Your search keyword '"Gelain F"' showing total 132 results

51. New bioactive motifs and their use in functionalized self-assembling peptides for NSC differentiation and neural tissue engineering

Author

B. E. Cohen, B. Colleoni, Andrea Caprini, Diego Silva, Angelo L. Vescovi, Fabrizio Gelain, Stefania Antonini, Matteo Donegà, Daniela Cigognini, Gelain, F, Cigognini, D, Caprini, A, Silva, D, Colleoni, B, Donegá, M, Antonini, S, Cohen, B, and Vescovi, A

Subjects

Cellular differentiation, Molecular Sequence Data, Nanofibers, Biology, Microscopy, Atomic Force, Regenerative medicine, Neural tissue engineering, Mice, Tissue engineering, Neural Stem Cells, medicine, Animals, Humans, General Materials Science, Amino Acid Sequence, Spinal Cord Injuries, Cell Proliferation, Neurons, Tissue Engineering, Regeneration (biology), Nervous tissue, Cell Differentiation, Hydrogels, Neural stem cell, Cell biology, Rats, medicine.anatomical_structure, Immunology, self assembling peptides, NSC, Stem cell, Peptides

Abstract

Developing functionalized biomaterials for enhancing transplanted cell engraftment in vivo and stimulating the regeneration of injured tissues requires a multi-disciplinary approach customized for the tissue to be regenerated. In particular, nervous tissue engineering may take a great advantage from the discovery of novel functional motifs fostering transplanted stem cell engraftment and nervous fiber regeneration. Using phage display technology we have discovered new peptide sequences that bind to murine neural stem cell (NSC)-derived neural precursor cells (NPCs), and promote their viability and differentiation in vitro when linked to LDLK12 self-assembling peptide (SAPeptide). We characterized the newly functionalized LDLK12 SAPeptides via atomic force microscopy, circular dichroism and rheology, obtaining nanostructured hydrogels that support human and murine NSC proliferation and differentiation in vitro. One functionalized SAPeptide (Ac-FAQ), showing the highest stem cell viability and neural differentiation in vitro, was finally tested in acute contusive spinal cord injury in rats, where it fostered nervous tissue regrowth and improved locomotor recovery. Interestingly, animals treated with the non-functionalized LDLK12 had an axon sprouting/regeneration intermediate between Ac-FAQ-treated animals and controls. These results suggest that hydrogels functionalized with phage-derived peptides may constitute promising biomimetic scaffolds for in vitro NSC differentiation, as well as regenerative therapy of the injured nervous system. Moreover, this multi-disciplinary approach can be used to customize SAPeptides for other specific tissue engineering applications. © 2012 The Royal Society of Chemistry.

Published

2012

52. BMHP1-derived self-assembling peptides: hierarchically assembled structures with self-healing propensity and potential for tissue engineering applications

Author

Ki Tae Nam, Omar Villa, Ronald N. Zuckermann, Antonino Natalello, Francesca Taraballi, Angelo L. Vescovi, Diego Silva, Silvia Maria Doglia, Andrea Caprini, Fabrizio Gelain, Gelain, F, Silva, D, Caprini, A, Taraballi, F, Natalello, A, Villa, O, Nam, K, Zuckermann, R, Doglia, S, and Vescovi, A

Subjects

Scaffold, Nanostructure, Cellular differentiation, General Physics and Astronomy, Nanotechnology, Regenerative medicine, Neural Stem Cells, Tissue engineering, Humans, General Materials Science, Nerve Growth Factors, Cells, Cultured, Cell Proliferation, Neurons, Self-assembling peptides, Tissue Engineering, Chemistry, General Engineering, BIO/13 - BIOLOGIA APPLICATA, Cell Differentiation, BIO/10 - BIOCHIMICA, FIS/01 - FISICA SPERIMENTALE, Cell culture, Biotinylation, Biophysics, Feasibility Studies, Self-assembling peptide

Abstract

Self-assembling peptides (SAPs) are rapidly gaining interest as bioinspired scaffolds for cell culture and regenerative medicine applications. Bone Marrow Homing Peptide 1 (BMHP1) functional motif (PFSSTKT) was previously demonstrated to stimulate neural stem cell (NSC) viability and differentiation when linked to SAPs. We here describe a novel ensemble of SAPs, developed from the BMHP1 (BMHP1-SAPs), that spontaneously assemble into tabular fibers, twisted ribbons, tubes and hierarchical self-assembled sheets: organized structures in the nano- and microscale. Thirty-two sequences were designed and evaluated, including biotinylated and unbiotinylated sequences, as well as a hybrid peptide-peptoid sequence. Via X-ray diffraction (XRD), CD, and FTIR experiments we demonstrated that all of the BMHP1-SAPs share similarly organized secondary structures, that is, β-sheets and β-turns, despite their heterogeneous nanostructure morphology, scaffold stiffness, and effect over NSC differentiation and survival. Notably, we demonstrated the self-healing propensity of most of the tested BMHP1-SAPs, enlarging the set of potential applications of these novel SAPs. In in vitro cell culture experiments, we showed that some of these 10-mer peptides foster adhesion, differentiation, and proliferation of human NSCs. RGD-functionalized and hybrid peptide-peptoid self-assembling sequences also opened the door to BMHP1-SAP functionalization with further bioactive motifs, essential to tailor new scaffolds for specific applications. In in vivo experiments we verified a negligible reaction of the host nervous tissue to the injected and assembled BMHP1-SAP. This work will pave the way to the development of novel SAP sequences that may be useful for material science and regenerative medicine applications.

Published

2011

53. Glycine-spacers influence functional motifs exposure and self-assembling propensity of functionalized substrates tailored for neural stem cell cultures

Author

Francesca Taraballi, Silvia Maria Doglia, Antonino Natalello, Marcello Campione, Omar Villa, Fabrizio Gelain, Alberto Paleari, Taraballi, F, Natalello, A, Campione, M, Villa, O, Doglia, S, Paleari, A, and Gelain, F

Subjects

biomaterial, nanostructure, neural stem cell, AFM, FTIR, Micro-Raman, Scaffold, nanostructure, biomaterial, Biomedical Engineering, Biophysics, Neuroscience (miscellaneous), Biomaterial, Biology, Bioinformatics, Regenerative medicine, In vitro, Neural stem cell, Neural tissue engineering, neural stem cell, Micro-Raman, FTIR, Tissue engineering, Surface modification, AFM, Original Research, Neuroscience

Abstract

The understanding of phenomena involved in the self-assembling of bio-inspired biomaterials acting as three-dimensional scaffolds for regenerative medicine applications is a necessary step to develop effective therapies in neural tissue engineering. We investigated the self-assembled nanostructures of functionalized peptides featuring four, two or no glycine-spacers between the self-assembly sequence RADA16-I and the functional biological motif PFSSTKT. The effectiveness of their biological functionalization was assessed via in vitro experiments with neural stem cells (NSCs) and their molecular assembly was elucidated via atomic force microscopy, Raman and Fourier Transform Infrared spectroscopy. We demonstrated that glycine-spacers play a crucial role in the scaffold stability and in the exposure of the functional motifs. In particular, a glycine-spacer of four residues leads to a more stable nanostructure and to an improved exposure of the functional motif. Accordingly, the longer spacer of glycines, the more effective is the functional motif in both eliciting NSCs adhesion, improving their viability and increasing their differentiation. Therefore, optimized designing strategies of functionalized biomaterials may open, in the near future, new therapies in tissue engineering and regenerative medicine.

Published

2010

54. Effect of functionalization on the self-assembling propensity of β-sheet forming peptides

Author

Wonmuk Hwang, Francesca Taraballi, Fabrizio Gelain, Angelo L. Vescovi, Adele Sassella, Alberto Paleari, Marcello Campione, Taraballi, F, Campione, M, Sassella, A, Vescovi, A, Paleari, A, Hwang, W, and Gelain, F

Subjects

Chemistry, Bilayer, Beta sheet, Sequence (biology), Nanotechnology, General Chemistry, self-assembly, Condensed Matter Physics, peptide, symbols.namesake, Molecular dynamics, symbols, Surface modification, Molecule, Self-assembly, Raman spectroscopy

Abstract

The mechanism underlying self-assembly of short peptides has not been fully understood despite the fact that a few decades have passed since their serendipitous discovery. RADA16-I (AcN-RADARADARADARADA-CONH2), representative of a class of self-assembling peptides with alternate hydrophobic and hydrophilic residues, self-assembles into β-sheet bilayer filaments. Though a sliding diffusion model for this class of peptides has been developed in previous works, this theory need further improvements, supported by experimental investigations, to explain how RADA16-I functionalization with biological active motifs, added at the C-terminus of the self-assembling core sequence, may influence the self-assembling tendency of new functionalized peptides (FPs). Since FPs recently became a promising class of biomaterials for cell biology and tissue engineering, a better understanding of the phenomenon is necessary to design new scaffolds for nanotechnology applications. In this work we investigated viaatomic force microscopy and Raman spectroscopy the assembly of three RADA16-I FPs that have different hydrophobic/hydrophilic profiles and charge distributions. We performed molecular dynamics simulations to provide further insights into the experimental results: functionalizing self-assembling peptides can strongly influence or prevent molecular assembly into nanofibers. We also found certain vibrational molecular modes in Raman spectroscopy to be useful indicators for elucidating the assembly propensity of FPs. Preliminary FP designing strategies should therefore include functional motif sequences with balanced hydrophobicity profiles avoiding hydrophobic patches, causing fast hydrophobic collapses of the FP molecules, or very hydrophilic motifs capable of destabilizing the RADA16-I double layered β-sheet structure.

Published

2009

55. Integrated fluorine-18 fluorodeoxyglucose (18F-FDG) PET/CT compared to standard contrast-enhanced CT for characterization and staging of pulmonary tumors eligible for surgical resection

Author

Giuseppe La Tona, E. Boscolo, Emilio Quaia, F. Gelain, L. Bussoli, Riccardo Pizzolato, E. Lubin, Quaia, Emilio, Tona, G, Gelain, F, Pizzolato, R, Boscolo, E, and Bussoli, L.

