2022
DOI: 10.1016/j.mtchem.2022.100808
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Virus-like particles: a self-assembled toolbox for cancer therapy

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Cited by 12 publications
(13 citation statements)
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“…Cationic nanoparticles tend to induce higher cellular internalization in comparison with negatively or neutrally charged nanoparticles, which may attribute to the electrostatic interaction between nanoparticles and anionic cell membrane lipid bilayer. VLPs with positive surface charge shield their negatively charged cargo such as nucleic acid, and can be readily taken up by cells [28]. However, acute inflammation and nonspecific immune stimulation are associated with positively charged nanoparticles, as they may activate the pattern-recognition receptors [29,30].…”
Section: Surface Chargementioning
confidence: 99%
“…Cationic nanoparticles tend to induce higher cellular internalization in comparison with negatively or neutrally charged nanoparticles, which may attribute to the electrostatic interaction between nanoparticles and anionic cell membrane lipid bilayer. VLPs with positive surface charge shield their negatively charged cargo such as nucleic acid, and can be readily taken up by cells [28]. However, acute inflammation and nonspecific immune stimulation are associated with positively charged nanoparticles, as they may activate the pattern-recognition receptors [29,30].…”
Section: Surface Chargementioning
confidence: 99%
“…(Lee et al, 2018) They are also popular vaccine candidates, as many of these proteinaceous materials are intrinsically immunogenic and can elicit potent humoral and cellmediated immune responses. (Luzuriaga et al, 2021;Shahrivarkevishahi et al, 2022; Compared to other commonly used nanoparticles such as liposomes, lipid-based nanoparticles, and dendrimers, many VLPs allow orthogonal surface modifications to install more than one new chemical moiety. (Benjamin et al, 2020b;Shahrivarkevishahi et al, 2021) For instance, drug delivery components can be installed via a single set of reactions, and stealth PEG coatings that promote solubility can orthogonally be attached to the same VLP via a second reaction.…”
Section: Virus-like Particlesmentioning
confidence: 99%
“…(Benjamin et al, 2020a) Bioconjugation strategies have recently gained much attention, as they can be used for tailoring VLPs and VNPs to perform specific functions such as imaging, cellular trafficking, and targeted drug delivery. (Shahrivarkevishahi et al, 2022) Though convenient, these reactions are not simple to execute in cases where the availability of exposed amino acids is limited, resulting in reduced efficiency of bioconjugation. (Hermanson, 2013) Figure 4 highlights some approaches to decorate the surface-exposed amino acids found in VLPs and viruses.…”
Section: Post-synthetic Modifications Of Vlps and Virusesmentioning
confidence: 99%
“…The structure of most VLPs is known to atomistic detail, and their exposed surfaces can be functionalized using high-yielding bioconjugation chemistry. In particular, VLP Qβthe crystal structure displayed in Figure Ahas been used extensively as a proteinaceous nanocarrier, as its well-understood surface chemistry, minimal toxicity, and low reactogenicity have made it an ideal biodegradable delivery platform . Qβ is an icosahedral VLP comprised of 180 coat proteins connected through disulfide bonds (Figure A yellow residues) with four solvent-exposed primary amine residues from lysine (Figure A green residues), which have been chemically modified for use in multiple biomedical applications, including contrast agents, photothermal scaffolds, and drug carriers. …”
Section: Introductionmentioning
confidence: 99%