Challenges for Natural Hydrogels in Tissue Engineering

Jabbari, Esmaiel

doi:10.3390/gels5020030

Cited by 33 publications

(20 citation statements)

References 48 publications

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“…Despite the attractive developments in biomedical applications, due to high lot‐to‐lot variability, undefined matrix composition, and limited chemical modification, these natural hydrogels have been subjected to critical limitations in advanced or precise biomedical technologies for translational medicine, such as spatiotemporally controlled ex vivo microtissue models, biological functionalization incorporated by adhesive and degradable motifs, precisely controlling cell morphology, mechanical stiffness modulations, cell‐specific biomimicry or tissue‐specific components incorporated into hydrogel design, complex multiple cell types construct, [ 4b,48 ] since these biomedical technologies harbor the hierarchical stratified microarchitectures in their native state in vivo, which need be reconstructed by nanoscale methodologies. However, the natural hydrogels in themselves are unable to quantify their composition and characterize their cell binding pockets with cell surface receptors at the nanometer scale.…”

Section: Common Hydrogel Products and Biomedical Featuresmentioning

confidence: 99%

Designer Self‐Assembling Peptide Hydrogels to Engineer 3D Cell Microenvironments for Cell Constructs Formation and Precise Oncology Remodeling in Ovarian Cancer

Yang

Zhao

2020

Advanced Science

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mouse intestinal stem cells and primary colorectal cancer cells can be propagated in vitro long term, [1] there is an urgent need to develop more physiologically relevant, efficient, and robust precise oncology models that closely recapitulate the genetic and morphological heterogeneous composition and mimic the arrangement pattern of cancer cells in the original tumor. [2] To our knowledge in biomedical research, hydrogel is the best tool to reconstruct precise oncology models in vitro, especially tumor organoid, which not only recapitulates in vivo biology and microenvironmental factors, but also at large extent allows side-by-side comparison to evaluate the translational potential of 3D model systems to the patients. [2a,3] Generally, hydrogels are mainly composed of hydrophilic polymeric scaffolds that absorb large amounts of water, so the hydrogel matrix better mimics elastic and viscoelastic properties in ECM and microscale topographies of cell matrices, which controls proper cell morphology, directs viable cell behaviors, and drives in vivo fundamental cell-cell or cell-ECM interactions. [4] To recapitulate pathophysiological features of human tumors and imitate various aspects of human tumorigenesis in vivo, hydrogels can provide a realistic platform to establish a useful bridge between in vitro assays and in vivo cell microenvironments. In current biomedical applications, there are many kinds of hydrogels to be developed to mimic the biological properties of ECM, such Designer self-assembling peptides form the entangled nanofiber networks in hydrogels by ionic-complementary self-assembly. This type of hydrogel has realistic biological and physiochemical properties to serve as biomimetic extracellular matrix (ECM) for biomedical applications. The advantages and benefits are distinct from natural hydrogels and other synthetic or semisynthetic hydrogels. Designer peptides provide diverse alternatives of main building blocks to form various functional nanostructures. The entangled nanofiber networks permit essential compositional complexity and heterogeneity of engineering cell microenvironments in comparison with other hydrogels, which may reconstruct the tumor microenvironments (TMEs) in 3D cell cultures and tissue-specific modeling in vitro. Either ovarian cancer progression or recurrence and relapse are involved in the multifaceted TMEs in addition to mesothelial cells, fibroblasts, endothelial cells, pericytes, immune cells, adipocytes, and the ECM. Based on the progress in common hydrogel products, this work focuses on the diverse designer self-assembling peptide hydrogels for instructive cell constructs in tissue-specific modeling and the precise oncology remodeling for ovarian cancer, which are issued by several research aspects in a 3D context. The advantages and significance of designer peptide hydrogels are discussed, and some common approaches and coming challenges are also addressed in current complex tumor diseases.