Subjects

Lung Diseases, Male, medicine.medical_specialty, Lung Neoplasms, Contrast Media, Malignancy, Sensitivity and Specificity, Fluorodeoxyglucose F18, medicine, Humans, Radiology, Nuclear Medicine and imaging, Prospective Studies, Lung cancer, Neoplasm Staging, Fluorodeoxyglucose, Lung, Radiological and Ultrasound Technology, medicine.diagnostic_test, business.industry, Respiratory disease, Cancer, General Medicine, Middle Aged, medicine.disease, Image Enhancement, medicine.anatomical_structure, Positron emission tomography, Positron-Emission Tomography, Female, Radiology, Nuclear medicine, business, Tomography, X-Ray Computed, Emission computed tomography, medicine.drug

Abstract

Background: Accurate staging is necessary to determine the appropriate therapy in patients with lung cancer. Few studies have compared integrated fluorine-18 fluorodeoxyglucose (18F-FDG) positron emission tomography/computed tomography (PET/CT) and contrast-enhanced CT in the characterization and staging of pulmonary tumors considered eligible for surgical resection. Purpose: To compare 18F-FDG PET/CT with standard contrast-enhanced CT for the diagnosis and staging of lung neoplasms eligible for surgical resection. Material and Methods: Seventy-six consecutive patients (56 male, 20 female; mean age±SD, 63.4±20 years) with 84 pulmonary tumors suspected for malignancy and considered eligible for surgical resection were prospectively enrolled. Seventy-three malignant (65 non-small-cell lung carcinomas, one small-cell lung cancer, two carcinoids, and five metastases) and 11 benign lung tumors (three hamartomas, two sarcoidosis, one amyloidosis, one Wegener granulomatosis, one tuberculosis, and three areas of scarring) were finally diagnosed by histology. Tumor staging was based on the revised American Joint Committee on Cancer. Results: In lesion characterization, the sensitivity and specificity of 18F-FDG PET/CT versus contrast-enhanced CT were 90% vs. 83% and 18% vs. 63% ( P18F-FDG PET/CT versus contrast-enhanced CT were 78% vs. 46% and 80% vs. 93% ( P Conclusion: In patients with lung neoplasms considered eligible for surgical resection, 18F-FDG PET/CT versus contrast-enhanced CT revealed higher sensitivity in nodal staging, but lower specificity both in lesion characterization and nodal staging.

Published

2008

56. Electrospun micro- and nanofiber tubes for functional nervous regeneration in sciatic nerve transections

Author

Francesca Taraballi, Ubaldo Del Carro, Silvia Panseri, Carla Cunha, Joseph L. Lowery, Stefano Amadio, Angelo L. Vescovi, Fabrizio Gelain, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Chemical Engineering, Lowery, Joseph L., Panseri, S, Cunha, C, Lowery, J, Del Carro, U, Taraballi, F, Amadio, S, Vescovi, A, and Gelain, F

Subjects

Sciatic Neuropathy, lcsh:Biotechnology, Biology, Rats, Sprague-Dawley, Tissue engineering, Neurotrophic factors, lcsh:TP248.13-248.65, medicine, Electrochemistry, Animals, Nanotubes, Animal, Guided Tissue Regeneration, Nervous tissue, Regeneration (biology), Anatomy, Nerve Regeneration, Rats, Nanotube, medicine.anatomical_structure, Treatment Outcome, Peripheral nerve injury, Rat, Female, Sciatic nerve, Biotechnology, Biomedical engineering, Reinnervation, Research Article

Abstract

Background: Although many nerve prostheses have been proposed in recent years, in the case of consistent loss of nervous tissue peripheral nerve injury is still a traumatic pathology that may impair patient's movements by interrupting his motor-sensory pathways. In the last few decades tissue engineering has opened the door to new approaches;: however most of them make use of rigid channel guides that may cause cell loss due to the lack of physiological local stresses exerted over the nervous tissue during patient's movement. Electrospinning technique makes it possible to spin microfiber and nanofiber flexible tubular scaffolds composed of a number of natural and synthetic components, showing high porosity and remarkable surface/volume ratio. Results: In this study we used electrospun tubes made of biodegradable polymers (a blend of PLGA/PCL) to regenerate a 10-mm nerve gap in a rat sciatic nerve in vivo. Experimental groups comprise lesioned animals (control group) and lesioned animals subjected to guide conduits implantated at the severed nerve stumps, where the tubular scaffolds are filled with saline solution. Four months after surgery, sciatic nerves failed to reconnect the two stumps of transected nerves in the control animal group. In most of the treated animals the electrospun tubes induced nervous regeneration and functional reconnection of the two severed sciatic nerve tracts. Myelination and collagen IV deposition have been detected in concurrence with regenerated fibers. No significant inflammatory response has been found. Neural tracers revealed the re-establishment of functional neuronal connections and evoked potential results showed the reinnervation of the target muscles in the majority of the treated animals. Conclusion: Corroborating previous works, this study indicates that electrospun tubes, with no additional biological coating or drug loading treatment, are promising scaffolds for functional nervous regeneration. They can be knitted in meshes and various frames depending on the cytoarchitecture of the tissue to be regenerated. The versatility of this technique gives room for further scaffold improvements, like tuning the mechanical properties of the tubular structure or providing biomimetic functionalization. Moreover, these guidance conduits can be loaded with various fillers like collagen, fibrin, or self-assembling peptide gels or loaded with neurotrophic factors and seeded with cells. Electrospun scaffolds can also be synthesized in different micro-architectures to regenerate lesions in other tissues like skin and bone., Fondazione Cariplo, Nicolas G. and Dorothea K. Dumbros Scholarship and Fellowship Fund, United States. Army (contract DAAD-19-02-D-0002), Sixth Framework Programme (European Commission)

Published

2008

57. Biomimetic electrospun PVDF/self-assembling peptide piezoelectric scaffolds for neural stem cell transplantation in neural tissue engineering.

Author

Forouharshad M, Raspa A, Fortino G, Ciulla MG, Farazdaghi A, Stolojan V, Stendardo L, Bracco S, and Gelain F

Abstract

Piezoelectric materials can provide in situ electrical stimulation without external chemical or physical support, opening new frontiers for future bioelectric therapies. Polyvinylidene fluoride (PVDF) possesses piezoelectricity and biocompatibility, making it an electroactive biomaterial capable of enhancing bioactivity through instantaneous electrical stimulation, which indicates significant potential in tissue engineering. In this study, we developed electroactive and biomimetic scaffolds made of electrospun PVDF and self-assembling peptides (SAPs) to enhance stem cell transplantation for spinal cord injury regeneration. We investigated the morphology and crystalline polymorphs of the electrospun scaffolds. Morphological studies demonstrated the benefit of using mixed sodium dodecyl sulfate (SDS) and SAPs as additives to form thinner, uniform, and defect-free fibers. Regarding electroactive phases, β and γ phases-evidence of electroactivity-were predominant in aligned scaffolds and scaffolds modified with SDS and SAPs. In vitro studies showed that neural stem cells (NSCs) seeded on electrospun PVDF with additives exhibited desirable proliferation and differentiation compared to the gold standard. Furthermore, the orientation of the fibers influenced scaffold topography, resulting in a higher degree of cell orientation in fiber-aligned scaffolds compared to randomly oriented ones., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

58. In Situ Transglutaminase Cross-Linking Improves Mechanical Properties of Self-Assembling Peptides for Biomedical Applications.

Author

Ciulla MG, Marchini A, Gazzola J, Forouharshad M, Pugliese R, and Gelain F

Subjects

Peptides pharmacology, Peptides chemistry, Biocompatible Materials pharmacology, Biocompatible Materials chemistry, Hydrogels pharmacology, Hydrogels chemistry, Transglutaminases, Tissue Engineering methods

Abstract

The development of three-dimensional (3D) biomaterials that mimic natural tissues is required for efficiently restoring physiological functions of injured tissues and organs. In the field of soft hydrogels, self-assembled peptides (SAPs) stand out as distinctive biomimetic scaffolds, offering tunable properties. They have garnered significant attention in nanomedicine due to their innate ability to self-assemble, resulting in the creation of fibrous nanostructures that closely mimic the microenvironment of the extracellular matrix (ECM). This unique feature ensures their biocompatibility and bioactivity, making them a compelling area of study over the past few decades. As they are soft hydrogels, approaches are necessary to enhance the stiffness and resilience of the SAP materials. This work shows an enzymatic strategy to selectively increase the stiffness and resiliency of functionalized SAPs using transglutaminase (TGase) type 2, an enzyme capable of triggering the formation of isopeptide bonds. To this aim, we synthesized a set of SAP sequences and characterized their cross-linking via rheological experiments, atomic force microscopy (AFM), thioflavin-T binding assay, and infrared spectroscopy (ATR-FTIR) tests. The results showed an improvement of the storage modulus of cross-linked SAPs at no cost of the maximum stress-at-failure. Further, in in vitro tests, we examined and validated the TGase capability to cross-link SAPs without hampering seeded neural stem cells (hNSCs) viability and differentiation, potentially leaving the door open for safe in situ cross-linking reactions in vivo .

Published

2024

59. Multiparametric in vitro and in vivo analysis of the safety profile of self-assembling peptides.

Author

Ramirez-Labrada A, Santiago L, Pesini C, Arrieta M, Arias M, Calvo Pérez A, Ciulla MG, Forouharshad M, Pardo J, Gálvez EM, and Gelain F

Subjects

Humans, Tissue Engineering methods, Neurons, Biocompatible Materials pharmacology, Biocompatible Materials chemistry, Peptides chemistry, Nanostructures chemistry

Abstract

Self-assembling peptides (SAPs) have gained significant attention in biomedicine because of their unique properties and ability to undergo molecular self-assembly driven by non-covalent interactions. By manipulating their composition and structure, SAPs can form well-ordered nanostructures with enhanced selectivity, stability and biocompatibility. SAPs offer advantages such as high chemical and biological diversity and the potential for functionalization. However, studies concerning its potentially toxic effects are very scarce, a limitation that compromises its potential translation to humans. This study investigates the potentially toxic effects of six different SAP formulations composed of natural amino acids designed for nervous tissue engineering and amenable to ready cross-linking boosting their biomechanical properties. All methods were performed in accordance with the relevant guidelines and regulations. A wound-healing assay was performed to evaluate how SAPs modify cell migration. The results in vitro demonstrated that SAPs did not induce genotoxicity neither skin sensitization. In vivo, SAPs were well-tolerated without any signs of acute systemic toxicity. Interestingly, SAPs were found to promote the migration of endothelial, macrophage, fibroblast, and neuronal-like cells in vitro, supporting a high potential for tissue regeneration. These findings contribute to the development and translation of SAP-based biomaterials for biomedical applications., (© 2024. The Author(s).)

Published

2024

60. Low-power microwaves: a cell-compatible physical treatment to enhance the mechanical properties of self-assembling peptides.

