Nanotoxicité des points quantiques : étude in vitro chez les cellules épithéliales alvéolaires humaines A549

Bergeron-Prévost, Myrella

01 1900

Les nanoparticules (NPs) sont définies comme des particules ayant au moins une dimension comprise entre 1 à 100 nanomètres. Plusieurs études in vitro et in vivo indiquent que les NPs pourraient constituer un risque potentiel pour la santé des personnes les synthétisant ou les manipulant lors de leur incorporation dans d’autres matériaux. La nanotoxicologie est un domaine de recherche émergeant. Les propriétés physico-chimiques particulières des NPs sont responsables d’interférences non spécifiques entre les nanomatériaux et certains des composants des essais in vitro pouvant mener à de faux résultats. L’inhalation a été identifiée comme une voie d’exposition présentant un risque important de toxicité. Dans le cadre de ce projet, nous avons utilisé la lignée de cellules épithéliales alvéolaires humaines, A549. Nous avons étudié chez cette lignée les conséquences de l’exposition aux points quantiques (PQs), NPs d’intérêt pour leurs applications potentielles en médecine (nanovecteur ou nanosonde). La mise au point des conditions expérimentales (interférence entre l’essai LDH et le milieu de culture) a permis de valider les essais de cytotoxicité MTS et LDH en présence des PQs. Nous avons montré que les PQs présentaient une cytotoxicité à court et long terme, et nous avons par la suite étudié un des mécanismes de toxicité potentielle, la mesure du cadmium (Cd2+) libéré des PQs. Nous avons déterminé que la mesure du Cd2+ comportait plusieurs interférences qui invalident cet essai. En conclusion, notre étude a permis d’identifier des interférences qui remettent en question plusieurs conclusions d’études publiées qui n’ont pas vérifié l’existence de telles interférences. / Nanoparticles (NPs) are defined as particles with a diameter ranging from 1 to 100 nm. Several studies have suggested or demonstrated that NPs are a health risk factor for workers handling nanomaterials or for the general population using products containing NPs. Nanotoxicology is a new field of research. The particular physicochemical properties of NPs have revealed unexpected interferences of these nanomaterials with components of cytotoxic assays leading to false positive or negative interpretations. Inhalation being one of the most potential risk of NPs exposures, in this project, in vitro experiments were performed with the human alveolar epithelial cell line A549. Quantum dots (QDs) have been selected over other NPs because of their potential applications in medicine as nanovectors or nanoprobes. We have first validated the use of nanocytotoxic assays (LDH and MTS with QDs), and found that LDH assay interacts with components of the cell culture medium. A protocol established to counteract this interference has allowed demonstrating that both short and long term exposures to QDs are cytotoxic. We next addressed the underlying mechanisms of QDs nanotoxicity by determining concentrations of free cadmium potentially released from QDs when interacting with cells. We found that the cadmium assay has several interferences which invalidated the use of this assay. In conclusion, our study has allowed to identify several interferences with that call into question conclusions of published studies which have not examined these potential interferences.

Nanoparticules

Points quantiques

Cytotoxicité

Interférences

Mécanismes de toxicité

Nanotoxicité

Essais in vitro de cytotoxicité

Nanoparticles

Quantum dots

Nanotoxicity

Cytotoxicity

In vitro cytotoxic assays

Mechanisms of toxicity

Nanomaterial Charge-Dependent Platelet Activating Factor Receptor Agonism in Human Epidermal Cells

Qureshi, Shahryar Jamshed

30 August 2018

No description available.

Toxicology

Biology

Nanoscience

Nanotechnology

Nanoparticles

Nanotoxicity

Silver

Ag

Platelet Activating Factor Receptor

Platelet Activating Factor

IL-8

ROS

ICP-MS

BPEI

Implications of Shape Factors on Fate, Uptake, and Nanotoxicity of Gold Nanomaterials

