A Detailed Investigation on the Interactions between Magnetic Nanoparticles and Cell Membrane Models

Uehara, Thiers M.; Marangoni, Valéria S.; Pasquale, Nicholas; Miranda, Paulo B.; Lee, Ki‐Bum; Zucolotto, Valtencir

doi:10.1021/am404042r

Cited by 32 publications

(31 citation statements)

References 42 publications

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“…18,19 Until today, the emergence of several biomimetic model membranes based on lipid nanosystems and biophysical techniques to study and characterize drug-membrane interactions have resulted in new concerns about how a drug influences membrane properties and vice-versa. [19][20][21][22][23][24][25][26][27][28][29][30] In our previous works, as well as in other studies, it is reported the correlations between the biological action and cytotoxicity of drugs and their biophysical effects in biomimetic membranes, eg by altering lipid membrane packing, decreasing lipid membrane transition temperatures or disturbing cooperativity of lipid unit cells, with consequent membrane biophysical impairment. 21,[26][27][28]31,32 Additionally, several interesting reports 19,20,[33][34][35][36][37] highlighted the importance of biomimetic models based on lipid nanosystems (liposomes, monolayers and supported lipid bilayers) to acquire molecular and functional information.…”

Section: Introductionmentioning

confidence: 85%

“…This information can also assist to the design of new chemical entities with improved efficacy and reduced toxicity, 19,34,37 or even to understand the interaction of drug delivery nanosystems with biomembranes. 30,34,38,39 Therefore, in this study, the interaction of AntiOxCIN 3 with the most relevant biointerfaces was studied and characterized allying in silico descriptors with different in vitro biophysical methods and biomimetic model systems to predict its biodistribution behavior. In order to mimic the journey of AntiOxCIN 3 in the body after oral administration, four different biomimetic interface models were considered: (i) micelles of intestinal biliary salts; (ii) human serum albumin (HSA); (iii) lipid nanosystems (lipid vesicles and lipid bilayers) used as membrane models, which are composed by phosphatidylcholine (PC) as the main phospholipid component of cell membranes; and (iv) lipid nanosystems (lipid vesicles) composed of lipids from the endothelial membrane of BBB mimicking this important lipid biointerface.…”

Section: Introductionmentioning

confidence: 99%

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Lipid Nanosystems and Serum Protein as Biomimetic Interfaces: Predicting the Biodistribution of a Caffeic Acid-Based Antioxidant

Fernandes

Benfeito

Cagide

et al. 2021

NSA

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AntiOxCIN 3 is a novel mitochondriotropic antioxidant developed to minimize the effects of oxidative stress on neurodegenerative diseases. Prior to an investment in preclinical in vivo studies, it is important to apply in silico and biophysical cell-free in vitro studies to predict AntiOxCIN 3 biodistribution profile, respecting the need to preserve animal health in accordance with the EU principles (Directive 2010/63/EU). Accordingly, we propose an innovative toolbox of biophysical studies and mimetic models of biological interfaces, such as nanosystems with different compositions mimicking distinct membrane barriers and human serum albumin (HSA). Methods: Intestinal and cell membrane permeation of AntiOxCIN 3 was predicted using derivative spectrophotometry. AntiOxCIN 3-HSA binding was evaluated by intrinsic fluorescence quenching, synchronous fluorescence, and dynamic/electrophoretic light scattering. Steady-state and time-resolved fluorescence quenching was used to predict AntiOxCIN 3membrane orientation. Fluorescence anisotropy, synchrotron small-and wide-angle X-ray scattering were used to predict lipid membrane biophysical impairment caused by AntiOxCIN 3 distribution. Results and Discussion: We found that AntiOxCIN 3 has the potential to permeate the gastrointestinal tract. However, its biodistribution and elimination from the body might be affected by its affinity to HSA (>90%) and by its steady-state volume of distribution (VD SS =1.89 ± 0.48 L•Kg −1). AntiOxCIN 3 is expected to locate parallel to the membrane phospholipids, causing a bilayer stiffness effect. AntiOxCIN 3 is also predicted to permeate through blood-brain barrier and reach its therapeutic target-the brain. Conclusion: Drug interactions with biological interfaces may be evaluated using membrane model systems and serum proteins. This knowledge is important for the characterization of drug partitioning, positioning and orientation of drugs in membranes, their effect on membrane biophysical properties and the study of serum protein binding. The analysis of these interactions makes it possible to collect valuable knowledge on the transport, distribution, accumulation and, eventually, therapeutic impact of drugs which may aid the drug development process.

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Section: Introductionmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Lipid Nanosystems and Serum Protein as Biomimetic Interfaces: Predicting the Biodistribution of a Caffeic Acid-Based Antioxidant

Fernandes

Benfeito

Cagide

et al. 2021

NSA

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“…In contrast, for the NPs/DPPC system, both types of nanoparticles are capable of interacting with the zwitterionic DPPC molecules, forming an overlayer of lipid-covered NPs on top of the DPPC film, which leads to a reduction in the area per molecule [277].…”

Section: Accepted Manuscriptmentioning

confidence: 98%

Interactions of bioactive molecules & nanomaterials with Langmuir monolayers as cell membrane models

et al. 2015

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“…SFG spectroscopy/microscopy has already proven to be of great interest in the study of model biointerfaces in the past [70,71]. In fact, the studies of interactions of magnetic nanoparticles [72] or AuNPs [73] with cell membrane models are performed on more or less complex interfaces made of supported lipid bilayers. Indeed, small AuNPs may interact with the cell membrane but the interaction mechanism at the nanoscale is not well understood.…”

Section: Recent Developments In Sfg Spectroscopy Of Plasmonic Matementioning

confidence: 99%

Sum-Frequency Generation Spectroscopy of Plasmonic Nanomaterials: A Review

et al. 2019

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We report on the recent scientific research contribution of non-linear optics based on Sum-Frequency Generation (SFG) spectroscopy as a surface probe of the plasmonic properties of materials. In this review, we present a general introduction to the fundamentals of SFG spectroscopy, a well-established optical surface probe used in various domains of physical chemistry, when applied to plasmonic materials. The interest of using SFG spectroscopy as a complementary tool to surface-enhanced Raman spectroscopy in order to probe the surface chemistry of metallic nanoparticles is illustrated by taking advantage of the optical amplification induced by the coupling to the localized surface plasmon resonance. A short review of the first developments of SFG applications in nanomaterials is presented to span the previous emergent literature on the subject. Afterwards, the emphasis is put on the recent developments and applications of the technique over the five last years in order to illustrate that SFG spectroscopy coupled to plasmonic nanomaterials is now mature enough to be considered a promising research field of non-linear plasmonics.

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A Detailed Investigation on the Interactions between Magnetic Nanoparticles and Cell Membrane Models

Cited by 32 publications

References 42 publications

Lipid Nanosystems and Serum Protein as Biomimetic Interfaces: Predicting the Biodistribution of a Caffeic Acid-Based Antioxidant

Lipid Nanosystems and Serum Protein as Biomimetic Interfaces: Predicting the Biodistribution of a Caffeic Acid-Based Antioxidant

Interactions of bioactive molecules & nanomaterials with Langmuir monolayers as cell membrane models

Sum-Frequency Generation Spectroscopy of Plasmonic Nanomaterials: A Review

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