Author

Ciulla MG, Marchini A, Gazzola J, Sambrotta M, and Gelain F

Abstract

Biomaterials designed for tissue engineering applications should, among other requirements, mimic the native extracellular matrix (ECM) of the tissues to be regenerated, both in terms of biomimetic and mechanical properties. Ideally, the scaffold stiffness and stress resistance should be tuned for each specific implantation therapy. Self-assembling peptides (SAPs) are promising synthetic bionanomaterials prone to easy multi-functionalization, bestowing biomimetic properties. However, they usually yield soft and fragile hydrogels unsuited for the regeneration of medium-to-hard tissues. For this purpose, chemical cross-linking of SAPs is an option, but it often requires a moderately toxic and expensive chemical compound and/or the presence of specific residues/reactive sites, posing issues for its feasibility and translational potential. In this work, we introduced, characterized by rheology, atomic force microscopy (AFM), Thioflavin-T assay (ThT), and Fourier transform infrared (FT-IR) tests, and optimized (by tuning the power, temperature and treatment time) a novel fast, green and affordable methodology using mild microwave (MW) irradiation to increase the mechanical properties of diverse classes of SAPs. Low-power MWs increase stiffness, resilience, and β-structuration, while high-power MW treatments partially denature the tested SAPs. Our pure-physical methodology does not alter the SAP biomimetic properties (verified via in vitro tests of viability and differentiation of human neural stem cells), is compatible with already seeded cells, and is also synergic with genipin-based cross-linking of SAPs; therefore, it may become the next standard for SAP preparation in tissue engineering applications at hand of all research labs and in clinics.

Published

2023

61. Biomimetic Electrospun Self-Assembling Peptide Scaffolds for Neural Stem Cell Transplantation in Neural Tissue Engineering.

Author

Forouharshad M, Raspa A, Marchini A, Ciulla MG, Magnoni A, and Gelain F

Abstract

Spinal cord regeneration using stem cell transplantation is a promising strategy for regenerative therapy. Stem cells transplanted onto scaffolds that can mimic natural extracellular matrix (ECM) have the potential to significantly improve outcomes. In this study, we strived to develop a cell carrier by culturing neural stem cells (NSCs) onto electrospun 2D and 3D constructs made up of specific crosslinked functionalized self-assembling peptides (SAPs) featuring enhanced biomimetic and biomechanical properties. Morphology, architecture, and secondary structures of electrospun scaffolds in the solid-state and electrospinning solution were studied step by step. Morphological studies showed the benefit of mixed peptides and surfactants as additives to form thinner, uniform, and defect-free fibers. It has been observed that β-sheet conformation as evidence of self-assembling has been predominant throughout the process except for the electrospinning solution. In vitro NSCs seeded on electrospun SAP scaffolds in 2D and 3D conditions displayed desirable proliferation, viability, and differentiation in comparison to the gold standard. In vivo biocompatibility assay confirmed the permissibility of implanted fibrous channels by foreign body reaction. The results of this study demonstrated that fibrous 2D/3D electrospun SAP scaffolds, when shaped as micro-channels, can be suitable to support NSC transplantation for regeneration following spinal cord injury.

Published

2023

62. Morphoscanner2.0: A new python module for analysis of molecular dynamics simulations.

Author

Fontana F, Carlino C, Malik A, and Gelain F

Subjects

Proteins chemistry, Peptides, Protein Structure, Secondary, Molecular Dynamics Simulation, Software

Abstract

Molecular dynamics simulations, at different scales, have been exploited for investigating complex mechanisms ruling biologically inspired systems. Nonetheless, with recent advances and unprecedented achievements, the analysis of molecular dynamics simulations requires customized workflows. In 2018, we developed Morphoscanner to retrieve structural relations within self-assembling peptide systems. In particular, we conceived Morphoscanner for tracking the emergence of β-structured domains in self-assembling peptide systems. Here, we introduce Morphoscanner2.0. Morphoscanner2.0 is an object-oriented library for structural and temporal analysis of atomistic and coarse-grained molecular dynamics (CG-MD) simulations written in Python. The library leverages MDAnalysis, PyTorch and NetworkX to perform the pattern recognition of secondary structure patterns, and interfaces with Pandas, Numpy and Matplotlib to make the results accessible to the user. We used Morphoscanner2.0 on both simulation trajectories and protein structures. Because of its dependencies on the MDAnalysis package, Morphoscanner2.0 can read several file formats generated by widely-used molecular simulation packages such as NAMD, Gromacs, OpenMM. Morphoscanner2.0 also includes a routine for tracking the alpha-helix domain formation., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Fontana et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

63. A Light Scattering Investigation of Enzymatic Gelation in Self-Assembling Peptides.

Author

Buzzaccaro S, Ruzzi V, Gelain F, and Piazza R

Abstract

Self-assembling peptides (SAPs) have been increasingly studied as hydrogel-former gelators because they can create biocompatible environments. A common strategy to trigger gelation, is to use a pH variation, but most methods result in a change in pH that is too rapid, leading to gels with hardly reproducible properties. Here, we use the urea-urease reaction to tune gel properties, by a slow and uniform pH increase. We were able to produce very homogeneous and transparent gels at several SAP concentrations, ranging from c=1g/L to c=10g/L. In addition, by exploiting such a pH control strategy, and combining photon correlation imaging with dynamic light scattering measurements, we managed to unravel the mechanism by which gelation occurs in solutions of (LDLK)3-based SAPs. We found that, in diluted and concentrated solutions, gelation follows different pathways. This leads to gels with different microscopic dynamics and capability of trapping nanoparticles. At high concentrations, a strong gel is formed, made of relatively thick and rigid branches that firmly entrap nanoparticles. By contrast, the gel formed in dilute conditions is weaker, characterized by entanglements and crosslinks of very thin and flexible filaments. The gel is still able to entrap nanoparticles, but their motion is not completely arrested. These different gel morphologies can potentially be exploited for controlled multiple drug release.

Published

2023

64. Structure-activity relationships of antibacterial peptides.

Author

Ciulla MG and Gelain F

Subjects

Animals, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Structure-Activity Relationship, Molecular Structure, Microbial Sensitivity Tests, Mammals, Peptides pharmacology, Anti-Infective Agents

Abstract

Antimicrobial peptides play a crucial role in innate immunity, whose components are mainly peptide-based molecules with antibacterial properties. Indeed, the exploration of the immune system over the past 40 years has revealed a number of natural peptides playing a pivotal role in the defence mechanisms of vertebrates and invertebrates, including amphibians, insects, and mammalians. This review provides a discussion regarding the antibacterial mechanisms of peptide-based agents and their structure-activity relationships (SARs) with the aim of describing a topic that is not yet fully explored. Some growing evidence suggests that innate immunity should be strongly considered for the development of novel antibiotic peptide-based libraries. Also, due to the constantly rising concern of antibiotic resistance, the development of new antibiotic drugs is becoming a priority of global importance. Hence, the study and the understanding of defence phenomena occurring in the immune system may inspire the development of novel antibiotic compound libraries and set the stage to overcome drug-resistant pathogens. Here, we provide an overview of the importance of peptide-based antibacterial sources, focusing on accurately selected molecular structures, their SARs including recently introduced modifications, their latest biotechnology applications, and their potential against multi-drug resistant pathogens. Last, we provide cues to describe how antibacterial peptides show a better scope of action selectivity than several anti-infective agents, which are characterized by non-selective activities and non-targeted actions toward pathogens., (© 2023 The Authors. Microbial Biotechnology published by Applied Microbiology International and John Wiley & Sons Ltd.)

Published

2023

65. Long-term cultures of human pancreatic islets in self-assembling peptides hydrogels.

Author

Marchini A, Ciulla MG, Antonioli B, Agnoli A, Bovio U, Visnoviz V, Bertuzzi F, and Gelain F

Abstract

Human pancreatic islets transplantation is an experimental therapeutic treatment for Type I Diabetes. Limited islets lifespan in culture remains the main drawback, due to the absence of native extracellular matrix as mechanical support after their enzymatic and mechanical isolation procedure. Extending the limited islets lifespan by creating a long-term in vitro culture remains a challenge. In this study, three biomimetic self-assembling peptides were proposed as potential candidates to recreate in vitro a pancreatic extracellular matrix, with the aim to mechanically and biologically support human pancreatic islets, by creating a three-dimensional culture system. The embedded human islets were analyzed for morphology and functionality in long-term cultures (14-and 28-days), by evaluating β-cells content, endocrine component, and extracellular matrix constituents. The three-dimensional support provided by HYDROSAP scaffold, and cultured into MIAMI medium, displayed a preserved islets functionality, a maintained rounded islets morphology and an invariable islets diameter up to 4 weeks, with results analogues to freshly-isolated islets. In vivo efficacy studies of the in vitro 3D cell culture system are ongoing; however, preliminary data suggest that human pancreatic islets pre-cultured for 2 weeks in HYDROSAP hydrogels and transplanted under subrenal capsule may restore normoglycemia in diabetic mice. Therefore, engineered self-assembling peptide scaffolds may provide a useful platform for long-term maintenance and preservation of functional human pancreatic islets in vitro ., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Marchini, Ciulla, Antonioli, Agnoli, Bovio, Visnoviz, Bertuzzi and Gelain.)

Published

2023

66. Human Neural Stem Cell-Based Drug Product: Clinical and Nonclinical Characterization.

Author

Profico DC, Gelati M, Ferrari D, Sgaravizzi G, Ricciolini C, Projetti Pensi M, Muzi G, Cajola L, Copetti M, Ciusani E, Pugliese R, Gelain F, and Vescovi AL

Subjects

Humans, Reproducibility of Results, Cryopreservation, Quality Control, Neural Stem Cells, Amyotrophic Lateral Sclerosis drug therapy

Abstract

Translation of cell therapies into clinical practice requires the adoption of robust production protocols in order to optimize and standardize the manufacture and cryopreservation of cells, in compliance with good manufacturing practice regulations. Between 2012 and 2020, we conducted two phase I clinical trials (EudraCT 2009-014484-39, EudraCT 2015-004855-37) on amyotrophic lateral sclerosis secondary progressive multiple sclerosis patients, respectively, treating them with human neural stem cells. Our production process of a hNSC-based medicinal product is the first to use brain tissue samples extracted from fetuses that died in spontaneous abortion or miscarriage. It consists of selection, isolation and expansion of hNSCs and ends with the final pharmaceutical formulation tailored to a specific patient, in compliance with the approved clinical protocol. The cells used in these clinical trials were analyzed in order to confirm their microbiological safety; each batch was also tested to assess identity, potency and safety through morphological and functional assays. Preclinical, clinical and in vitro nonclinical data have proved that our cells are safe and stable, and that the production process can provide a high level of reproducibility of the cultures. Here, we describe the quality control strategy for the characterization of the hNSCs used in the above-mentioned clinical trials.

