Cross-linker-Modulated Nanogel Flexibility Correlates with Tunable Targeting to a Sterically Impeded Endothelial Marker

Myerson, Jacob W.; Mcpherson, Olivia; DeFrates, Kelsey G.; Towslee, Jenna H; Marcos‐Contreras, Oscar A.; Shuvaev, Vladimir V.; Braender, Bruce; Composto, Russell J.; Muzykantov, Vladimir R.; Eckmann, David M.

doi:10.1021/acsnano.9b04789

Cited by 30 publications

(25 citation statements)

References 54 publications

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“…2c). This observation agrees with those reported in earlier experimental studies 36 for in-vivo retention of ICAM-targeted flexible NPs in mouse lungs (inset of Fig. 2c and Supplementary Fig.…”

Section: Free Energy Analysissupporting

confidence: 93%

Biophysical Considerations in the Rational Design and Cellular Targeting of Flexible Polymeric Nanoparticles

Farokhirad

Kandy

Tsourkas

et al. 2021

Preprint

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It is becoming evident that engineered physicochemical characteristics of nanoparticles (NPs) are essential to improve their biological function for their cellular delivery and uptake. How NP mechanical properties impact multivalent ligand-receptor mediated binding to cell surfaces, the avidity of NP adhesion to cells, and cooperative effects due to crowding remain largely unknown or unquantified, and how tuning NPs' stiffness impacts their propensity for internalization is not clear. Here we focus on exploring the binding mechanisms of three distinct NPs that differ in type and rigidity (core-corona flexible NP, rigid NP, and rigid-tethered NP) but are otherwise similar in size and ligand surface density; moreover, for the case of flexible NP, we tune NP stiffness by varying the internal crosslinking density. We employed our recent spatial biophysical modeling of NP binding to membranes together with thermodynamic analysis powered by free energy calculations and show that efficient cellular targeting and uptake of NP functionalized with targeting ligand molecules can be shaped by factors including NP flexibility and crowding, receptor-ligand binding avidity, state of the membrane cytoskeleton, and curvature inducing proteins. Owing to this multitude of factors, we demonstrate that the binding avidity of a flexible NP depends on engineered changes in NP flexibility in a non-intuitive fashion because of significant enthalpy entropy compensations arising from multiple competing terms associated with NP, receptor density, and membrane. Analyses of the individual enthalpic and entropic contributions associated with NP, membrane, and receptor-ligand binding and receptor diffusion collectively illuminate this complex dependence of avidity on crosslinking. We find that the NP binding avidity can be engineered in a crowded environment by tuning their flexibility. We also find that when the cell membrane is bound to the cytoskeletal proteins via the pinning sites, the pinning sites' presence does not limit the binding avidity of both flexible and rigid-tethered NPs. Furthermore, we show that the membrane tension and pinning density, and the stiffness of flexible NPs can be tuned to alter the adhesion energy landscape and eventually improve the adhesion efficiency of flexible NPs. We also probed the effects of curvature-inducing proteins and receptor-ligand binding interactions on NP uptake. We found that complete uptake of both rigid-tethered NPs, and flexible NPs can be achieved by tuning NP stiffness and membrane tension even under moderate levels of ligand-densities in use for physiologically relevant applications. These findings provide strong evidence that NP flexibility is an important design parameter for rationally engineering NP targeting and uptake in a crowded cellular adhesion microenvironment.

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Section: Free Energy Analysissupporting

confidence: 93%

Biophysical Considerations in the Rational Design and Cellular Targeting of Flexible Polymeric Nanoparticles

Farokhirad

Kandy

Tsourkas

et al. 2021

Preprint

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“…Owing to competing enthalpic and entropic terms, there is no obvious systematic trend in how the total free energy of a flexible NP interacting with the cell membrane depends on the engineered changes in NP flexibility due to crosslinking (Figure 2c). This observation agrees with those reported in earlier experimental studies [36] on linking the flexibility of nanogels to the in vivo retention of ICAM-targeted nanogels in mouse lungs (Figure S2b, Supporting Information). It must be noted that the in vivo DAD crosslinker in Figure S2b (Supporting Information) represent a flexible NP with the highest crosslinking density.…”

Section: Free Energy Analysissupporting

confidence: 92%

Biophysical Considerations in the Rational Design and Cellular Targeting of Flexible Polymeric Nanoparticles

