Fully synthetic matrices for in vitro culture of primary human intestinal enteroids and endometrial organoids

Hernandez-Gordillo, Victor; Kassis, Timothy; Lampejo, Arinola O.; Choi, GiHun; Gamboa, Mario; Gnecco, Juan; Brown, Alan; Breault, David T.; Carrier, Rebecca L.; Griffith, Linda G.

doi:10.1016/j.biomaterials.2020.120125

Cited by 108 publications

(124 citation statements)

References 101 publications

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“…This study further charted the mechanical requirement for organoid growth and demonstrated that stiff ECM is essential for the initial expansion phase of intestinal stem cells, whereas ECM softening by proteolysis promotes subsequent organoid formation and differentiation. Another study found that the incorporation of the α2β1 integrin affinity motif found in type I collagen allows for enhanced recovery and expansion of human intestinal and endometrial organoids 147 . These are good examples of how fractionalizing the dependency of organoids on BMM and ECM properties can navigate the synthesis of minimal and defined hydrogels for organoid culture.…”

Section: Salmonella Typhimuriummentioning

confidence: 99%

Somatic cell-derived organoids as prototypes of human epithelial tissues and diseases

2020

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Section: Salmonella Typhimuriummentioning

confidence: 99%

Somatic cell-derived organoids as prototypes of human epithelial tissues and diseases

2020

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“…120 These models employing natural ECMs have shortcomings, in part because there are no "one-size-fits-all" ECMs for both epithelia and stroma (and potentially other cell types), and also because natural proteins are impure (Matrigel has myriad growth factors); are substantially variable from lot-to-lot; are relatively rapidly degraded by cells; and are subject to variation in structural and mechanical properties depending on how quickly or slowly the gels are polymerized. 115,121 Variation is further exacerbated as some investigators use atelocollagen, which yields very different outcomes than whole collagen. 122 These shortcomings have prompted a sustained effort in the biomaterials community to create synthetic alternatives to Matrigel and collagen.…”

Section: General Approaches To 3d Tissue Engineering Of Endometrium Amentioning

confidence: 99%

“…123,124 A popular approach exploits the relative inertness of poly(ethylene glycol) (PEG), which is commercially available in multi-arm star/branched configurations activated with cell-compatible reactive groups, to create modular cell-encapsulating hydrogels crosslinked with short matrix metalloprotease (MMP)-sensitive peptides and incorporating synthetic integrin-binding motifs. 121,[123][124][125][126] Other types of synthetic gel ECMs based entirely on synthetic proteins or semisynthetic gels based on modified hyaluronic acid are also widely used. 124,127 The local and bulk mechanical modulus, permeability, degradation properties, and biochemical recognition motifs-all of which have been correlated to cell responses 115,121,125 -can be tuned independently to match the needs of individual cells and tissues.…”

Section: General Approaches To 3d Tissue Engineering Of Endometrium Amentioning

confidence: 99%

“…121,[123][124][125][126] Other types of synthetic gel ECMs based entirely on synthetic proteins or semisynthetic gels based on modified hyaluronic acid are also widely used. 124,127 The local and bulk mechanical modulus, permeability, degradation properties, and biochemical recognition motifs-all of which have been correlated to cell responses 115,121,125 -can be tuned independently to match the needs of individual cells and tissues.…”

Section: General Approaches To 3d Tissue Engineering Of Endometrium Amentioning

confidence: 99%

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Physiomimetic Models of Adenomyosis

et al. 2020

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Adenomyosis remains an enigmatic disease in the clinical and research communities. The high prevalence, diversity of morphological and symptomatic presentations, array of potential etiological explanations, and variable response to existing interventions suggest that different subgroups of patients with distinguishable mechanistic drivers of disease may exist. These factors, combined with the weak links to genetic predisposition, make the entire spectrum of the human condition challenging to model in animals. Here, after an overview of current approaches, a vision for applying physiomimetic modeling to adenomyosis is presented. Physiomimetics combines a system's biology analysis of patient populations to generate hypotheses about mechanistic bases for stratification with in vitro patient avatars to test these hypotheses. A substantial foundation for three-dimensional (3D) tissue engineering of adenomyosis lesions exists in several disparate areas: epithelial organoid technology; synthetic biomaterials matrices for epithelial–stromal coculture; smooth muscle 3D tissue engineering; and microvascular tissue engineering. These approaches can potentially be combined with microfluidic platform technologies to model the lesion microenvironment and can potentially be coupled to other microorgan systems to examine systemic effects. In vitro patient-derived models are constructed to answer specific questions leading to target identification and validation in a manner that informs preclinical research and ultimately clinical trial design.

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“…With the relationship in biological tissues being E = 3G 68 , this would correspond to G = 967 Pa, indeed in the range observed to be optimal for culturing intestinal epithelial organoids. Interestingly, a subsequent study found that a PEG-based matrix functionalised with the cell adhesion domains from type I collagen (GFOGER) on its own was sufficient as a matrix in supporting the growth of primary human intestinal epithelial cells as spheroids 69 . This again points to the important role of biomechanical cues in controlling cell fate and is supported by the observation that organoid 'crypt' formation depends on local mechanical signals as the length and the number of crypts per organoid can be modulated by softening the matrix 70 .…”

Section: Modelling the Intestinal Epithelial Physiology In Vitromentioning

confidence: 99%

A bioengineering perspective on modelling the intestinal epithelial physiology in vitro

Antfolk

Jensen

2020

Nat Commun

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The small intestine is a specialised organ, essential for nutrient digestion and absorption. It is lined with a complex epithelial cell layer. Intestinal epithelial cells can be cultured in three-dimensional (3D) scaffolds as self-organising entities with distinct domains containing stem cells and differentiated cells. Recent developments in bioengineering provide new possibilities for directing the organisation of cells in vitro. In this Perspective, focusing on the small intestine, we discuss how studies at the interface between bioengineering and intestinal biology provide new insights into organ function. Specifically, we focus on engineered biomaterials, complex 3D structures resembling the intestinal architecture, and micro-physiological systems.

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Fully synthetic matrices for in vitro culture of primary human intestinal enteroids and endometrial organoids

Cited by 108 publications

References 101 publications

Somatic cell-derived organoids as prototypes of human epithelial tissues and diseases

Somatic cell-derived organoids as prototypes of human epithelial tissues and diseases

Physiomimetic Models of Adenomyosis

A bioengineering perspective on modelling the intestinal epithelial physiology in vitro

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