Published

2022

67. Synthetic scaffolds for 3D cell cultures and organoids: applications in regenerative medicine.

Author

Marchini A and Gelain F

Subjects

Animals, Cell Culture Techniques, Three Dimensional, Peptides, Tissue Engineering, Organoids, Regenerative Medicine

Abstract

Three-dimensional (3D) cell cultures offer an unparalleled platform to recreate spatial arrangements of cells in vitro . 3D cell culture systems have gained increasing interest due to their evident advantages in providing more physiologically relevant information and more predictive data compared to their two-dimensional (2D) counterpart. Design and well-established fabrication of organoids (a particular type of 3D cell culture system) are nowadays considered a pivotal achievement for their ability to replicate in vitro cytoarchitecture and the functionalities of an organ. In this condition, pluripotent stem cells self-organize into 3D structures mimicking the in vivo microenvironments, architectures and multi-lineage differentiation. Scaffolds are key supporting elements in these 3D constructs, and Matrigel is the most commonly used matrix despite its relevant translation limitations including animal-derived sources, non-defined composition, batch-to-batch variability and poorly tailorable properties. Alternatively, 3D synthetic scaffolds, including self-assembling peptides, show promising biocompatibility and biomimetic properties, and can be tailored on specific target tissue/cells. In this review, we discuss the recent advances on 3D cell culture systems and organoids, promising tools for tissue engineering and regenerative medicine applications. For this purpose, we will describe the current state-of-the-art on 3D cell culture systems and organoids based on currently available synthetic-based biomaterials (including tailored self-assembling peptides) either tested in in vivo animal models or developed in vitro with potential application in the field of tissue engineering, with the aim to inspire researchers to take on such promising platforms for clinical applications in the near future.

Published

2022

68. Editorial: New Microenvironments for Neuronal Differentiation.

Author

Lecchi M and Gelain F

Abstract

Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2022

69. Boosted Cross-Linking and Characterization of High-Performing Self-Assembling Peptides.

Author

Ciulla MG, Pugliese R, and Gelain F

Abstract

Tissue engineering (TE) strategies require the design and characterization of novel biomaterials capable of mimicking the physiological microenvironments of the tissues to be regenerated. As such, implantable materials should be biomimetic, nanostructured and with mechanical properties approximating those of the target organ/tissue. Self-assembling peptides (SAPs) are biomimetic nanomaterials that can be readily synthesized and customized to match the requirements of some TE applications, but the weak interactions involved in the self-assembling phenomenon make them soft hydrogels unsuited for the regeneration of medium-to-hard tissues. In this work, we moved significant steps forward in the field of chemical cross-linked SAPs towards the goal of stiff peptidic materials suited for the regeneration of several tissues. Novel SAPs were designed and characterized to boost the 4-( N- Maleimidomethyl) cyclohexane-1-carboxylic acid 3-sulpho- N -hydroxysuccinimide ester (Sulfo-SMCC) mediated cross-linking reaction, where they reached G' values of ~500 kPa. An additional orthogonal cross-linking was also effective and allowed to top remarkable G' values of 840 kPa. We demonstrated that cross-linking fastened the pre-existing self-aggregated nanostructures, and at the same time, a strong presence of ß-structures is necessary for an effective cross-linking of (LKLK) 3 -based SAPs. Combining strong SAP design and orthogonal cross-linking reactions, we brought SAP stiffness closer to the MPa threshold, and as such, we opened the door of the regeneration of skin, muscle and lung to biomimetic SAP technology.

Published

2022

70. Bioinspired photo-crosslinkable self-assembling peptides with pH-switchable "on-off" luminescence.

Author

Pugliese R, Montuori M, and Gelain F

Abstract

Significant progress has been made in peptide self-assembly over the past two decades; however, the in situ cross-linking of self-assembling peptides yielding better performing nanomaterials is still in its infancy. Indeed, self-assembling peptides (SAPs), relying only on non-covalent interactions, are mechanically unstable and susceptible to solvent erosion, greatly hindering their practical application. Herein, drawing inspiration from the biological functions of tyrosine, we present a photo-cross-linking approach for the in situ cross-linking of a tyrosine-containing LDLK12 SAP. This method is based on the ruthenium-complex-catalyzed conversion of tyrosine to dityrosine upon light irradiation. We observed a stable formation of dityrosine cross-linking starting from 5 minutes, with a maximum peak after 1 hour of UV irradiation. Furthermore, the presence of a ruthenium complex among the assembled peptide bundles bestows unusual fluorescence intensity stability up to as high as 42 °C, compared to the bare ruthenium complex. Also, due to a direct deprotonation-protonation process between the ruthenium complex and SAP molecules, the fluorescence of the photo-cross-linked SAP is capable of exhibiting "off-on-off-on" luminescence switchable from acid to basic pH. Lastly, we showed that the photo-cross-linked hydrogel exhibited enhanced mechanical stability with a storage modulus of ∼26 kPa, due to the formation of a densely entangled fibrous network of SAP molecules through dityrosine linkages. As such, this ruthenium-mediated photo-cross-linked SAP hydrogel could be useful in the design of novel tyrosine containing SAP materials with intriguing potential for biomedical imaging, pH sensing, photonics, soft electronics, and bioprinting., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021

71. Correction to Self-Assembling Peptide EAK16 and RADA16 Nanofiber Scaffold Hydrogel.

Author

Gelain F, Luo Z, and Zhang S

Published

2021

72. HyperBeta: characterizing the structural dynamics of proteins and self-assembling peptides.

Author

Nobile MS, Fontana F, Manzoni L, Cazzaniga P, Mauri G, Saracino GAA, Besozzi D, and Gelain F

Subjects

Molecular Structure, Peptides chemistry, Proteins chemistry, Software

Abstract

Self-assembling processes are ubiquitous phenomena that drive the organization and the hierarchical formation of complex molecular systems. The investigation of assembling dynamics, emerging from the interactions among biomolecules like amino-acids and polypeptides, is fundamental to determine how a mixture of simple objects can yield a complex structure at the nano-scale level. In this paper we present HyperBeta, a novel open-source software that exploits an innovative algorithm based on hyper-graphs to efficiently identify and graphically represent the dynamics of [Formula: see text]-sheets formation. Differently from the existing tools, HyperBeta directly manipulates data generated by means of coarse-grained molecular dynamics simulation tools (GROMACS), performed using the MARTINI force field. Coarse-grained molecular structures are visualized using HyperBeta 's proprietary real-time high-quality 3D engine, which provides a plethora of analysis tools and statistical information, controlled by means of an intuitive event-based graphical user interface. The high-quality renderer relies on a variety of visual cues to improve the readability and interpretability of distance and depth relationships between peptides. We show that HyperBeta is able to track the [Formula: see text]-sheets formation in coarse-grained molecular dynamics simulations, and provides a completely new and efficient mean for the investigation of the kinetics of these nano-structures. HyperBeta will therefore facilitate biotechnological and medical research where these structural elements play a crucial role, such as the development of novel high-performance biomaterials in tissue engineering, or a better comprehension of the molecular mechanisms at the basis of complex pathologies like Alzheimer's disease.

Published

2021

73. Self-assembling peptide scaffolds in the clinic.

Author

Gelain F, Luo Z, Rioult M, and Zhang S

Abstract

Well-defined scaffold hydrogels made of self-assembling peptides have found their way into clinical products. By examining the properties and applications of two self-assembling peptides-EAK16 and RADA16-we highlight the potential for translating designer biological scaffolds into commercial products.

Published

2021

74. Self-assembling peptide hydrogels for the stabilization and sustained release of active Chondroitinase ABC in vitro and in spinal cord injuries.

Author

Raspa A, Carminati L, Pugliese R, Fontana F, and Gelain F

Subjects

Animals, Delayed-Action Preparations therapeutic use, Hydrogels therapeutic use, Nerve Regeneration, Peptides therapeutic use, Rats, Spinal Cord, Chondroitin ABC Lyase therapeutic use, Spinal Cord Injuries drug therapy

Abstract

Activated microglia/macrophages infiltration, astrocyte migration, and increased production of inhibitory chondroitin sulfate proteoglycans (CSPGs) are standard harmful events taking place after the spinal cord injuries (SCI). The gliotic scar, viz. the outcome of chronic SCI, constitutes a long-lasting physical and chemical barrier to axonal regrowth. In the past two decades, various research groups targeted the hostile host microenvironments of the gliotic scar at the injury site. To this purpose, biomaterial scaffolds demonstrate to provide a promising potential for nervous cell restoration. We here focused our efforts on two self-assembling peptides (SAPs), featuring different self-assembled nanostructures, and on different methods of drug loading to exploit the neuroregenerative potential of Chondroitinase ABC (ChABC), a thermolabile pro-plastic agent attenuating the inhibitory action of CSPGs. Enzymatic activity of ChABC (usually lasting less than 72 hours in vitro) released from SAPs was remarkably detected up to 42 days in vitro. ChABC was continuously released in vitro from a few days to 42 days as well. Also, injections of ChABC loaded SAP hydrogels favored host neural regeneration and behavioral recovery in chronic SCI in rats. Hence, SAP hydrogels showed great promise for the delivery of Chondroitinase ABC in future therapies targeting chronic SCI., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2021

75. Mimicking Extracellular Matrix via Engineered Nanostructured Biomaterials for Neural Repair.

Author

Raspa A and Gelain F

Subjects

Animals, Biomimetics, Hydrogels, Neurons, Biocompatible Materials, Extracellular Matrix

Abstract

Extracellular matrix (ECM) consists of proteins, proteoglycans, and different soluble molecules. ECM provides structural support to mammalian cells. ECM is responsible for important cell functions, as well as assembling cells into various tissues and organs, regulating growth and cell-cell interaction. Recent studies have shown the potential of nanostructured biomaterials to mimic native ECM. Developing tailor-made biomaterials that mimic the complex nanoscale mesh of local ECM is not a trivial endeavor: bio-inspired biomaterials are designed to supply a healthy ECMlike structure, capable of filling the lesion cavity, favoring transplanted cell engraftment, providing physical support to endogenous neurogenesis and also tuning the inflammatory response to protect spared neurons. The strategies used to manufacture biomimetic hydrogel scaffold represent particularly important prospects of novel therapies for CNS regeneration. During this review, we describe with details the most promising regulatory pathways from ECM involved in the CNS injury and regeneration and we draw a line to the biomimetic potential of engineered nanostructured biomaterials aimed at mimicking extracellular matrix constructs and favoring the release of pro-regenerative agents. Lastly, a brief overview of their application in clinical trials is provided., (Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.net.)

