Engineering the Interface between Inorganic Nanoparticles and Biological Systems through Ligand Design

Huang, Rui; Luther, David C.; Zhang, Xianzhi; Gupta, Aarohi; Tufts, S.; Rotello, Vincent

doi:10.3390/nano11041001

Cited by 15 publications

(18 citation statements)

References 141 publications

(183 reference statements)

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“…Monolayer-protected gold nanoparticles (AuNPs) have been extensively investigated to disclose their unique and diverse properties. [1][2][3][4][5] AuNPs have already shown great potential in applications, including chemosensing (i.e., small molecule detection in solution) [6,7], biosensing [8][9][10], catalysis (nanozymes) [11][12][13] and transport of chemical species in biological environments and cells (e.g., drug delivery) [14][15][16]. Inorganic nanoparticles can be engineered to possess physiochemical properties for specific applications, e.g., their shape [17] and size [18] can be tuned to define nanoparticle properties.…”

Section: Introductionmentioning

confidence: 99%

“…The molecular recognition properties of these particles are dictated by the chemical structure of the coating ligands, which form self-organized and multivalent binding sites for the guest species [19], a feature crucial for nanoparticle colloidal stability [20,21]. The surface of the nanoparticles interfaces with the external environment, and appropriately engineered surfaces can be used to regulate interactions between nanoparticles and biomolecules [22][23][24] driven by non-covalent interactions [9,25].…”

Section: Introductionmentioning

confidence: 99%

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Role of Ionic Strength in the Formation of Stable Supramolecular Nanoparticle–Protein Conjugates for Biosensing

Brancolini

Rotello

Corni

2022

IJMS

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Monolayer-protected gold nanoparticles (AuNPs) exhibit distinct physical and chemical properties depending on the nature of the ligand chemistry. A commonly employed NP monolayer comprises hydrophobic molecules linked to a shell of PEG and terminated with functional end group, which can be charged or neutral. Different layers of the ligand shell can also interact in different manners with proteins, expanding the range of possible applications of these inorganic nanoparticles. AuNP-fluorescent Green Fluorescent Protein (GFP) conjugates are gaining increasing attention in sensing applications. Experimentally, their stability is observed to be maintained at low ionic strength conditions, but not at physiologically relevant conditions of higher ionic strength, limiting their applications in the field of biosensors. While a significant amount of fundamental work has been done to quantify electrostatic interactions of colloidal nanoparticle at the nanoscale, a theoretical description of the ion distribution around AuNPs still remains relatively unexplored. We perform extensive atomistic simulations of two oppositely charged monolayer-protected AuNPs interacting with fluorescent supercharged GFPs co-engineered to have complementary charges. These simulations were run at different ionic strengths to disclose the role of the ionic environment on AuNP–GFP binding. The results highlight the capability of both AuNPs to intercalate ions and water molecules within the gold–sulfur inner shell and the different tendency of ligands to bend inward allowing the protein to bind not only with the terminal ligands but also the hydrophobic alkyl chains. Different binding stability is observed in the two investigated cases as a function of the ligand chemistry.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Role of Ionic Strength in the Formation of Stable Supramolecular Nanoparticle–Protein Conjugates for Biosensing

Brancolini

Rotello

Corni

2022

IJMS

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“…12 Incorporating TMCs into nanoparticle hosts can solubilize and stabilize the catalysts, providing bioorthogonal 'nanozymes' that replicate structural and functional aspects of natural enzymes. 13,14 These nanoscaffolds possess unique physicochemical properties that facilitate rational design and future applications. 15 To date, a wide range of nanomaterials have been used to generate nanozymes, advancing the development of bioorthogonal catalysis.…”

Section: Introductionmentioning

confidence: 99%

All-natural gelatin-based bioorthogonal catalysts for efficient eradication of bacterial biofilms

et al. 2022

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“…Gating, substrate- and site-selectivities derived from the molecular details of the on-particle molecular environment needed to be carefully designed . Mimicking the catalytic activity of proteins or their interaction with biological matter exploiting SAM-AuNPs has also been the object of growing exploration. − The integration of bio-orthogonal catalytic systems such as transition-metal catalysts into nanoparticle scaffolds allowed the creation of synthetic catalytic nanosystems (nanozymes) able to replicate the complex behavior of natural enzymes in biological media. , Hydrophobicity of surface motifs and monolayer compaction regulate the kinetic behavior of the nanozyme, together with temperature or pH. , …”

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confidence: 99%

“…15,16 Hydrophobicity of surface motifs and monolayer compaction regulate the kinetic behavior of the nanozyme, together with temperature or pH. 17,18 The examples cited above point out the beauty and complexity of surface confined environments in SAMs. They all rely on the local structure, dynamics, and solvation of the monolayer at atomic and nanoscale, although to a different extent.…”

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confidence: 99%

Spotting Local Environments in Self-Assembled Monolayer-Protected Gold Nanoparticles

et al. 2022

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Organic−inorganic (O−I) nanomaterials are versatile platforms for an incredible high number of applications, ranging from heterogeneous catalysis to molecular sensing, cell targeting, imaging, and cancer diagnosis and therapy, just to name a few. Much of their potential stems from the unique control of organic environments around inorganic sites within a single O−I nanomaterial, which allows for new properties that were inaccessible using purely organic or inorganic materials. Structural and mechanistic characterization plays a key role in understanding and rationally designing such hybrid nanoconstructs. Here, we introduce a general methodology to identify and classify local (supra)molecular environments in an archetypal class of O−I nanomaterials, i.e., self-assembled monolayer-protected gold nanoparticles (SAM-AuNPs). By using an atomistic machine-learning guided workflow based on the Smooth Overlap of Atomic Positions (SOAP) descriptor, we analyze a collection of chemically different SAM-AuNPs and detect and compare local environments in a way that is agnostic and automated, i.e., with no need of a priori information and minimal user intervention. In addition, the computational results coupled with experimental electron spin resonance measurements prove that is possible to have more than one local environment inside SAMs, being the thickness of the organic shell and solvation primary factors in the determining number and nature of multiple coexisting environments. These indications are extended to complex mixed hydrophilic−hydrophobic SAMs. This work demonstrates that it is possible to spot and compare local molecular environments in SAM-AuNPs exploiting atomistic machine-learning approaches, establishes ground rules to control them, and holds the potential for the rational design of O−I nanomaterials instructed from data.

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Engineering the Interface between Inorganic Nanoparticles and Biological Systems through Ligand Design

Cited by 15 publications

References 141 publications

Role of Ionic Strength in the Formation of Stable Supramolecular Nanoparticle–Protein Conjugates for Biosensing

Role of Ionic Strength in the Formation of Stable Supramolecular Nanoparticle–Protein Conjugates for Biosensing

All-natural gelatin-based bioorthogonal catalysts for efficient eradication of bacterial biofilms

Spotting Local Environments in Self-Assembled Monolayer-Protected Gold Nanoparticles

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