Protein based biomaterials for therapeutic and diagnostic applications

Chu, Stanley; Wang, Andrew L; Bhattacharya, Aparajita; Montclare, Jin Kim

doi:10.1088/2516-1091/ac2841

Cited by 16 publications

(12 citation statements)

References 248 publications

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“…In addition to their central importance to the molecular basis of life processes, protein- and peptide-based systems have a wide range of applications to therapeutics, − food, − catalysts, − as well as nanoscale and macroscale materials. − Given that structure and function can often be encoded in the sequence of the amino acids, targeted properties can in principle be achieved via careful selection of sequences, solution conditions, and processing. Peptides have been used to engineer a wide range of assemblies, including nanotubes, nanosheets, nanolattices, and polymers of peptide building blocks. − The structure, functionality, and aggregation of proteins are a result of multiple noncovalent interactions, including electrostatic effects, hydrogen bonding, and hydrophobic interactions.…”

Section: Introductionmentioning

confidence: 99%

Computational Design of Homotetrameric Peptide Bundle Variants Spanning a Wide Range of Charge States

et al. 2022

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With the ability to design their sequences and structures, peptides can be engineered to realize a wide variety of functionalities and structures. Herein, computational design was used to identify a set of 17 peptides having a wide range of putative charge states but the same tetrameric coiled-coil bundle structure. Calculations were performed to identify suitable locations for ionizable residues (D, E, K, and R) at the bundle's exterior sites, while interior hydrophobic interactions were retained. The designed bundle structures spanned putative charge states of −32 to +32 in units of electron charge. The peptides were experimentally investigated using spectroscopic and scattering techniques. Thermal stabilities of the bundles were investigated using circular dichroism. Molecular dynamics simulations assessed structural fluctuations within the bundles. The cylindrical peptide bundles, 4 nm long by 2 nm in diameter, were covalently linked to form rigid, micron-scale polymers and characterized using transmission electron microscopy. The designed suite of sequences provides a set of readily realized nanometer-scale structures of tunable charge that can also be polymerized to yield rigid-rod polyelectrolytes.

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Section: Introductionmentioning

confidence: 99%

Computational Design of Homotetrameric Peptide Bundle Variants Spanning a Wide Range of Charge States

et al. 2022

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“…Though protein therapies are highly favored by researchers, they still face a hindering obstacle on the road toward clinical translation: efficient and targeted delivery mechanics. In nearly all cases, such therapies succeed because they both protect the protein's structure from degradation in order to ensure the protein's efficacy and simultaneously interact specifically with the corresponding target site in the body [2,24,125]. Although protein-based therapeutics show a high specificity at much lower concentrations than small-molecule drugs, integrating biomaterials into these therapeutic systems can help in overcoming difficulties through efficient and targeted delivery [8,126].…”

Section: Efficient and Targeted Delivery: The Core Challengementioning

confidence: 99%

Biomaterials for Protein Delivery: Opportunities and Challenges to Clinical Translation

Gorantla,

Hall,

Troidle

et al. 2024

Micromachines

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The development of biomaterials for protein delivery is an emerging field that spans materials science, bioengineering, and medicine. In this review, we highlight the immense potential of protein-delivering biomaterials as therapeutic options and discuss the multifaceted challenges inherent to the field. We address current advancements and approaches in protein delivery that leverage stimuli-responsive materials, harness advanced fabrication techniques like 3D printing, and integrate nanotechnologies for greater targeting and improved stability, efficacy, and tolerability profiles. We also discuss the demand for highly complex delivery systems to maintain structural integrity and functionality of the protein payload. Finally, we discuss barriers to clinical translation, such as biocompatibility, immunogenicity, achieving reliable controlled release, efficient and targeted delivery, stability issues, scalability of production, and navigating the regulatory landscape for such materials. Overall, this review summarizes insights from a survey of the current literature and sheds light on the interplay between innovation and the practical implementation of biomaterials for protein delivery.

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“…The bioavailability of drug candidates is often the largest barrier from clinical translation as issues of solubility, aggregation, degradation, cell-membrane penetration, and clearance often necessitate a carrier molecule to protect and escort drug payloads to their targeted sites [ 79 ]. Accordingly, selection criteria for drug-delivering protein or peptide materials share many similarities with those employed for therapeutic use including easy administration, good pharmacokinetics and dynamics, and minimization of off-target effects; however, essential characteristics tend to be more flexible since the vehicle does not need to be intrinsically medicinal in nature [ 80 ]. This is often preferred so as not to confer unintended compounding effects.…”

Section: Drug Deliverymentioning

confidence: 99%

Fluorinated Protein and Peptide Materials for Biomedical Applications

et al. 2022

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Fluorination represents one of the most powerful modern design strategies to impart biomacromolecules with unique functionality, empowering them for widespread application in the biomedical realm. However, the properties of fluorinated protein materials remain unpredictable due to the heavy context-dependency of the surrounding atoms influenced by fluorine’s strong electron-withdrawing tendencies. This review aims to discern patterns and elucidate design principles governing the biochemical synthesis and rational installation of fluorine into protein and peptide sequences for diverse biomedical applications. Several case studies are presented to deconvolute the overgeneralized fluorous stabilization effect and critically examine the duplicitous nature of the resultant enhanced chemical and thermostability as it applies to use as biomimetic therapeutics, drug delivery vehicles, and bioimaging modalities.

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Protein based biomaterials for therapeutic and diagnostic applications

Cited by 16 publications

References 248 publications

Computational Design of Homotetrameric Peptide Bundle Variants Spanning a Wide Range of Charge States

Computational Design of Homotetrameric Peptide Bundle Variants Spanning a Wide Range of Charge States

Biomaterials for Protein Delivery: Opportunities and Challenges to Clinical Translation

Fluorinated Protein and Peptide Materials for Biomedical Applications

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