Published

2021

76. Self-Assembling Peptide EAK16 and RADA16 Nanofiber Scaffold Hydrogel.

Author

Gelain F, Luo Z, and Zhang S

Subjects

Animals, Biomechanical Phenomena, Biomimetic Materials chemistry, Humans, Nanofibers chemistry, Printing, Three-Dimensional, Tissue Engineering, Hydrogels chemistry, Oligopeptides chemistry

Abstract

Short peptides are ubiquitous in nature. They are found as hormones, pheromones, antibacterial and antifungal agents in innate immunity systems, toxins, and pesticides. But no one seriously considered that peptides could be useful as scaffold hydrogel materials. There has been a significant change since 1990 after the discovery of an ionic self-complementary peptide as a very interesting repeating segment in a yeast protein. It is now recognized that self-assembling peptides made from 20 natural amino acids have real material properties. Currently, many diverse applications have been developed from these simple and designer self-assembling peptide scaffold hydrogels and are commercially available. Examples include: (1) real 3D tissue cell cultures of diverse tissue cells and various stem cells, (2) reparative and regenerative medicine as well as tissue engineering, (3) 3D tissue printing, (4) sustained releases of small molecules, growth factors, and monoclonal antibodies, and (5) accelerated wound healings of skin and diabetic ulcers as well as instant hemostatic applications in surgery. Self-assembling peptide nanobiotechnology will likely continue to expand in many directions in the coming years.

Published

2020

77. Pulmonary Hypertension in COVID-19 Pneumoniae: It Is Not Always as It Seems.

Author

Pasqualetto MC, Sorbo MD, Vitiello M, Ferrara C, Scevola M, Pantalone F, Gelain F, Aloi C, Nizzetto M, and Rigo F

Abstract

A patient affected by COVID-19 pneumonia may develop pulmonary hypertension (PH) and secondary right ventricular (RV) involvement, due to lung parenchymal and interstitial damage and altered pulmonary haemodynamics, even in non-advanced phases of the disease. This is a consequence of hypoxic vasoconstriction of the pulmonary circulation, the use of positive end-expiratory pressure (PEEP) in mechanical ventilation, pulmonary endothelial injury, and local inflammatory thrombotic and/or thromboembolic processes. We report the case of a young man admitted with a diagnosis of COVID-19 pneumoniae with PH unrelated to viral infection and in whom partial anomalous pulmonary venous drainage (PAPVD) was eventually diagnosed., Learning Points: COVID-19 patients, even if previously well, can have pulmonary hypertension due to other causes.The cause of pulmonary hypertension should always be sought and not assumed, even in COVID-19 patients., Competing Interests: Conflicts of Interests: The Authors declare that there are no competing interests., (© EFIM 2020.)

Published

2020

78. Author Correction: Control over the fibrillization yield by varying the oligomeric nucleation propensities of self-assembling peptides.

Author

Lau CYJ, Fontana F, Mandemaker LDB, Wezendonk D, Vermeer B, Bonvin AMJJ, de Vries R, Zhang H, Remaut K, van den Dikkenberg J, Medeiros-Silva J, Hassan A, Perrone B, Kuemmerle R, Gelain F, Hennink WE, Weingarth M, and Mastrobattista E

Published

2020

79. Control over the fibrillization yield by varying the oligomeric nucleation propensities of self-assembling peptides.

Author

Lau CYJ, Fontana F, Mandemaker LDB, Wezendonk D, Vermeer B, Bonvin AMJJ, de Vries R, Zhang H, Remaut K, van den Dikkenberg J, Medeiros-Silva J, Hassan A, Perrone B, Kuemmerle R, Gelain F, Hennink WE, Weingarth M, and Mastrobattista E

Abstract

Self-assembling peptides are an exemplary class of supramolecular biomaterials of broad biomedical utility. Mechanistic studies on the peptide self-assembly demonstrated the importance of the oligomeric intermediates towards the properties of the supramolecular biomaterials being formed. In this study, we demonstrate how the overall yield of the supramolecular assemblies are moderated through subtle molecular changes in the peptide monomers. This strategy is exemplified with a set of surfactant-like peptides (SLPs) with different β-sheet propensities and charged residues flanking the aggregation domains. By integrating different techniques, we show that these molecular changes can alter both the nucleation propensity of the oligomeric intermediates and the thermodynamic stability of the fibril structures. We demonstrate that the amount of assembled nanofibers are critically defined by the oligomeric nucleation propensities. Our findings offer guidance on designing self-assembling peptides for different biomedical applications, as well as insights into the role of protein gatekeeper sequences in preventing amyloidosis., (© 2020. The Author(s).)

Published

2020

80. Cross-Linked Self-Assembling Peptides and Their Post-Assembly Functionalization via One-Pot and In Situ Gelation System.

Author

Pugliese R and Gelain F

Subjects

Biomechanical Phenomena, Cell Differentiation, Hydrogels chemistry, Neural Stem Cells cytology, Rheology, Tissue Engineering, Carbodiimides chemistry, Gelatin chemistry, Peptides chemistry, Succinimides chemistry

Abstract

Supramolecular nanostructures formed through peptide self-assembly can have a wide range of applications in the biomedical landscape. However, they often lose biomechanical properties at low mechanical stress due to the non-covalent interactions working in the self-assembling process. Herein, we report the design of cross-linked self-assembling peptide hydrogels using a one-pot in situ gelation system, based on 1-ethyl-3-[3-dimethylaminopropyl] carbodiimide/N-hydroxysulfosuccinimide (EDC/sulfo-NHS) coupling, to tune its biomechanics. EDC/sulfo-NHS coupling led to limited changes in storage modulus (from 0.9 to 2 kPa), but it significantly increased both the strain (from 6% to 60%) and failure stress (from 19 to 35 Pa) of peptide hydrogel without impairing the spontaneous formation of β-sheet-containing nano-filaments. Furthermore, EDC/sulfo-NHS cross-linking bestowed self-healing and thixotropic properties to the peptide hydrogel. Lastly, we demonstrated that this strategy can be used to incorporate bioactive functional motifs after self-assembly on pre-formed nanostructures by functionalizing an Ac-LDLKLDLKLDLK-CONH 2 (LDLK12) self-assembling peptide with the phage display-derived KLPGWSG peptide involved in the modulation of neural stem cell proliferation and differentiation. The incorporation of a functional motif did not alter the peptide's secondary structure and its mechanical properties. The work reported here offers new tools to both fine tune the mechanical properties of and tailor the biomimetic properties of self-assembling peptide hydrogels while retaining their nanostructures, which is useful for tissue engineering and regenerative medicine applications.

Published

2020

81. Multi-Functionalized Self-Assembling Peptides as Reproducible 3D Cell Culture Systems Enabling Differentiation and Survival of Various Human Neural Stem Cell Lines.

Author

Marchini A, Favoino C, and Gelain F

Abstract

Neural stem cells-based therapies have shown great potential for central nervous system regeneration, with three-dimensional (3D) culture systems representing a key technique for tissue engineering applications, as well as disease modeling and drug screenings. Self-assembling peptides (SAPs), providing biomimetic synthetic micro-environments regulating cellular functionality and tissue repair, constitute a suitable tool for the production of complex tissue-like structures in vitro . However, one of the most important drawbacks in 3D cultures, obtained via animal-derived substrates and serum-rich media, is the reproducibility and tunability of a standardized methodology capable to coax neural differentiation of different human cell lines. In this work we cultured four distinct human neural stem cell (hNSC) lines in 3D synthetic multifunctionalized hydrogel (named HYDROSAP) for up to 6 weeks. Three-dimensional cultures of differentiating hNSCs exhibited a progressive differentiation and maturation over time. All hNSCs-derived neurons in 3D culture system exhibited randomly organized entangled networks with increasing expression of GABAergic and glutamatergic phenotypes and presence of cholinergic ones. Oligodendrocytes formed insulating myelin sheaths positive for myelin basic protein (MBP). In summary, results demonstrated a successfully standardized and reproducible 3D cell culture system for hNSC differentiation and maturation in serum-free conditions useful for future therapies., (Copyright © 2020 Marchini, Favoino and Gelain.)

Published

2020

82. "Bottom-Up" Strategy for the Identification of Novel Soybean Peptides with Angiotensin-Converting Enzyme Inhibitory Activity.

Author

Dellafiora L, Pugliese R, Bollati C, Gelain F, Galaverna G, Arnoldi A, and Lammi C

Subjects

Angiotensin-Converting Enzyme Inhibitors pharmacology, Antihypertensive Agents pharmacology, Cell Line, Cell Survival drug effects, Humans, Peptidyl-Dipeptidase A chemistry, Plant Extracts pharmacology, Spectroscopy, Fourier Transform Infrared, Angiotensin-Converting Enzyme Inhibitors chemistry, Antihypertensive Agents chemistry, Peptides chemistry, Plant Extracts chemistry, Glycine max chemistry

Abstract

IAVPTGVA (Soy1) and LPYP are two soybean peptides, which display a multifunctional behavior, showing in vitro hypocholesterolemic and hypoglycemic activities. A preliminary screening of their structures using BIOPEP suggested that they might be potential angiotensin-converting enzyme (ACE) inhibitors. Therefore, a bottom-up-aided approach was developed in order to clarify the in vitro hypotensive activity. Soy1 and LPYP dropped the intestinal and renal ACE enzyme activity with IC 50 values equal to 14.7 ± 0.28 and 5.0 ± 0.28 μM (Caco-2 cells), and 6.0 ± 0.35 and 6.8 ± 0.20 μM (HK-2 cells), respectively. In parallel, a molecular modeling study suggested their capability to act as competitive inhibitors of this enzyme. Finally, in order to increase both their stability and hypotensive properties, a suitable strategy for the harmless control of their release from a nanomaterial was developed through their encapsulation into the RADA16-assembling peptide.

Published

2020

83. Probing mechanical properties and failure mechanisms of fibrils of self-assembling peptides.

Author

Fontana F and Gelain F

Abstract

Self-assembling peptides (SAPs) are a promising class of biomaterials amenable to easy molecular design and functionalization. Despite their increasing usage in regenerative medicine, a detailed analysis of their biomechanics at the nanoscale level is still missing. In this work, we propose and validate, in all-atom dynamics, a coarse-grained model to elucidate strain distribution, failure mechanisms and biomechanical effects of functionalization of two SAPs when subjected to both axial stretching and bending forces. We highlight different failure mechanisms for fibril seeds and fibrils, as well as the negligible contribution of the chosen functional motif to the overall system rupture. This approach could lay the basis for the development of "more" coarse-grained models in the long pathway connecting SAP sequences and hydrogel mechanical properties., Competing Interests: There are no conflicts of interest to declare., (This journal is © The Royal Society of Chemistry.)