Abtahi, Seyyed Mohammad Hossein

28 June 2018

Noble metal nanoparticles such as gold and silver are of interest because of the unique electro-optical properties (e.g., localized surface plasmon resonance [LSPR]) that originate from the collective behavior of their surface electrons. These nanoparticles are commonly developed and used for biomedical and industrial application. A recent report has predicted that the global market for gold nanoparticles will be over 12.7 tons by year 2020. However, these surface-functionalized nanoparticles can be potential environmental persistent contaminants post-use due to their high colloidal stability in the aquatic systems. Despite, the environmental risks associated with these nanoparticles, just a few studies have investigated the effect of nanofeature factors such as size and shape on the overall fate/transport and organismal uptake of these nanomaterials in the aquatic matrices. This study presents a comprehensive approach to evaluate the colloidal stability, fate/transport, and organismal uptake of these nanoparticles while factoring in the size and shape related properties. We demonstrate the importance and effect of anisotropicity of a gold nanoparticle on the colloidal behavior and interaction with ecologically susceptible aquatic biota. We also show how readily available characterization techniques can be utilized to monitor and assess the fate/transport of this class of nanoparticles. We further describe and investigate the relationship between the aspect ratio (AR) of these elongated gold nanoparticles with clearance mechanisms and rates from the aquatic suspension columns including aggregation, deposition, and biopurification. We illustrate how a fresh water filter-feeder bivalve, Corbicula fluminea, can be used as a model organism to study the size and shape-selective biofiltration and nanotoxicity of elongated gold nanoparticles. The results suggest that biofiltration by C. fluminea increases with an increase in the size and AR of gold nanoparticle. We develop a simple nanotoxicity assay to investigate the short-term exposure nanotoxicity of gold nanoparticles to C. fluminea. The toxicity results indicate that for the tested concentration and exposure period that gold nanoparticles were not acutely toxic (i.e., not lethal). However, gold nanoparticles significantly inhibited the activities of some antioxidant enzymes in gill and digestive gland tissues. These inhibitions could directly affect the resistance of these organisms to a secondary stressor (temperature, pathogens, hypoxia etc.) and threaten organismal health. / Ph. D.

Nanotechnology

nanomaterials

nanotoxicity

gold nanoparticles

gold nanorods

aggregation

colloidal stability

filter-feeders

Corbicula fluminea

fate and transport

Vis-NIR spectroscopy

TEM

Dynamic light scattering (DLS)

Estudo de nanopartículas de ouro e de magnetita voltadas para medicina diagnóstica / Study of gold and magnetite nanoparticles for medical diagnostics applicatios

Uchiyama, Mayara Klimuk

14 August 2015

A teragnóstica de doenças tem sido extremamente marcada nos últimos anos por nanomateriais formados pela conjugação de nanopartículas a biomoléculas, pois a aplicação de tecnologias baseadas em materiais na dimensão nanométrica é capaz de aumentar a seletividade, sensibilidade e praticidade dos métodos atualmente empregados, ou mesmo criar novos métodos de diagnóstico e tratamento de doenças. Dentre os vários tipos de nanomateriais desenvolvidos, aqueles baseados em nanopartículas de ouro ou nanopartículas magnéticas apresentam propriedades químicas e físicas diferenciadas que propiciam novas possibilidades. Por exemplo, a presente tese demonstrou que nanopartículas superparamagnéticas são excelentes agentes de contraste em exames de imagem por ressonância magnética (IRM) por serem mais seguros, apresentarem melhor contraste nas imagens e possibilitarem direcionar/concentrar o material em tecidos ou tumores através de um gradiente de campo magnético aplicado. Foram feitos numerosos ensaios de toxicidade tanto in vitro quanto in vivo para assegurar a segurança da aplicação de nanopartículas no organismo, cujo potencial de uso somente se tornará uma realidade caso os nanomateriais se mostrem não tóxicos e biocompatíveis. Apesar dos significativos avanços na área da aplicação desses nanomateriais, não foram encontrados na literatura modelos capazes de explicar ou prever por quais sítios de ligação devem ocorrer as interações proteína-nanopartícula, como também não foram encontrados estudos sistemáticos acerca dos fatores que determinam a estabilidade e a funcionalidade dos nanobioconjugados (NBCs). Assim, nesta tese buscamos compreender os fatores responsáveis pela ligação/adsorção das proteínas nas nanopartículas de ouro e sua influência sobre a estabilidade das suspensões e a funcionalidade das proteínas. Desta forma, foram obtidos NBCs com propriedades adequadas para o desenvolvimento ou aprimoramento de ensaios de diagnóstico e até para o tratamento de doenças. Foi demonstrado o potencial das nanopartículas de ouro para melhorar a performance de imunoensaios do tipo ELISA, mas também podem ser utilizadas para o desenvolvimento de métodos de diagnóstico, explorando as propriedades plasmônicas das nanopartículas de ouro acopladas a técnicas como SERS, SPR e microscopia Raman confocal. / Theranostics has been intensively pursued in recent years using hybrid materials based on nanoparticles conjugated with biomolecules. This is an interesting strategy to increase the selectivity and sensitivity, as well as to improve the currently used methods facilitating their use or creating new ones. Among the various types of nanomaterials, those based on gold and magnetic nanoparticles exhibit interesting chemical and physical properties in the biological environment, differing from that of free drugs or current explored in assay methods. For example, superparamagnetic nanoparticles are excellent contrast agents for magnetic resonance image (MRI) diagnostics because they are safer, present a better contrast efficiency for imaging and can be magnetically accumulated in tissues or tumors using a magnetic field. Numerous in vitro and in vivo toxicity assays were performed to ensure the safety for medical applications. Clearly, these type of applications only will be realized if nanomaterials prove to be nontoxic and biocompatible. This imply an strict control on their structure and composition. However, despite the significant advances in the development of such nanomaterials, there were not found in the literature model systems explaining or that can be used to predict by which sites the protein-nanoparticle binding should take place. In addition, no systematic studies on the factors determining the stability and the functionality of nanobioconjugates (NBC) were found. Thus, this thesis is focused in unveiling the factors responsible for binding/adsorption of proteins on gold nanoparticles and their influence on the colloidal stability of hybrid nanoparticles suspensions while keeping the functionality of biomolecules. In fact, NBC with enhanced properties suitable for the development of diagnostic methods and even for treatment of diseases were obtained. These nanomaterials can improve the ELISA immunoassay, or other diagnosis methods can be developed by using the gold nanoparticles plasmonic properties in association with SERS, SPR and confocal Raman microscopy techniques.

