Salwa Alshehri scite author profile

We report about rationally designed ultrashort peptide bioinks, overcoming severe limitations in current bioprinting procedures. Bioprinting is increasingly relevant in tissue engineering, regenerative and personalized medicine due to its ability to fabricate complex tissue scaffolds through an automated deposition process. Printing stable large-scale constructs with high shape fidelity and enabling long-term cell survival are major challenges that most existing bioinks are unable to solve. Additionally, they require chemical or UV-cross-linking for the structure-solidifying process which compromises the encapsulated cells, resulting in restricted structure complexity and low cell viability. Using ultrashort peptide bioinks as ideal bodylike but synthetic material, we demonstrate an instant solidifying cellembedding printing process via a sophisticated extrusion procedure under true physiological conditions and at cost-effective low bioink concentrations. Our printed large-scale cell constructs and the chondrogenic differentiation of printed mesenchymal stem cells point to the strong potential of the peptide bioinks for automated complex tissue fabrication.

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Self-assembling tetrameric peptides allow in situ 3D bioprinting under physiological conditions

Rauf

Susapto

Kahin

et al. 2021

J. Mater. Chem. B

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Scaffolds from Self-Assembling Tetrapeptides Support 3D Spreading, Osteogenic Differentiation, and Angiogenesis of Mesenchymal Stem Cells

2021

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The apparent rise of bone disorders demands advanced treatment protocols involving tissue engineering. Here, we describe self-assembling tetrapeptide scaffolds for the growth and osteogenic differentiation of human mesenchymal stem cells (hMSCs). The rationally designed peptides are synthetic amphiphilic self-assembling peptides composed of four amino acids that are nontoxic. These tetrapeptides can quickly solidify to nanofibrous hydrogels that resemble the extracellular matrix and provide a three-dimensional (3D) environment for cells with suitable mechanical properties. Furthermore, we can easily tune the stiffness of these peptide hydrogels by just increasing the peptide concentration, thus providing a wide range of peptide hydrogels with different stiffnesses for 3D cell culture applications. Since successful bone regeneration requires both osteogenesis and vascularization, our scaffold was found to be able to promote angiogenesis of human umbilical vein endothelial cells (HUVECs) in vitro . The results presented suggest that ultrashort peptide hydrogels are promising candidates for applications in bone tissue engineering.

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Air-loaded Gas Vesicle Nanoparticles Promote Cell Growth in Three-dimensional Bioprinted Tissue Constructs

Alshehri¹,

Karan²,

Ghalayini³

et al. 2022

IJB

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Three-dimensional (3D) bioprinting has emerged as a promising method for the engineering of tissues and organs. Still, it faces challenges in its widespread use due to issues with the development of bioink materials and the nutrient diffusion barrier inherent to these scaffold materials. Herein, we introduce a method to promote oxygen diffusion throughout the printed constructs using genetically encoded gas vesicles derived from haloarchaea. These hollow nanostructures are composed of a protein shell that allows gases to permeate freely while excluding the water flow. After printing cells with gas vesicles of various concentrations, the cells were observed to have increased activity and proliferation. These results suggest that air-filled gas vesicles can help overcome the diffusion barrier throughout the 3D bioprinted constructs by increasing oxygen availability to cells within the center of the construct. The biodegradable nature of the gas vesicle proteins combined with our promising results encourage their potential use as oxygen-promoting materials in biological samples.

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3D bioprinting of ultrashort self-assembling peptides to engineer scaffolds with different matrix stiffness for chondrogenesis

Alhattab¹,

Khan²,

Alshehri³

et al. 2024

IJB

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Articular cartilage is a non-vascularized and poorly cellularized tissue with a low self-repair capacity. Therefore, damage to this tissue due to trauma or degenerative joint diseases such as osteoarthritis needs a high-end medical intervention. However, such interventions are costly, have limited healing capacity, and could impair patients’ quality of life. In this regard, tissue engineering and three-dimensional (3D) bioprinting hold great potential. However, identifying suitable bioinks that are biocompatible, with the desired mechanical stiffness, and can be used under physiological conditions is still a challenge. In this study, we developed two tetrameric self-assembling ultrashort peptide bioinks that are chemically well-defined and can spontaneously form nanofibrous hydrogels under physiological conditions. The printability of the two ultrashort peptides was demonstrated; different shape constructs were printed with high shape fidelity and stability. Furthermore, the developed ultrashort peptide bioinks gave rise to constructs with different mechanical properties that could be used to guide stem cell differentiation toward specific lineages. Both ultrashort peptide bioinks demonstrated high biocompatibility and supported the chondrogenic differentiation of human mesenchymal stem cells. Additionally, the gene expression analysis of differentiated stem cells with the ultrashort peptide bioinks revealed articular cartilage extracellular matrix formation preference. Based on the different mechanical stiffness of the two ultrashort peptide bioinks, they can be used to fabricate cartilage tissue with different cartilaginous zones, including the articular and calcified cartilage zones, which are essential for engineered tissue integration.

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Salwa Alshehri

Ultrashort Peptide Bioinks Support Automated Printing of Large-Scale Constructs Assuring Long-Term Survival of Printed Tissue Constructs

Self-assembling tetrameric peptides allow in situ 3D bioprinting under physiological conditions

Scaffolds from Self-Assembling Tetrapeptides Support 3D Spreading, Osteogenic Differentiation, and Angiogenesis of Mesenchymal Stem Cells

Air-loaded Gas Vesicle Nanoparticles Promote Cell Growth in Three-dimensional Bioprinted Tissue Constructs

3D bioprinting of ultrashort self-assembling peptides to engineer scaffolds with different matrix stiffness for chondrogenesis

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