Published

2019

84. Design Parameters of Tissue-Engineering Scaffolds at the Atomic Scale.

Author

Jekhmane S, Prachar M, Pugliese R, Fontana F, Medeiros-Silva J, Gelain F, and Weingarth M

Subjects

Humans, Microscopy, Atomic Force, Peptide Fragments chemistry, Biocompatible Materials chemistry, Extracellular Matrix, Nanofibers chemistry, Neural Stem Cells cytology, Regenerative Medicine, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Stem-cell behavior is regulated by the material properties of the surrounding extracellular matrix, which has important implications for the design of tissue-engineering scaffolds. However, our understanding of the material properties of stem-cell scaffolds is limited to nanoscopic-to-macroscopic length scales. Herein, a solid-state NMR approach is presented that provides atomic-scale information on complex stem-cell substrates at near physiological conditions and at natural isotope abundance. Using self-assembled peptidic scaffolds designed for nervous-tissue regeneration, we show at atomic scale how scaffold-assembly degree, mechanics, and homogeneity correlate with favorable stem cell behavior. Integration of solid-state NMR data with molecular dynamics simulations reveals a highly ordered fibrillar structure as the most favorable stem-cell scaffold. This could improve the design of tissue-engineering scaffolds and other self-assembled biomaterials., (© 2019 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2019

85. Multifunctionalized hydrogels foster hNSC maturation in 3D cultures and neural regeneration in spinal cord injuries.

Author

Marchini A, Raspa A, Pugliese R, El Malek MA, Pastori V, Lecchi M, Vescovi AL, and Gelain F

Subjects

Animals, Cholinergic Neurons metabolism, Cholinergic Neurons pathology, Disease Models, Animal, Female, Heterografts, Humans, Rats, Rats, Sprague-Dawley, Cell Differentiation, Cell Proliferation, Cells, Immobilized metabolism, Cells, Immobilized pathology, Cells, Immobilized transplantation, Hydrogels chemistry, Hydrogels pharmacology, Neural Stem Cells metabolism, Neural Stem Cells pathology, Neural Stem Cells transplantation, Regeneration, Spinal Cord Injuries metabolism, Spinal Cord Injuries pathology, Spinal Cord Injuries therapy

Abstract

Three-dimensional cell cultures are leading the way to the fabrication of tissue-like constructs useful to developmental biology and pharmaceutical screenings. However, their reproducibility and translational potential have been limited by biomaterial and culture media compositions, as well as cellular sources. We developed a construct comprising synthetic multifunctionalized hydrogels, serum-free media, and densely seeded good manufacturing practice protocol-grade human neural stem cells (hNSC). We tracked hNSC proliferation, differentiation, and maturation into GABAergic, glutamatergic, and cholinergic neurons, showing entangled electrically active neural networks. The neuroregenerative potential of the "engineered tissue" was assessed in spinal cord injuries, where hNSC-derived progenitors and predifferentiated hNSC progeny, embedded in multifunctionalized hydrogels, were implanted. All implants decreased astrogliosis and lowered the immune response, but scaffolds with predifferentiated hNSCs showed higher percentages of neuronal markers, better hNSC engraftment, and improved behavioral recovery. Our hNSC-construct enables the formation of 3D functional neuronal networks in vitro, allowing novel strategies for hNSC therapies in vivo., Competing Interests: Conflict of interest statement: F.G. and A.L.V. are inventors on the patent US9,273,101B2 “Functionalized biomaterials for tissue regeneration.” All other authors declare no competing interests., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

86. A Supramolecular Approach to Develop New Soybean and Lupin Peptide Nanogels with Enhanced Dipeptidyl Peptidase IV (DPP-IV) Inhibitory Activity.

Author

Pugliese R, Bollati C, Gelain F, Arnoldi A, and Lammi C

Subjects

Dipeptidyl Peptidase 4 chemistry, Dipeptidyl Peptidase 4 metabolism, Humans, Hydrolysis, Kinetics, Nanostructures chemistry, Tandem Mass Spectrometry, Dipeptidyl-Peptidase IV Inhibitors chemistry, Lupinus chemistry, Peptides chemistry, Glycine max chemistry

Abstract

Soy1 (IAVPTGVA) and Lup1 (LTFPGSAED), two peptides from soybean and lupin protein hydrolysis, have been singled out as dipeptidyl peptidase IV (DPP-IV) activity inhibitors in different model systems. However, their activity is affected by their instability toward intestinal proteases. Here, an innovative strategy based on nanogels was developed in order to increase both their stability and antidiabetic properties through encapsulation into the RADA16 peptide. The nanogel formation was stimulated by a solvent-triggered approach, allowing us to produce stable nanogels ( G' = 1826 Pa, stress-failure ≥50 Pa) with shear-thinning propensity. ThT binding assay, and ATR-FTIR spectroscopy experiments showed that nanogels self-aggregated into stable cross-β structures providing higher resistance against proteases (ex vivo experiments) and increased bioavailability of Soy1 and Lup1 peptides (in situ experiments on Caco-2 cells). Hence, this simple and harmless nanotechnological approach could be a key-step in making innovative nanomaterials for nutraceuticals delivering.

Published

2019

87. Enhancement of the Stability and Anti-DPPIV Activity of Hempseed Hydrolysates Through Self-Assembling Peptide-Based Hydrogels.

Author

Lammi C, Bollati C, Gelain F, Arnoldi A, and Pugliese R

Abstract

Although there is an increasing interest for bioactive food protein hydrolysates as valuable ingredients for functional food and dietary supplement formulations, their potential applications are hampered by their insufficient stability in physiological conditions. In this study, an innovative strategy based on nanomaterials was developed in order to increase the hempseed hydrolysate stability and the anti-diabetic properties, through their encapsulation into ionic self-complementary RADA16 peptide based-hydrogels. Atomic force microscope (AFM) morphological analysis indicated that the new nanomaterials were composed of a nanofibril network, whose increased diameter in respect to native RADA16 suggests the presence of transient non-covalent interactions among the RADA16 supramolecular assemblies and the embedded hempseed peptides. Structural analysis by FT-IR spectroscopy indicated typical β-sheet signatures. The RADA16-hempseed protein hydrolysate hydrogel was shown to act as a novel dipeptidyl peptidase IV (DPPIV) inhibitor in different biological assays. Finally, this nanoformulation was used as a drug delivery system of the anti-diabetic drug sitagliptin, helping to reduce its dosage and eventually associated side-effects.

Published

2019

88. Feasible stabilization of chondroitinase abc enables reduced astrogliosis in a chronic model of spinal cord injury.

Author

Raspa A, Bolla E, Cuscona C, and Gelain F

Subjects

Animals, Astrocytes enzymology, Astrocytes pathology, Cells, Cultured, Chondroitin ABC Lyase isolation & purification, Chondroitin ABC Lyase metabolism, Chronic Disease, Disease Models, Animal, Enzyme Stability drug effects, Gliosis enzymology, Gliosis pathology, Mice, Neural Stem Cells drug effects, Neural Stem Cells enzymology, Neural Stem Cells pathology, Neuroprotective Agents isolation & purification, Neuroprotective Agents metabolism, Proteus vulgaris enzymology, Random Allocation, Rats, Sprague-Dawley, Spinal Cord Injuries enzymology, Spinal Cord Injuries pathology, Spinal Cord Regeneration drug effects, Astrocytes drug effects, Chondroitin ABC Lyase pharmacology, Gliosis drug therapy, Neuroprotective Agents pharmacology, Spinal Cord Injuries drug therapy

Abstract

Aims: Usually, spinal cord injury (SCI) develops into a glial scar containing extracellular matrix molecules including chondroitin sulfate proteoglycans (CSPGs). Chondroitinase ABC (ChABC), from Proteus vulgaris degrading the glycosaminoglycan (GAG) side chains of CSPGs, offers the opportunity to improve the final outcome of SCI. However, ChABC usage is limited by its thermal instability, requiring protein structure modifications, consecutive injections at the lesion site, or implantation of infusion pumps., Methods: Aiming at more feasible strategy to preserve ChABC catalytic activity, we assessed various stabilizing agents in different solutions and demonstrated, via a spectrophotometric protocol, that the 2.5 mol/L Sucrose solution best stabilized ChABC as far as 14 days in vitro., Results: ChABC activity was improved in both stabilizing and diluted solutions at +37°C, that is, mimicking their usage in vivo. We also verified the safety of the proposed aqueous sucrose solution in terms of viability/cytotoxicity of mouse neural stem cells (NSCs) in both proliferating and differentiating conditions in vitro. Furthermore, we showed that a single intraspinal treatment with ChABC and sucrose reduced reactive gliosis at the injury site in chronic contusive SCI in rats and slightly enhanced their locomotor recovery., Conclusion: Usage of aqueous sucrose solutions may be a feasible strategy, in combination with rehabilitation, to ameliorate ChABC-based treatments to promote the regeneration of central nervous system injuries., (© 2018 John Wiley & Sons Ltd.)

Published

2019

89. Self-assembling peptides cross-linked with genipin: resilient hydrogels and self-standing electrospun scaffolds for tissue engineering applications.

Author

Pugliese R, Maleki M, Zuckermann RN, and Gelain F

Subjects

Biocompatible Materials chemistry, Cell Differentiation, Cell Line, Cell Proliferation, Humans, Models, Molecular, Nanofibers chemistry, Nanofibers ultrastructure, Cross-Linking Reagents chemistry, Hydrogels chemistry, Iridoids chemistry, Neural Stem Cells cytology, Peptides chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Self-assembling peptides (SAPs) are synthetic bioinspired biomaterials that can be feasibly multi-functionalized for applications in surgery, drug delivery, optics and tissue engineering (TE). Despite their promising biocompatibility and biomimetic properties, they have never been considered real competitors of polymers and/or cross-linked extracellular matrix (ECM) natural proteins. Indeed, synthetic SAP-made hydrogels usually feature modest mechanical properties, limiting their potential applications, due to the transient non-covalent interactions involved in the self-assembling phenomenon. Cross-linked SAP-hydrogels have been recently introduced to bridge this gap, but several questions remain open. New strategies leading to stiffer gels of SAPs may allow for a full exploitation of the SAP technology in TE and beyond. We have developed and characterized a genipin cross-linking strategy significantly increasing the stiffness and resiliency of FAQ(LDLK)3, a functionalized SAP already used for nervous cell cultures. We characterized different protocols of cross-linking, analyzing their dose and time-dependent efficiency, influencing stiffness, bioabsorption time and molecular arrangements. We choose the best developed protocol to electrospin into nanofibers, for the first time, self-standing, water-stable and flexible fibrous mats and micro-channels entirely made of SAPs. This work may open the door to the development and tailoring of bioprostheses entirely made of SAPs for different TE applications.

