In Situ Characterization of Protein Adsorption onto Nanoparticles by Fluorescence Correlation Spectroscopy

Li, Shang; Nienhaus, G. Ulrich

doi:10.1021/acs.accounts.6b00579

Cited by 156 publications

(142 citation statements)

References 72 publications

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“…As we will show further below, the excellent agreement of such data with a binding isotherm (Figure b) does not per se prove that a dynamic equilibrium rules the process . Thus, we checked for reversibility by measuring R H of the NPs immersed in PBS with specific Tf concentrations before and after eightfold dilution of the protein . R H decreased after dilution as predicted by the binding curve (Figure b), confirming reversibility of protein binding.…”

Section: Resultsmentioning

confidence: 99%

Formation of a Monolayer Protein Corona around Polystyrene Nanoparticles and Implications for Nanoparticle Agglomeration

Wang

Nienhaus

et al. 2019

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Nanoparticle (NP) interactions with cells and organisms are mediated by a biomolecular adsorption layer, the so‐called “protein corona.” An in‐depth understanding of the corona is a prerequisite to successful and safe application of NPs in biology and medicine. In this work, earlier in situ investigations on small NPs are extended to large polystyrene (PS) NPs of up to 100 nm diameter, using human transferrin (Tf) and human serum albumin (HSA) as model proteins. Direct NP sizing experiments reveal a reversibly bound monolayer protein shell (under saturating conditions) on hydrophilic, carboxyl‐functionalized (PS‐COOH) NPs, as was earlier observed for much smaller NPs. In contrast, protein binding on hydrophobic, sulfated (PS‐OSO3H) NPs in solvent of low ionic strength is completely irreversible; nevertheless, the thickness of the observed protein corona again corresponds to a protein monolayer. Under conditions of reduced charge repulsion (higher ionic strength), the NPs are colloidally unstable and form large clusters below a certain protein–NP stoichiometric ratio, indicating that the adsorbed proteins induce NP agglomeration. This comprehensive characterization of the persistent protein corona on PS‐OSO3H NPs by nanoparticle sizing and quantitative fluorescence microscopy/nanoscopy reveals mechanistic aspects of molecular interactions occurring during exposure of NPs to biofluids.

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Section: Resultsmentioning

confidence: 99%

Formation of a Monolayer Protein Corona around Polystyrene Nanoparticles and Implications for Nanoparticle Agglomeration

Wang

Nienhaus

et al. 2019

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“…Studies have found that nanoparticles entering the body will combine with proteins to form complex due to excessive surface free energy. A large number of proteins attach to the surface of UFCB to form a protein corona (a protein membrane coated by proteins) . The combination of the two will change the function and structure of proteins.…”

Section: Resultsmentioning

confidence: 99%

“…A large number of proteins attach to the surface of UFCB to form a protein corona (a protein membrane coated by proteins). [47][48][49] The combination of the two will change the function and structure of proteins.…”

Section: The Backbone Changes Of Bhb Induced By Ufcbmentioning

confidence: 99%

Hematological effects of ultrafine carbon black on red blood cells and hemoglobin

Pan

Zhang

et al. 2019

J Biochem & Molecular Tox

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The harmful effects of ultrafine particles (UFPs) in the atmosphere have caused widespread concern. Ultrafine carbon black (UFCB) is an important component of UFPs. In this study, we explored the impact of UFCB on the structure, the antioxidant defense system, and the ATPase activity of human red blood cells (hRBCs). It was found that UFCB decreased the activity of SOD (73.58%), CAT (89.79%), and GSH‐Px (81.02%), leading to oxidative stress in hRBCs. UFCB had no destructive effect on the structure of hRBCs in 4 hours. ATPase activity increased (119.34%) and UFCB had weakly stimulated the cell membrane. On the molecular level, spectroscopic experiments showed that bovine hemoglobin (BHb) can bind to the UFCB by electrostatic force, leading to the shrinking of the BHb skeleton and increase in microenvironment polarity. This study demonstrates the negative hematological effect of UFCB on hemoglobin and hRBCs and reveals the potential risks in animals and humans.