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Section: Common Hydrogel Products and Biomedical Featuresmentioning

confidence: 99%

Designer Self‐Assembling Peptide Hydrogels to Engineer 3D Cell Microenvironments for Cell Constructs Formation and Precise Oncology Remodeling in Ovarian Cancer

Yang

Zhao

2020

Advanced Science

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“…Based on the types polymers extracted, the hydrogels can be classified into natural hydrogels and synthetic hydrogels. Although increasing evidence suggests that the synthetic hydrogels can act as tissue scaffolds with tunable mechanical strength, they lack important bioactive molecules, such as amino acids to support the adhesion, growth, and maturation of the encapsulated cells (Jabbari, ). In contrast, natural hydrogels contain the native tissue constituents of mammals, thus offering more appropriate conditions for intestinal organoid culture.…”

Section: Biomaterials For Intestinal Organoid Culturementioning

confidence: 99%

Biomaterials and biosensors in intestinal organoid culture, a progress review

Huang

Jiang

Ren

et al. 2020

J Biomedical Materials Res

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As an emerging technology, intestinal organoids are promising new tools for basic and translational research in gastroenterology. Currently, culture of intestinal organoids relies mostly on a type of tumor-derived scaffolds, namely Matrigel, which may pose tumorigenic risks to organoid implantation. Apart from the traditional detection methods, such as tissue slicing and fluorescence staining, the monitoring of intestinal organoids requires real-time biosensors that can adapt to their threedimensional dynamic growth patterns. In this review, we summarized the recent advances in developing definite hydrogel scaffolds for intestinal organoid culture and identified key parameters for scaffold design. In addition, classified by different substrate compositions like pH, electrolytes, and functional proteins, we concluded the existing live-imaging biosensors and elucidated their underlying mechanisms. We hope this review enhances the understanding of intestinal organoid culture and provides more practical approaches to investigate them. K E Y W O R D Sbiosensor, intestinal stem cell, organoid, regenerative medicine, scaffold design

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“…Both synthetic and natural materials have demonstrated their usefulness to reconstruct and replace the great majority of damaged tissues. [6,7,37] To do so, preformed materials should fulfill a series of requirements to be considered as optimal im- plants for promoting SC repair and neural tissue engineering. These include their lack of toxicity and immunogenicity, thus contributing to high biocompatibility.…”

Section: Hydrogel-based Materials In Sci and Neural Regenerationmentioning

confidence: 99%

“…The use of hydrogels provides a broad range of possibilities in biomedicine, ranging from cell and gene therapy, and drug delivery, to regenerative medicine and tissue engineering applications . The success of this technology derives from the ability of hydrogels to retain high levels of water, as much as over 99%, which favors the entrapment of biological entities and increases their biocompatibility …”

Section: Introductionmentioning

confidence: 99%

“…The rapid development and extensive research sustained by polymer science have facilitated the appropriate design and preparation of a large number of scaffolds for tissue engineering applications. Both synthetic and natural materials have demonstrated their usefulness to reconstruct and replace the great majority of damaged tissues . To do so, preformed materials should fulfill a series of requirements to be considered as optimal implants for promoting SC repair and neural tissue engineering.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Alginate Hydrogels as Scaffolds and Delivery Systems to Repair the Damaged Spinal Cord

Grijalvo

Nieto‐Díaz

Maza

et al. 2019

Biotechnology Journal

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Alginate (ALG) is a lineal hydrophilic polysaccharide present in brown algae cell walls, which turns into a gel state when hydrated. Gelation readily produces a series of three dimensional (3D) architectures like fibers, capillaries, and microspheres, used as biosensors and bio‐actuators in a plethora of biomedical applications like drug delivery and wound healing. Hydrogels have made a great impact on regenerative medicine and tissue engineering because they are able to mimic the mechanical properties of natural tissues due to their high water content. Recent advances in neurosciences have led to promising strategies for repairing and/or regenerating the damaged nervous system. Spinal cord injury (SCI) is particularly challenging, owing to its devastating medical, human, and social consequences. Although effective therapies to repair the damaged spinal cord (SC) are still lacking, multiple pharmacological, genetic, and cell‐based therapies are currently under study. In this framework, ALG hydrogels constitute a source of potential tools for the development of implants capable of promoting axonal growth and/or delivering cells or drugs at specific damaged sites, which may result in therapeutic strategies for SCI. In this mini‐review, the current state of the art of ALG applications in neural tissues for repairing the damaged spinal cord is discussed.

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Challenges for Natural Hydrogels in Tissue Engineering

Cited by 33 publications

References 48 publications

Designer Self‐Assembling Peptide Hydrogels to Engineer 3D Cell Microenvironments for Cell Constructs Formation and Precise Oncology Remodeling in Ovarian Cancer

Designer Self‐Assembling Peptide Hydrogels to Engineer 3D Cell Microenvironments for Cell Constructs Formation and Precise Oncology Remodeling in Ovarian Cancer

Biomaterials and biosensors in intestinal organoid culture, a progress review

Alginate Hydrogels as Scaffolds and Delivery Systems to Repair the Damaged Spinal Cord

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