Published

2018

90. Branched peptides integrate into self-assembled nanostructures and enhance biomechanics of peptidic hydrogels.

Author

Pugliese R, Fontana F, Marchini A, and Gelain F

Subjects

Amino Acid Sequence, Biomechanical Phenomena, Cell Differentiation, Cell Survival, Cells, Cultured, Humans, Molecular Dynamics Simulation, Neural Stem Cells cytology, Protein Structure, Secondary, Rheology, Spectroscopy, Fourier Transform Infrared, Hydrogels chemistry, Nanostructures chemistry, Peptides chemistry

Abstract

Self-assembling peptides (SAP) have drawn an increasing interest in the tissue engineering community. They display unquestionable biomimetic properties, tailorability and promising biocompatibility. However their use has been hampered by poor mechanical properties making them fragile soft scaffolds. To increase SAP hydrogel stiffness we introduced a novel strategy based on multiple ramifications of (LDLK) 3 , a well-known linear SAP, connected with one or multiple "lysine knots". Differently branched SAPs were tested by increasing the number of (LDLK) 3 -like branches and by adding the neuro-regenerative functional motif BMHP1 as a single branch. While pure branched peptides did not have appealing self-assembling propensity, when mixed with the corresponding linear SAP they increased the stiffness of the overall hydrogel of multiple times. Notably, optimal results (or peak) were obtained 1) at similar molar ratio (between linear and branched peptides) for all tested sequences and 2) for the branched SAPs featuring the highest number of branches made of (LDLK) 3 . The functional motif BMHP1, as expected, seemed not to contribute to the increase of the storage modulus as efficiently as (LDLK) 3 . Interestingly, branched SAPs improved the β-sheet self-arrangement of (LDLK) 3 and allowed for the formation of assembled nanofibers. Indeed in coarse-grained molecular dynamics we showed they readily integrate in the assembled aggregates providing "molecular connections" among otherwise weakly paired β-structures. Lastly, branched SAPs did not affect the usual response of human neural stem cells cultured on (LDLK) 3 -like scaffolds in vitro. Hence, branched SAPs may be a valuable new tool to enhance mechanical properties of self-assembling peptide biomaterials harmlessly; as neither chemical nor enzymatic cross-linking reactions are involved. As a consequence, branched SAPs may enlarge the field of application of SAPs in tissue engineering and beyond., Statement of Significance: Self-assembling peptides stand at the forefront of regenerative medicine because they feature biomimetic nano-architectures that mimic the complexity of natural peptide-based extracellular matrices of living tissues. Their superior biocompatibility and ease of scale-up production are hampered by weak mechanical properties due to transient non-covalent interactions among and within the self-assembled peptide chains, thus limiting their potential applications. We introduced new branched self-assembling peptides to be used as "molecular connectors" among self-assembled nanostructures made of linear SAPs. Branched SAPs could be mixed with linear SAPs before self-assembling in order to have them intermingled with different β-sheets of linear SAPs after gelation. This strategy caused a manifold increase of the stiffness of the assembled hydrogels (proportional to the number of self-assembling branches), did not affect SAP propensity to form β-sheet but, instead, further stimulated their secondary structure rearrangements. It is now possible to modularly improve SAP scaffold mechanical properties without using harmful chemical reactions. Therefore, branched SAPs represent an additional tool to be adopted for efficient and harmless SAP scaffold customization in tissue engineering., (Copyright © 2017 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2018

91. Fabrication of nanofibrous electrospun scaffolds from a heterogeneous library of co- and self-assembling peptides.

Author

Maleki M, Natalello A, Pugliese R, and Gelain F

Subjects

Amino Acid Sequence, Biotin chemistry, Nanofibers ultrastructure, Peptides chemical synthesis, Protein Structure, Secondary, Solvents, Nanofibers chemistry, Peptide Library, Peptides chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Self-assembling (SAPs) and co-assembling peptides (CAPs) are driving increasing enthusiasm as synthetic but biologically inspired biomaterials amenable of easy functionalization for regenerative medicine. On the other hand, electrospinning (ES) is a versatile technique useful for tailoring the nanostructures of various biomaterials into scaffolds resembling the extracellular matrices found in organs and tissues. The synergistic merging of these two approaches is a long-awaited advance in nanomedicine that has not been deeply documented so far. In the present work, we describe the successful ES of a library of diverse SAPs and CAPs into biomimetic nanofibrous mats. Our results suggest that suitable ES solutions are characterized by high concentrations of peptides, providing backbone physical chain entanglements, and by random coil/α-helical conformations while β-sheet aggregation may be detrimental to spinnability. The resulting peptide fibers feature interconnected seamless mats with nanofibers average diameters ranging from ∼100nm to ∼400nm. Also, peptide chemical nature and ES set up parameters play pivotal roles in determining the conformational transitions and morphological properties of the produced nanofibers. Far from being an exhaustive description of the just-opened novel field of ES-assembled peptides, this seminal work aims at shining a light on a still missing general theory for the production of electrospun peptidic biomaterials bringing together the spatial, biochemical and biomimetic of these two techniques into unique scaffolds for tissue engineering., Statement of Significance: Construction of peptide hydrogels has received considerable attention due to their potential as nanostructures amenable of easy functionalization and capable of creating microenvironments suited for culturing cells and triggering tissue regeneration. They display a superior biocompatibility unmatched by other known synthetic biomaterials so far. However, their applications are confined to body fillers because most of them do spontaneously form hydrogels, while effective tissue regeneration often requires well-defined fibrous scaffolds. In this work, we developed electrospun fibers of various peptides (cross-beta self-assembling, hierarchically assembling, functionalized, co-assembling) and we provided a deep understanding of the crucial phenomena to be taken into account when peptides fibers fabrication. These results open new venues for exploring novel regenerative applications of peptide nanofibrous scaffolds., (Copyright © 2017 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2017

92. Peptidic Biomaterials: From Self-Assembling to Regenerative Medicine.

Author

Pugliese R and Gelain F

Subjects

Nanocapsules ultrastructure, Protein Binding, Biomimetic Materials chemistry, Extracellular Matrix chemistry, Nanocapsules chemistry, Peptides chemistry, Tissue Engineering instrumentation, Tissue Engineering methods, Tissue Scaffolds

Abstract

Peptidic biomaterials represent a particularly exciting topic in regenerative medicine. Peptidic scaffolds can be specifically designed for biomimetic customization for targeted therapy. The field is at a pivotal point where preclinical research is being translated into clinics, so it is crucial to understand the theory and describe the status of this rapidly developing technology. In this review, we highlight major advantages and current limitations of self-assembling peptide-based biomaterials, and we discuss the most widely used classes of assembling peptides, describing recent and promising approaches in tissue engineering, drug delivery, and clinics. We also suggest design strategies and hurdles that still need to be overcome to fully exploit their therapeutic potential., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2017

93. Recent therapeutic approaches for spinal cord injury.

Author

Raspa A, Pugliese R, Maleki M, and Gelain F

Subjects

Clinical Trials as Topic, Guided Tissue Regeneration methods, Guided Tissue Regeneration trends, Humans, Regenerative Medicine trends, Regenerative Medicine methods, Spinal Cord Injuries therapy, Spinal Cord Regeneration

Abstract

A spinal cord injury (SCI) often causes permanent changes in strength and sensation functions below the site of the injury and affects thousands of people each year. Transplantation of stem cells is a promising approach in acute SCI as it may support spinal cord repair. However, in case of chronic SCI greater amounts of nervous tissue have to be regenerated, leaving scaffold transplantation the only feasible option for cellular engraftment and nervous bridging. The aim of regenerative medicine, specifically tissue engineering, is to create a microenvironment that mimics native extracellular matrix (ECM), capable of promoting specific cell-matrix interactions, coaxing cell behavior, and fostering host tissue regeneration. In this regard, nanostructured scaffolds are currently the most promising advanced substrates capable of supporting nervous fiber ingrowth and delivery of neurotrophic drugs. Among them, electrospinning technique and Self-Assembling Peptides (SAPs) have recently attracted lots of attention for their reproducible synthesis and high tailorability. This review highlights clinical trials and recent encouraging strategies for spinal cord repair comprising both cell therapy and nanomedicine., (© 2015 Wiley Periodicals, Inc.)

Published

2016

94. Designer self-assembling hydrogel scaffolds can impact skin cell proliferation and migration.

Author

Bradshaw M, Ho D, Fear MW, Gelain F, Wood FM, and Iyer KS

Subjects

Animals, Cell Line, Cell Movement drug effects, Cell Proliferation drug effects, Fibroblasts cytology, Fibroblasts physiology, Humans, Hydrogels chemistry, Keratinocytes cytology, Keratinocytes physiology, Mice, Models, Biological, NIH 3T3 Cells, Nanofibers chemistry, Nanofibers ultrastructure, Peptides chemical synthesis, Structure-Activity Relationship, Wound Healing physiology, Fibroblasts drug effects, Hydrogels pharmacology, Keratinocytes drug effects, Peptides pharmacology, Tissue Scaffolds

Abstract

There is a need to develop economical, efficient and widely available therapeutic approaches to enhance the rate of skin wound healing. The optimal outcome of wound healing is restoration to the pre-wound quality of health. In this study we investigate the cellular response to biological stimuli using functionalized nanofibers from the self-assembling peptide, RADA16. We demonstrate that adding different functional motifs to the RADA16 base peptide can influence the rate of proliferation and migration of keratinocytes and dermal fibroblasts. Relative to unmodified RADA16; the Collagen I motif significantly promotes cell migration, and reduces proliferation.

Published

2014

95. Evaluation of mechanical properties and therapeutic effect of injectable self-assembling hydrogels for spinal cord injury.