Agente de contraste em IRM

Antiinflammatory property

Biodistribuição

Biodistribution

Bioinorganic chemistry

Direcionamento magnético

In vitro and in vivo nanotoxicity

Magnetic targeting

MRI contrast agent

Nanotoxicidade in vitro e in vivo

Propriedade anti-inflamatória

Química bioinorgânica

Teragnóstica

Theranostic

Estudo de nanopartículas de ouro e de magnetita voltadas para medicina diagnóstica / Study of gold and magnetite nanoparticles for medical diagnostics applicatios

Mayara Klimuk Uchiyama

14 August 2015

A teragnóstica de doenças tem sido extremamente marcada nos últimos anos por nanomateriais formados pela conjugação de nanopartículas a biomoléculas, pois a aplicação de tecnologias baseadas em materiais na dimensão nanométrica é capaz de aumentar a seletividade, sensibilidade e praticidade dos métodos atualmente empregados, ou mesmo criar novos métodos de diagnóstico e tratamento de doenças. Dentre os vários tipos de nanomateriais desenvolvidos, aqueles baseados em nanopartículas de ouro ou nanopartículas magnéticas apresentam propriedades químicas e físicas diferenciadas que propiciam novas possibilidades. Por exemplo, a presente tese demonstrou que nanopartículas superparamagnéticas são excelentes agentes de contraste em exames de imagem por ressonância magnética (IRM) por serem mais seguros, apresentarem melhor contraste nas imagens e possibilitarem direcionar/concentrar o material em tecidos ou tumores através de um gradiente de campo magnético aplicado. Foram feitos numerosos ensaios de toxicidade tanto in vitro quanto in vivo para assegurar a segurança da aplicação de nanopartículas no organismo, cujo potencial de uso somente se tornará uma realidade caso os nanomateriais se mostrem não tóxicos e biocompatíveis. Apesar dos significativos avanços na área da aplicação desses nanomateriais, não foram encontrados na literatura modelos capazes de explicar ou prever por quais sítios de ligação devem ocorrer as interações proteína-nanopartícula, como também não foram encontrados estudos sistemáticos acerca dos fatores que determinam a estabilidade e a funcionalidade dos nanobioconjugados (NBCs). Assim, nesta tese buscamos compreender os fatores responsáveis pela ligação/adsorção das proteínas nas nanopartículas de ouro e sua influência sobre a estabilidade das suspensões e a funcionalidade das proteínas. Desta forma, foram obtidos NBCs com propriedades adequadas para o desenvolvimento ou aprimoramento de ensaios de diagnóstico e até para o tratamento de doenças. Foi demonstrado o potencial das nanopartículas de ouro para melhorar a performance de imunoensaios do tipo ELISA, mas também podem ser utilizadas para o desenvolvimento de métodos de diagnóstico, explorando as propriedades plasmônicas das nanopartículas de ouro acopladas a técnicas como SERS, SPR e microscopia Raman confocal. / Theranostics has been intensively pursued in recent years using hybrid materials based on nanoparticles conjugated with biomolecules. This is an interesting strategy to increase the selectivity and sensitivity, as well as to improve the currently used methods facilitating their use or creating new ones. Among the various types of nanomaterials, those based on gold and magnetic nanoparticles exhibit interesting chemical and physical properties in the biological environment, differing from that of free drugs or current explored in assay methods. For example, superparamagnetic nanoparticles are excellent contrast agents for magnetic resonance image (MRI) diagnostics because they are safer, present a better contrast efficiency for imaging and can be magnetically accumulated in tissues or tumors using a magnetic field. Numerous in vitro and in vivo toxicity assays were performed to ensure the safety for medical applications. Clearly, these type of applications only will be realized if nanomaterials prove to be nontoxic and biocompatible. This imply an strict control on their structure and composition. However, despite the significant advances in the development of such nanomaterials, there were not found in the literature model systems explaining or that can be used to predict by which sites the protein-nanoparticle binding should take place. In addition, no systematic studies on the factors determining the stability and the functionality of nanobioconjugates (NBC) were found. Thus, this thesis is focused in unveiling the factors responsible for binding/adsorption of proteins on gold nanoparticles and their influence on the colloidal stability of hybrid nanoparticles suspensions while keeping the functionality of biomolecules. In fact, NBC with enhanced properties suitable for the development of diagnostic methods and even for treatment of diseases were obtained. These nanomaterials can improve the ELISA immunoassay, or other diagnosis methods can be developed by using the gold nanoparticles plasmonic properties in association with SERS, SPR and confocal Raman microscopy techniques.

