Enhancing Peptide Biomaterials for Biofabrication

Firipis, Kate; Nisbet, David R.; Franks, Stephanie; Kapsa, Robert M. I.; Pirogova, Elena; Williams, Richard J.; Quigley, Anita

doi:10.3390/polym13162590

Cited by 13 publications

(7 citation statements)

References 199 publications

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“…[ 10 ] Designer self‐assembling peptide (dSAP) nanomaterials intend to produce biomimics of tissue‐specific nanostructures and support the inherent incorporation of local and bulk biological cues via hierarchical mimicry. [ 11 ] This fabrication technology at the atomic scale or molecular level mainly focuses on designing various peptide nanofiber biomaterial devices, [ 12 ] which is becoming an important trend in biomedical nanomaterial strategy and aims to resolve current limitations of hemostatic biomaterial research in surgical use, especially in surgical procedures on tissues that are difficult to access, impractical to mechanical and thermal treatments, or too delicate to conduct suturing. From a biochemical perspective, these dSAP building blocks are remarkably innovative nanomaterials with notable biocompatibility and defined tissue‐sealing efficiency in NCTH and IMB scenarios.…”

Section: Introductionmentioning

confidence: 99%

Short Peptide Nanofiber Biomaterials Ameliorate Local Hemostatic Capacity of Surgical Materials and Intraoperative Hemostatic Applications in Clinics

et al. 2023

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Short designer self‐assembling peptide (dSAP) biomaterials are a new addition to the hemostat group. It may provide a diverse and robust toolbox for surgeons to integrate wound microenvironment with much safer and stronger hemostatic capacity than conventional materials and hemostatic agents. Especially in noncompressible torso hemorrhage (NCTH), diffuse mucosal surface bleeding, and internal medical bleeding (IMB), with respect to the optimal hemostatic formulation, dSAP biomaterials are the ingenious nanofiber alternatives to make bioactive neural scaffold, nasal packing, large mucosal surface coverage in gastrointestinal surgery (esophagus, gastric lesion, duodenum, and lower digestive tract), epicardiac cell‐delivery carrier, transparent matrix barrier, and so on. Herein, in multiple surgical specialties, dSAP‐biomaterial‐based nano‐hemostats achieve safe, effective, and immediate hemostasis, facile wound healing, and potentially reduce the risks in delayed bleeding, rebleeding, post‐operative bleeding, or related complications. The biosafety in vivo, bleeding indications, tissue‐sealing quality, surgical feasibility, and local usability are addressed comprehensively and sequentially and pursued to develop useful surgical techniques with better hemostatic performance. Here, the state of the art and all‐round advancements of nano‐hemostatic approaches in surgery are provided. Relevant critical insights will inspire exciting investigations on peptide nanotechnology, next‐generation biomaterials, and better promising prospects in clinics.

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Section: Introductionmentioning

confidence: 99%

Short Peptide Nanofiber Biomaterials Ameliorate Local Hemostatic Capacity of Surgical Materials and Intraoperative Hemostatic Applications in Clinics

et al. 2023

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“…Such supramolecular hydrogels can be exploited to create biomaterials with various applications, including as drug delivery vehicles, tissue engineering scaffolds, or as precursors for creating nanostructured surfaces (Das and Gavel, 2020;Cardoso et al, 2021;Shi et al, 2021). Specifically, the use of a fluorenylmethyloxycarbonyl (Fmoc) group located at the N-terminal of the sequence was previously reported to drive peptide supramolecular assembly into biocompatible hydrogels (Fleming et al, 2013;Tao et al, 2016;Firipis et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Rational design of potent ultrashort antimicrobial peptides with programmable assembly into nanostructured hydrogels

