate growth factor (GF) signalling and mechanotransduction into the design of advanced microenvironments. Materials systems have been developed for surface‐bound presentation of GFs, either covalently tethered or sequestered through physico‐chemical affinity to the matrix, as an alternative to soluble GFs. Furthermore, some materials contain both GF and integrin binding regions and thereby enable synergistic signalling between the two. Mechanotransduction refers to the ability of the cells to sense physical properties of the ECM and to transduce them into biochemical signals. Various aspects of the physics of the ECM, i.e. stiffness, geometry and ligand spacing, as well as time‐dependent properties, such as matrix stiffening, degradability, viscoelasticity, surface mobility as well as spatial patterns and gradients of physical cues are discussed. To conclude, various examples illustrate the potential for cooperative signalling of growth factors and the physical properties of the microenvironment for potential applications in regenerative medicine, cancer research and drug testing.

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“…More recently, synthetic hydrogels have been developed for intestinal organoid cultures in order to define the both the physical and adhesive properties of the scaffold and without the need for Matrigel [18] (Fig. 1).…”

Section: Intestinal Organoidsmentioning

confidence: 99%

“…[5,[14][15][16][17][18][19][20][21][22] Intestinal organoids have been used to model epithelial barrier function, interactions with microbes, infectious diseases and cancer. [23][24][25][26][27][28][29][30][31][32] Intestinal organoids derived from human samples were first grown from isolated small intestinal or colonic crypts, which are localized at the base of the intestinal and colonic epithelium, respectively.…”

Section: Intestinal Organoidsmentioning

confidence: 99%

Take a deep breath and digest the material: organoids and biomaterials of the respiratory and digestive systems

et al. 2017

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Human organoid models recapitulate many aspects of the complex composition and function of native organs. One of the main challenges in developing these models is the growth and maintenance of three-dimensional tissue structures and proper cellular organization that enable function. Biomaterials play an important role by providing a defined and tunable three-dimensional environment that is required for complex cellular organization and organoid growth in vitro or in vivo. This review summarizes organoids of the respiratory and digestive system, and the use of biomaterials to improve upon these model systems.

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Designer matrices for intestinal stem cell and organoid culture

Cited by 1,053 publications

References 44 publications

Complementary, Semiautomated Methods for Creating Multidimensional PEG-Based Biomaterials

Complementary, Semiautomated Methods for Creating Multidimensional PEG-Based Biomaterials

Mechanotransduction and Growth Factor Signalling to Engineer Cellular Microenvironments

Take a deep breath and digest the material: organoids and biomaterials of the respiratory and digestive systems

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