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“…78 Materials in that environment, including but not limited to other nano-structures and various molecules (e.g., organic materials from lactose, plant or animal proteins and nucleic acids, dyes and/or minerals/ions in colloidal solutions with nano-structures), will attach (adsorb) to the outer surfaces of nano-scale structures to form new layers, coatings, or shells around the nano-structure. [78][79][80] Multiple factors, especially surface structure and surface energetics, as well as pH of the surrounding solution, 81 modulate the emergent properties of the resultant nanostructure coating. During the agitation such as sonication, vortexing, or manual succussions of a colloidal nano-structure solution, some of those elemental constituents, for example, nitrogen or phosphorus, as well as ethanol, may also dope the particles.…”

Section: Homeopathic Medicines As Complex Systemsmentioning

confidence: 99%

The Complexity of the Homeopathic Healing Response Part 2: The Role of the Homeopathic Simillimum as a Complex System in Initiating Recovery from Disease

Bell

2019

Homeopathy

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Background Evidence indicates that homeopathic medicines are complex self-organizing nano-scale systems that generate unique low-intensity electromagnetic signals and/or quantum coherence domains. In Part 1, we reviewed relevant concepts from complex adaptive systems science on living systems for the nature of homeopathic healing. Aim In Part 2, we discuss the complex-system nature of homeopathic medicines. The aim is to relate the evidence on the nature and properties of homeopathic medicines to the complex systems model for homeopathic healing. Methods and Results The work is a narrative review, with complexity model development for the nature of homeopathic medicines. Studies suggest that homeopathic manufacturing generates nano-structures of source material, silica and silicon quantum dots if succussed in glassware or including botanical source materials; or carbon quantum dots if succussed in plastic or including any organic source materials, as well as solute-induced water nano-structures carrying medicine-specific information. On contact with physiological fluids (e.g., blood plasma), there is evidence that nano-structures additionally adsorb individualized patterns of the recipient's own proteins on to their surfaces to create a unique protein corona coat (shell). Thus, the simillimum may generate a personalized biological identity upon administration. Consequently, a medicine can serve as an individually salient, self-similar information carrier, whose protein corona constituent pattern reflects the individual's current internal state of health/disease. Homeopathic medicine complexity emerges from interactions of the component parts from source, silica from glassware or carbon from plastic containers, solvents (lactose, water, ethanol), adsorbed biomolecule layers from plant or animal sources, and adsorbed biomolecules of the recipient. Low doses of these complex medicines can act as biological signaling agents to initiate hormesis via a network-wide pattern of adaptive responses by the recipient complex adaptive system, rather than as conventional pharmaceutical drugs. Biological mediators of adaptive responses include inter-connected network elements of the cell danger/damage defense system: for example, gene expression, reactive oxygen species, heat shock proteins, cytokines, macrophages, T-cells, and associated brain–immune system mediator pathways. Conclusions Every homeopathic medicine is a complex nano-scale system involving multiple inter-connected, interacting components, and emergent properties. Simillimum individualization derives from formation of a unique personalized protein corona shell adsorbed to the reactive surface of the homeopathic nano-structures on contact with the recipient's body fluids. Low doses of such complex nano-structures initiate the adaptive processes of hormesis to mobilize endogenous healing of a disease state. The capacity for self-organization and self-similarity in complex systems is the key to future research on the nature of homeopathic medicines and systemic healing during individualized homeopathic treatment.

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In Situ Characterization of Protein Adsorption onto Nanoparticles by Fluorescence Correlation Spectroscopy

Cited by 156 publications

References 72 publications

Formation of a Monolayer Protein Corona around Polystyrene Nanoparticles and Implications for Nanoparticle Agglomeration

Formation of a Monolayer Protein Corona around Polystyrene Nanoparticles and Implications for Nanoparticle Agglomeration

Hematological effects of ultrafine carbon black on red blood cells and hemoglobin

The Complexity of the Homeopathic Healing Response Part 2: The Role of the Homeopathic Simillimum as a Complex System in Initiating Recovery from Disease

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