et al. 2023

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Microbial resistance to common antibiotics is threatening to cause the next pandemic crisis. In this context, antimicrobial peptides (AMPs) are receiving increased attention as an alternative approach to the traditional small molecule antibiotics. Here, we report the bi-functional rational design of Fmoc-peptides as both antimicrobial and hydrogelator substances. The tetrapeptide Fmoc-WWRR-NH2—termed Priscilicidin—was rationally designed for antimicrobial activity and molecular self-assembly into nanostructured hydrogels. Molecular dynamics simulations predicted Priscilicidin to assemble in water into small oligomers and nanofibrils, through a balance of aromatic stacking, amphiphilicity and electrostatic repulsion. Antimicrobial activity prediction databases supported a strong antimicrobial motif via sequence analogy. Experimentally, this ultrashort sequence showed a remarkable hydrogel forming capacity, combined to a potent antibacterial and antifungal activity, including against multidrug resistant strains. Using a set of biophysical and microbiology techniques, the peptide was shown to self-assemble into viscoelastic hydrogels, as a result of assembly into nanostructured hexagonal mesophases. To further test the molecular design approach, the Priscilicidin sequence was modified to include a proline turn—Fmoc-WPWRR-NH2, termed P-Priscilicidin–expected to disrupt the supramolecular assembly into nanofibrils, while predicted to retain antimicrobial activity. Experiments showed P-Priscilicidin self-assembly to be effectively hindered by the presence of a proline turn, resulting in liquid samples of low viscosity. However, assembly into small oligomers and nanofibril precursors were evidenced. Our results augur well for fast, adaptable, and cost-efficient antimicrobial peptide design with programmable physicochemical properties.

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“…14 However, these systems alone remain far from recreating the diverse multiscale signaling observed in the native extracellular matrix (ECM). 15 Multicomponent self-assembly faciliates controlled integration of multiple types of building-blocks leading to materials with properties that not only combine those of the individual components but also emergent ones. 16 Through this approach, O'Reilly and co-workers developed a temperature-responsive bioconjugate system of superfolder green fluorescent protein (sfGFP) and poly[(oligo ethylene glycol) methyl ether methacrylate] (PEGMA).…”

Section: ■ Introductionmentioning

confidence: 99%

“…The versatility of these molecules also enables structural modifications by incorporating matrix metalloproteinase cleavage sites in order to reveal a hidden bioactive region after controlled degradation, integrating host–guest moieties to tailor interfiber interactions, − or enabling hierarchical assembly into aligned nanofibers . However, these systems alone remain far from recreating the diverse multiscale signaling observed in the native extracellular matrix (ECM) …”

Section: Introductionmentioning

confidence: 99%

Peptide–Protein Coassemblies into Hierarchical and Bioactive Tubular Membranes

et al. 2023

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Multicomponent self-assembly offers opportunities for the design of complex and functional biomaterials with tunable properties. Here, we demonstrate how minor modifications in the molecular structures of peptide amphiphiles (PAs) and elastin-like recombinamers (ELs) can be used to generate coassembling tubular membranes with distinct structures, properties, and bioactivity. First, by introducing minor modifications in the charge density of PA molecules (PAK2, PAK3, PAK4), different diffusionreaction processes can be triggered, resulting in distinct membrane microstructures. Second, by combining different types of these PAs prior to their coassembly with ELs, further modifications can be achieved, tuning the structures and properties of the tubular membranes. Finally, by introducing the cell adhesive peptide RGDS in either the PA or EL molecules, it is possible to harness the different diffusion-reaction processes to generate tubular membranes with distinct bioactivities. The study demonstrates the possibility to trigger and achieve minor but crucial differences in coassembling processes and tune material structure and bioactivity. The study demonstrates the possibility to use minor, yet crucial, differences in coassembling processes to tune material structure and bioactivity.

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Enhancing Peptide Biomaterials for Biofabrication

Cited by 13 publications

References 199 publications

Short Peptide Nanofiber Biomaterials Ameliorate Local Hemostatic Capacity of Surgical Materials and Intraoperative Hemostatic Applications in Clinics

Short Peptide Nanofiber Biomaterials Ameliorate Local Hemostatic Capacity of Surgical Materials and Intraoperative Hemostatic Applications in Clinics

Rational design of potent ultrashort antimicrobial peptides with programmable assembly into nanostructured hydrogels

Peptide–Protein Coassemblies into Hierarchical and Bioactive Tubular Membranes

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