Author

Cigognini D, Silva D, Paloppi S, and Gelain F

Subjects

Animals, Axons pathology, Biotinylation, Diffusion, Female, Hematoma pathology, Hematoma physiopathology, Hindlimb physiopathology, Injections, Macrophages pathology, Microscopy, Atomic Force, Motor Activity, Peptides therapeutic use, Rats, Rats, Sprague-Dawley, Recovery of Function, Rheology, Solutions, Spinal Cord pathology, Spinal Cord Injuries pathology, Spinal Cord Injuries physiopathology, Streptavidin metabolism, Tissue Scaffolds chemistry, Viscosity, Hydrogels administration & dosage, Hydrogels therapeutic use, Materials Testing, Mechanical Phenomena, Spinal Cord Injuries therapy

Abstract

Self-assembling peptides are promising biomaterials for spinal cord repair as they can easily be injected into the lesion site and can provide physical support to regrowing nervous tissue. However, to improve upon the design of synthetic scaffolds for spinal cord injury, characteristics of the scaffold/host relationship need to be further investigated. In the current study we aimed to evaluate both the mechanical properties and the therapeutic effect of two self-assembling peptides B24 and biotin-LDLK12 in spinal cord injury. Atomic force microscopy and rheology were used to characterise various concentrations of the two peptides in terms of the propensity to form nanostructures and the viscoelastic properties. Concurrently, these peptide solutions were injected into the contused spinal cord of rats to evaluate both diffusibility within the tissue, and scaffold formation in vivo. After selection of the best concentration for delivery in vivo, the two self-assembling peptides were tested in the contused spinal cord of rats for their influence on hematoma and cyst formation, biocompatibility and permissiveness for axonal growth. The results suggest that rheology can provide a useful indication to predict the hydrogel formation and diffusibility of the self-assembling peptides in vivo. Moreover at three days post-injury both self-assembling peptides had a good hemostatic effect and at 28 days they improved axon regrowth. In summary, the injectable self-assembling hydrogels could attenuate hematoma and provide a therapeutic effect in a spinal cord injury model.

Published

2014

96. Modelling and analysis of early aggregation events of BMHP1-derived self-assembling peptides.

Author

Saracino GA and Gelain F

Subjects

Biotinylation, Hydrogen Bonding, Hydrophobic and Hydrophilic Interactions, Protein Conformation, Protein Folding, Acyltransferases chemistry, Molecular Dynamics Simulation, Peptides chemistry

Abstract

Despite the increasing use and development of peptide-based scaffolds in different fields including that of regenerative medicine, the understanding of the factors governing the self-assembly process and the relationship between sequence and properties have not yet been fully understood. BMHP1-derived self-assembling peptides (SAPs) have been developed and characterized showing that biotinylation at the N-terminal cap corresponds to better performing assembly and scaffold biomechanics. In this study, the effects of biotinylation on the self-assembly dynamics of seven BMHP1-derived SAPs have been investigated by molecular dynamics simulations. We confirmed that these SAPs self-assemble into β-structures and that proline acts as a β-breaker of the assembled aggregates. In biotinylated peptides, the formation of ordered β-structured aggregates is triggered by both the establishment of a dense and dynamic H-bonds network and the formation of a 'hydrophobic wall' available to interact with other peptides. Such conditions result from the peculiar chemical composition of the biotinyl-cap, given by the synergic cooperation of the uracil function of the ureido ring with the high hydrophobic portion consisting of the thiophenyl ring and valeryl chain. The inbuilt propensity of biotinylated peptides towards the formation of ordered small aggregates makes them ideal precursors of higher hierarchically organized self-assembled nanostructures as experimentally observed.

Published

2014

97. A novel bioactive peptide: assessing its activity over murine neural stem cells and its potential for neural tissue engineering.

Author

Caprini A, Silva D, Zanoni I, Cunha C, Volontè C, Vescovi A, and Gelain F

Subjects

Amino Acid Sequence, Animals, Cells, Cultured, Humans, Mice, Neural Stem Cells cytology, Neurons cytology, Cell Differentiation drug effects, Neural Stem Cells metabolism, Neurons metabolism, Peptide Library, Tissue Engineering

Abstract

The design of biomimetic scaffolds suitable for cell-based therapies is a fundamental step for the regeneration of the damaged nervous system; indeed growing interest is focusing on the discovery of peptide sequences to modulate the fate of transplanted cells and, in particular, the differentiation outcome of multipotent neural stem cells. By applying the Phage Display technique to murine neural stem cells we isolated a peptide, KLPGWSG, present in proteins involved in both stem cell maintenance and differentiation. We show that KLPGWSG binds molecules expressed on the cell surface of murine adult neural stem cells, thus may potentially be involved in stem cell fate determination. Indeed we demonstrated that this peptide in solution enhances per se cell differentiation toward the neuronal phenotype. Hence, we synthesized two LDLK-12-based self-assembling peptides functionalized with KLPGWSG peptide (KLP and Ac-KLP) and characterized them via atomic force microscopy, rheometry and circular dichroism, obtaining nanostructured hydrogels supporting murine neural stem cells differentiation in vitro. Interestingly, we demonstrated that, when scaffold stiffness is comparable to that of the brain in vivo, the Ac-KLP SAP-based scaffold enhances the neuronal differentiation of neural stem cells. These evidences place both KLPGWSG and the functionalized self-assembling peptide Ac-KLP as promising candidates for, respectively, biomimetic studies and stem cell therapies for nervous regeneration., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2013

98. Synthesis and characterization of designed BMHP1-derived self-assembling peptides for tissue engineering applications.

Author

Silva D, Natalello A, Sanii B, Vasita R, Saracino G, Zuckermann RN, Doglia SM, and Gelain F

Subjects

Amino Acid Sequence, Animals, Cell Adhesion, Cell Proliferation, Extracellular Matrix metabolism, Hydrogels chemistry, Hydrogen Bonding, Kinetics, Materials Testing, Mice, Microscopy, Atomic Force methods, Molecular Sequence Data, Nanofibers chemistry, Neural Stem Cells cytology, Protein Structure, Secondary, Rheology methods, Spectroscopy, Fourier Transform Infrared methods, X-Ray Diffraction, Bone Marrow metabolism, Oligopeptides chemistry, Peptides chemistry, Regenerative Medicine methods, Tissue Engineering methods

Abstract

The importance of self-assembling peptides (SAPs) in regenerative medicine is becoming increasingly recognized. The propensity of SAPs to form nanostructured fibers is governed by multiple forces including hydrogen bonds, hydrophobic interactions and π-π aromatic interactions among side chains of the amino acids. Single residue modifications in SAP sequences can significantly affect these forces. BMHP1-derived SAPs is a class of biotinylated oligopeptides, which self-assemble in β-structured fibers to form a self-healing hydrogel. In the current study, selected modifications in previously described BMHP1-derived SAPs were designed in order to investigate the influence of modified residues on self-assembly kinetics and scaffold formation properties. The Fourier transform infrared spectroscopy (FTIR) and X-ray diffraction (XRD) analysis demonstrated the secondary structure (β-sheet) formation in all modified SAP sequences, whereas atomic force microscopy (AFM) analysis further confirmed the presence of nanofibers. Furthermore, the fiber shape and dimension analysis by AFM showed flattened and twisted fiber morphology ranging from ∼8 nm to ∼70 nm. The mechanical properties of the pre-assembled and post assembled solution were investigated by rheometry. The shear-thinning behavior and rapid re-healing properties of the pre-assembled solutions make them a preferable choice for injectable scaffolds. The wide range of stiffnesses (G')--from ∼1000 to ∼27,000 Pa--exhibited by the post-assembled scaffolds demonstrated their potential for a variety of tissue engineering applications. The extra cellular matrix (ECM) mimicking (physically and chemically) properties of SAP scaffolds enhanced cell adhesion and proliferation. The capability of the scaffold to facilitate murine neural stem cell (mNSC) proliferation was evaluated in vitro: the increased mNSCs adhesion and proliferation demonstrated the potential of newly synthesized SAPs for regenerative medicine approaches.

Published

2013

99. Nanomaterials design and tests for neural tissue engineering.

Author

Saracino GA, Cigognini D, Silva D, Caprini A, and Gelain F

Subjects

Humans, Hydrogels chemistry, Polymers chemistry, Synthetic Biology, Nanostructures chemistry, Nerve Tissue chemistry, Tissue Engineering

Abstract

Nanostructured scaffolds recently showed great promise in tissue engineering: nanomaterials can be tailored at the molecular level and scaffold morphology may more closely resemble features of extracellular matrix components in terms of porosity, framing and biofunctionalities. As a consequence, both biomechanical properties of scaffold microenvironments and biomaterial-protein interactions can be tuned, allowing for improved transplanted cell engraftment and better controlled diffusion of drugs. Easier said than done, a nanotech-based regenerative approach encompasses different fields of know-how, ranging from in silico simulations, nanomaterial synthesis and characterization at the nano-, micro- and mesoscales to random library screening methods (e.g. phage display), in vitro cellular-based experiments and validation in animal models of the target injury. All of these steps of the "assembly line" of nanostructured scaffolds are tightly interconnected both in their standard analysis techniques and in their most recent breakthroughs: indeed their efforts have to jointly provide the deepest possible analyses of the diverse facets of the challenging field of neural tissue engineering. The purpose of this review is therefore to provide a critical overview of the recent advances in and drawbacks and potential of each mentioned field, contributing to the realization of effective nanotech-based therapies for the regeneration of peripheral nerve transections, spinal cord injuries and brain traumatic injuries. Far from being the ultimate overview of such a number of topics, the reader will acknowledge the intrinsic complexity of the goal of nanotech tissue engineering for a conscious approach to the development of a regenerative therapy and, by deciphering the thread connecting all steps of the research, will gain the necessary view of its tremendous potential if each piece of stone is correctly placed to work synergically in this impressive mosaic.

Published

2013

100. Engineering of a 3D nanostructured scaffold made of functionalized self-assembling peptides and encapsulated neural stem cells.

Author

Cunha C, Panseri S, and Gelain F

Subjects

Adult Stem Cells cytology, Animals, Biocompatible Materials chemistry, Mice, Cell Culture Techniques, Nanostructures chemistry, Neural Stem Cells cytology, Peptides chemistry, Tissue Scaffolds chemistry

Abstract

Three-dimensional (3D) in vitro models of cell culture aim to fill the gap between the standard 2D cell studies and the in vivo environment. Especially for neural tissue regeneration approaches where there is little regenerative capacity, such models must rely on scaffolds that mimic the extracellular matrix in providing support; allowing the natural flow of oxygen, nutrients, and growth factors; and possibly favoring neural cell regrowth. Their combined use with stem cells has many potentialities for tissue engineering applications. Here, we describe a new 3D model of stem cell culture, using a nanostructured biomaterial, made of self-assembling peptides, where adult neural stem cells are completely embedded. This new 3D cell culture system takes advantage of the nano- and microfiber assembling process of these biomaterials under physiological conditions. The assembled scaffold forms an intricate and biologically active matrix able to display specifically designed functional motifs such as RGD, BMHP1, and BMHP2. Such model has the potential to be tailored to develop ad hoc designed peptides for specific cell lines.

Published

2013