Agente de contraste em IRM

Biodistribuição

Direcionamento magnético

Nanotoxicidade in vitro e in vivo

Propriedade anti-inflamatória

Química bioinorgânica

Teragnóstica

Antiinflammatory property

Biodistribution

Bioinorganic chemistry

In vitro and in vivo nanotoxicity

Magnetic targeting

MRI contrast agent

Theranostic

Development of a Lab-on-a-Chip Device for Rapid Nanotoxicity Assessment In Vitro

Shah, Pratikkumar

11 December 2014

Increasing useof nanomaterials in consumer products and biomedical applications creates the possibilities of intentional/unintentional exposure to humans and the environment. Beyond the physiological limit, the nanomaterialexposure to humans can induce toxicity. It is difficult to define toxicity of nanoparticles on humans as it varies by nanomaterialcomposition, size, surface properties and the target organ/cell line. Traditional tests for nanomaterialtoxicity assessment are mostly based on bulk-colorimetric assays. In many studies, nanomaterials have found to interfere with assay-dye to produce false results and usually require several hours or days to collect results. Therefore, there is a clear need for alternative tools that can provide accurate, rapid, and sensitive measure of initial nanomaterialscreening. Recent advancement in single cell studies has suggested discovering cell properties not found earlier in traditional bulk assays. A complex phenomenon, like nanotoxicity, may become clearer when studied at the single cell level, including with small colonies of cells. Advances in lab-on-a-chip techniques have played a significant role in drug discoveries and biosensor applications, however, rarely explored for nanomaterialtoxicity assessment. We presented such cell-integrated chip-based approach that provided quantitative and rapid response of cellhealth, through electrochemical measurements. Moreover, the novel design of the device presented in this study was capable of capturing and analyzing the cells at a single cell and small cell-population level. We examined the change in exocytosis (i.e. neurotransmitterrelease) properties of a single PC12 cell, when exposed to CuOand TiO2 nanoparticles. We found both nanomaterials to interfere with the cell exocytosis function. We also studied the whole-cell response of a single-cell and a small cell-population simultaneously in real-time for the first time. The presented study can be a reference to the future research in the direction of nanotoxicity assessment to develop miniature, simple, and cost-effective tool for fast, quantitative measurements at high throughput level. The designed lab-on-a-chip device and measurement techniques utilized in the present work can be applied for the assessment of othernanoparticles' toxicity, as well.

Nanotoxicity

Electrochemistry

Single Cell

Cell Electronics

Dielectrophoresis

Bio-MEMS

Nanotechnology

Analytical Chemistry

Bioelectrical and Neuroengineering

Biomedical Devices and Instrumentation

Nanotechnology Fabrication