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

Susapto, Hepi Hari; Alhattab, Dana; Abdelrahman, Sherin; Khan, Zainab; Alshehri, Salwa; Kahin, Kowther; Ge, Rui; Moretti, Manola; Emwas, Abdul‐Hamid; Hauser, Charlotte

doi:10.1021/acs.nanolett.0c04426

Cited by 48 publications

(101 citation statements)

References 52 publications

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“…However, in the translation of synthetic peptide materials to bioinks, these key predictors are often under-reported and seemingly inconsistent. In reported studies of SAP bioinks, measures of printability such as viscosity [ 80 , 81 , 82 , 104 ], loss tangent [ 80 , 81 , 102 ], shear-thinning [ 81 , 82 , 103 ], achievable height [ 81 , 82 , 99 , 103 ] and filament assessments [ 81 , 82 , 103 ], were briefly discussed. This demonstrates the adoption of printability measures into the SAP bioink field; however, the lack of standard printability outcomes and the inconsistency in relationships of printability and predictors such as viscosity [ 81 , 82 ] limit the understanding of key material properties for future development.…”

Section: Adapting Peptide Materials As Bioinksmentioning

confidence: 99%

“…This has required the development of novel fabrication setups to enhance gelation. Bioprinting techniques amenable to SAP bioinks include droplet printing [ 98 , 99 , 100 , 101 ], or the generation of droplets which are then extruded [ 100 , 101 ], extrusion printing [ 80 , 81 , 102 , 103 , 104 ], and the customisation of extrusion printing setups, such as coaxial nozzles to mix salt solutions [ 80 , 81 ], printing onto salt-covered substrates [ 82 ], or removing excess fluid with a vacuum print-bed [ 105 ]. This demonstrates that the unique properties of SAP materials can be exploited for bioprinting.…”

Section: Adapting Peptide Materials As Bioinksmentioning

confidence: 99%

“…Progress into biomaterial molecular modelling and design principles may improve the clinical translation of materials by predicting outcomes without significant labour-intensive bench time. Molecular modelling [ 80 , 81 , 82 , 83 , 84 ], design principles [ 85 , 86 , 87 , 88 , 89 , 90 , 91 ] and predictive gelation models [ 90 ] of synthetic peptide materials are being increasingly reported, indicating a future ramp-up of high-throughput peptide biomaterial discovery. Synthetic self-assembling peptide (SAP) hydrogels are peptide sequences that self-assemble via supramolecular interactions to spontaneously immobilise fluid, creating a highly hydrated scaffold [ 92 ].…”

Section: Introductionmentioning

confidence: 99%

“…Synthetic peptide materials give rise to complex biomimetic structures with bioactivity, resulting in controlled cell-scaffold interactions [ 96 , 97 ]. Furthermore, recent reports have demonstrated the translation of synthetic SAP biomaterials into bioinks [ 80 , 81 , 82 , 98 , 99 , 100 , 101 , 102 , 103 , 104 , 105 ]. This demonstrates the potential of synthetic SAP design for biofabrication of organs and tissues, and ultimately clinical translation ( Figure 1 ).…”

Section: Introductionmentioning

confidence: 99%

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Enhancing Peptide Biomaterials for Biofabrication

et al. 2021

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Biofabrication using well-matched cell/materials systems provides unprecedented opportunities for dealing with human health issues where disease or injury overtake the body’s native regenerative abilities. Such opportunities can be enhanced through the development of biomaterials with cues that appropriately influence embedded cells into forming functional tissues and organs. In this context, biomaterials’ reliance on rigid biofabrication techniques needs to support the incorporation of a hierarchical mimicry of local and bulk biological cues that mimic the key functional components of native extracellular matrix. Advances in synthetic self-assembling peptide biomaterials promise to produce reproducible mimics of tissue-specific structures and may go some way in overcoming batch inconsistency issues of naturally sourced materials. Recent work in this area has demonstrated biofabrication with self-assembling peptide biomaterials with unique biofabrication technologies to support structural fidelity upon 3D patterning. The use of synthetic self-assembling peptide biomaterials is a growing field that has demonstrated applicability in dermal, intestinal, muscle, cancer and stem cell tissue engineering.