Farokhirad

Kandy

Tsourkas

et al. 2021

Adv Materials Inter

Self Cite

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gene therapy [1][2][3] and their application as biomarkers for imaging and detection. [4][5][6] Functional nanoparticles are finding applications in genome editing, immune modulation, cell therapies, and molecular diagnostics to stratify patients based on biomarkers. However, the functional NPs' design, optimization, and deployment are hampered by our lack of understanding of their biological barriers and pharmacokinetics. [7] While such barriers have contributions that are systemic and span multiple scales, the specificity for a given application has essential contributions from the cellular scale. Cellular targeting is governed by avidity (adhesion) and uptake (internalization), which depend on the properties of the NPs and the cellular microenvironment.Adhesion between an NP and a cell surface typically involves the simultaneous binding [8,9] of many hundreds of ligands on the NP's surface to a similar number of receptors on the cell surface. [9][10][11][12][13] The physiological outcome of such multivalent adhesion, which can mediate diverse phenomena, including cell crowding and cell uptake, [14] depends on the strength of ligandreceptor binding interactions. Other factors that can modulate multivalent adhesion strength include physiochemical properties of both the NPs and the cell surfaces. [15] Previous How nanoparticle (NP) mechanical properties impact multivalent ligandreceptor-mediated binding to cell surfaces, the avidity, propensity for internalization, and effects due to crowding remains unknown or unquantified. Through computational analyses, the effects of NP composition from soft, deformable NPs to rigid spheres, effect of tethers, the crowding of NPs at the membrane surface, and the cell membrane properties such as cytoskeletal interactions are addressed. Analyses of binding mechanisms of three distinct NPs that differ in type and rigidity (core-corona flexible NP, rigid NP, and rigid-tethered NP) but are otherwise similar in size and ligand surface density are reported; moreover, for the case of flexible NP, NP stiffness is tuned by varying the internal crosslinking density. Biophysical modeling of NP binding to membranes together with thermodynamic analysis powered by free energy calculations is employed, and it is shown that efficient cellular targeting and uptake of NP functionalized with targeting ligand molecules can be shaped by factors including NP flexibility and crowding, receptor-ligand binding avidity, state of the membrane cytoskeleton, and curvature inducing proteins. Rational design principles that confer tension, membrane excess area, and cytoskeletal sensing properties to the NP which can be exploited for cellspecific targeting of NP are uncovered.

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“…However, obstacles also exist for the clinical translation of nanogels. For example, when deformity occurs, their previously advantageous properties such as their swellability, drug loading capacity, and affinity target adhesion can be largely affected [67]. Constant efforts are also being made to optimize their biodistribution, to avoid their fast clearance, to minimize the toxicity caused by the surface charge, and to gain better control of targeted drug release and the degradation of nanogels [64,65].…”

Section: Nanogelsmentioning

confidence: 99%

“…Constant efforts are also being made to optimize their biodistribution, to avoid their fast clearance, to minimize the toxicity caused by the surface charge, and to gain better control of targeted drug release and the degradation of nanogels [64,65]. Working towards these goals, recently, Myerson et al developed a cross-linker modulated nanogel tunable in shape and equipped with antibodies specific to endothelial markers for improved targeted drug delivery [67].…”

Section: Nanogelsmentioning

confidence: 99%

Recent Advances in Nanocarrier-Assisted Therapeutics Delivery Systems

Kang

2020

Pharmaceutics

145

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Nanotechnologies have attracted increasing attention in their application in medicine, especially in the development of new drug delivery systems. With the help of nano-sized carriers, drugs can reach specific diseased areas, prolonging therapeutic efficacy while decreasing undesired side-effects. In addition, recent nanotechnological advances, such as surface stabilization and stimuli-responsive functionalization have also significantly improved the targeting capacity and therapeutic efficacy of the nanocarrier assisted drug delivery system. In this review, we evaluate recent advances in the development of different nanocarriers and their applications in therapeutics delivery.

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Cross-linker-Modulated Nanogel Flexibility Correlates with Tunable Targeting to a Sterically Impeded Endothelial Marker

Cited by 30 publications

References 54 publications

Biophysical Considerations in the Rational Design and Cellular Targeting of Flexible Polymeric Nanoparticles

Biophysical Considerations in the Rational Design and Cellular Targeting of Flexible Polymeric Nanoparticles

Biophysical Considerations in the Rational Design and Cellular Targeting of Flexible Polymeric Nanoparticles

Recent Advances in Nanocarrier-Assisted Therapeutics Delivery Systems

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