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Section: Adapting Peptide Materials As Bioinksmentioning

confidence: 99%

Section: Adapting Peptide Materials As Bioinksmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Enhancing Peptide Biomaterials for Biofabrication

et al. 2021

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“…Bioinks based on ultrashort peptides composed of 3-7 natural amino acids boast great potential due to their natural but synthetic properties and their salt-enhanced instantaneous gelation [6][7][8][9][10] . Unlike polymers or gelatin and alginate-based bioinks, these peptide bioinks eliminate harmful processes of UV light and chemical exposures for post-printed crosslinking of the bioinks.…”

Section: Introductionmentioning

confidence: 99%

Time-dependent pulsing of microfluidic pumps to enhance 3D bioprinting of peptide bioinks

Khan

Kahin

Hauser

2021

Microfluidics, BioMEMS, and Medical Microsystems XIX

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Using bioinks for 3D bioprinting of cellular constructs remains a challenge due to factors including viscosity, fluid dynamics and shear stress. The encapsulation of cells within the bioinks directly affects the quality of 3D bioprinting and microfluidic pumping is a commonly used supporting approach. The accuracy of microfluidic pumps can be further improved by introducing various mixing techniques. However, many of these techniques introduce complex geometries or external fields. In this study, we used a simple control technique of time-dependent pulsing for instant gelation of the peptide bioinks and observed its effect during the bioprinting process. Various time-dependent periodic signals are imposed on to a stable flow cycle and the effects are analyzed. The microfluidic pumps are programmed with different flow patterns represented by low frequency sinusoidal pulses, ramp inputs, and duty cycle pulses. Different combinations of these pulses are tested to achieve an optimal pulse for improved quality of printed constructs. Time-varied pulsing of microfluidic pumps, particularly as square waveforms, is found to provide better continuous flow and avoid material buildup within the extruder unit when compared to pumping at a constant flow rate with manual tuning. Clogging is avoided since the gelation rate is periodically reduced which avoids gel clumps in the printed constructs. This study substantially improves the use of suitable peptide bioinks, standardizes the 3D bioprinting process, and reduces clogging and clumping during printing. Our findings allow for printing of more accurate and complex constructs for applications in tissue engineering, such as skin grafting, and other regenerative medical applications.

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3D Bioprinting of Miniaturized Tissues Embedded in Self‐Assembled Nanoparticle‐Based Fibrillar Platforms

Bakht

Gomez‐Florit

Lamers

et al. 2021

Adv Funct Materials

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The creation of microphysiological systems like tissue and organ-on-chip for in vitro modeling of human physiology and diseases is gathering increasing interest. However, the platforms used to build these systems have limitations concerning implementation, automation, and cost-effectiveness. Moreover, their typical plastic-based housing materials are poor recreations of native tissue extracellular matrix (ECM) and barriers. Here, the controlled selfassembly of plant-derived cellulose nanocrystals (CNC) is combined with the concept of 3D bioprinting in suspension baths for the direct biofabrication of microphysiological systems embedded within an ECM mimetic fibrillar support material. The developed support CNC fluid gel allows exceptionally highresolution bioprinting of 3D constructs with arbitrary geometries and low restrictions of bioink choice. The further induction of CNC self-assembly with biocompatible calcium ions results in a transparent biomimetic nanoscaled fibrillar matrix that allows hosting different compartmentalized cell types and perfusable channels, has tailored permeability for biomacromolecules diffusion and cellular crosstalk, and holds structural stability to support long-term in vitro cell maturation. In summary, this xeno-free nanoscale CNC fibrillar matrix allows the biofabrication of hierarchical living constructs, opening new opportunities not only for developing physiologically relevant 3D in vitro models but also for a wide range of applications in regenerative medicine.

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

Cited by 48 publications

References 52 publications

Enhancing Peptide Biomaterials for Biofabrication

Enhancing Peptide Biomaterials for Biofabrication

Time-dependent pulsing of microfluidic pumps to enhance 3D bioprinting of peptide bioinks

3D Bioprinting of Miniaturized Tissues Embedded in Self‐Assembled Nanoparticle‐Based Fibrillar Platforms

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