Analyse physico-chimique de milieux liquides d’intérêt biologique exposés à des plasmas froids produits à pression atmosphérique et température ambiante / Physico-chemical analysis of liquid media of biological interest exposed to cold plasmas produced at atmospheric pressure and room temperature

Girard, Fanny

05 December 2017

Les plasmas froids sont des gaz partiellement ionisés, très riches d’un point de vue physico-chimique. Cette propriété se retrouve dans des plasmas froids aujourd’hui générés à pression atmosphérique et température ambiante et a été mise à profit depuis une quinzaine d’années environ pour des applications biomédicales (hématologie, dermatologie, cancérologie, odontologie etc…). L’efficacité de ces plasmas froids dans le domaine de la médecine a été prouvée par de nombreuses études. Cependant, les phénomènes biologiques mis en jeu ne sont pas encore bien compris, et il primordial de savoir quels pourraient être les éventuels effets secondaires indésirables de ces milieux ionisés réactifs. Le premier niveau d’interaction des plasmas avec le vivant est celui avec les milieux liquides, qui sont présents en surface des tissus, des cellules in vivo ou en culture. Depuis une décennie, une attention particulière a donc été portée aux interactions des plasmas avec les liquides, pour apporter un niveau de compréhension supplémentaire. La compréhension de ces interactions a constitué l’axe de ce travail. Différents réacteurs à plasmas froids (générés à pression atmosphérique et température ambiante) ont été développés, notamment afin de contrôler les interactions du plasma avec l’air ambiant qui peuvent être problématiques pour les applications visées. La nature du gaz servant à initier le plasma a été modifiée, pour connaître son influence sur la réactivité chimique de la phase gaz. Pour cela, des mesures de spectroscopie d’émission optique (SEO) ont été nécessaires. Par ailleurs, de nouveaux capteurs électrochimiques et des approches méthodologiques ont été développés pour identifier et quantifier les espèces réactives de l’oxygène et de l’azote (RONS) produites dans des milieux liquides physiologiques, exposés à ces gaz ionisés. Les analyses électrochimiques ont été combinées à de la spectroscopie d’absorption UV-visible ainsi qu’à d’autres méthodes de chimie (pH-métrie/conductimétrie). Un des objectifs visés est d’établir une corrélation entre les espèces réactives générées dans la phase gaz et dans la phase liquide. Enfin, des expérimentations nous ont permis d’analyser la production des RONS dans des liquides in situ en temps réel. Les mesures de SEO montrent qu’il existe de nombreuses espèces chimiques excitées au sein des différents plasmas (NO°, HO°, O, N2+ (FNS) etc…). Les analyses de la phase liquide ont révélé la présence d’espèces stables de l’oxygène et de l’azote (H2O2, NO2-, NO3-), directement reliées aux espèces détectées dans les plasmas. De plus, les diverses méthodologies d’analyse chimique mises en place ont permis la détection et la quantification de RONS tels que l’anion peroxynitrite ONOO-. L’ensemble des résultats obtenus devrait permettre d’appréhender de façon plus fine les effets induits par différents plasmas froids dans des milieux liquides physiologiques afin d’établir un lien avec les études menées sur des cellules en culture et sur la peau dans le cadre d’un programme de recherche financé par l’ANR, Agence Nationale de la recherche. / Cold plasmas are partially ionized gases, very rich in a physico-chemical point of view. This property characterizes cold plasmas today generated at atmospheric pressure and ambient temperature and was used since about fifteen years approximately for biomedical applications (haematology, dermatology, cancer research, odontology etc.). The efficiency of these cold plasmas in the field of the medicine was proved by numerous studies. However, the involved biological phenomena are not still well included, and it is essential to know what could be the possible unwanted side effects of these reactive ionized gases. The first level of interaction of plasmas with living matter is the one with the liquid phase, which is present on the tissue surface, in vivo cells or in culture. For a decade, a particular attention was thus worn in the interactions of plasmas with liquids, to bring a level of additional understanding. The understanding of these interactions constituted the axis of this work. Various cold plasmas reactors (generated at atmospheric pressure and ambient temperature) were developed, in order to control the interactions of these plasmas with the ambient air which can be problematic for the aimed applications. The nature of the gas used to initiate the plasma was modified, to know its influence on the chemical reactivity of the gas phase. For that purpose, measurements of optical emissive spectroscopy (OES) were necessary. Besides, new electrochemical sensors and methodological approaches were developed in order to identify and quantify the reactive nitrogen and oxygen (RONS) produced in physiological liquid media, exposed to these ionized gases. The electrochemical analyses were combined UV-visible absorption spectroscopy as well as other methods of chemistry (pH-metry/conductimetry). One of the aimed objectives is to establish a correlation between the reactive species generated in the gas phase and in the liquid phase. Finally, experiments allowed us to analyze the production of RONS in liquids in situ and in real time. OES measurements showed that there are numerous chemical species generated in various plasmas (NO°, HO°, O, N2+ (FNS) etc.). The analyses of the liquid phase revealed the presence of stable oxygen and nitrogen species (H2O2, NO2-, NO3-), directly correlated with the species detected in plasmas. Furthermore, the diverse methodologies of chemical analysis allowed the detection and quantification of RONS such as the peroxynitrite anion ONOO-. The obtained results should allow to arrest in a finer way the effects led by various cold plasmas in physiological liquid media to establish links with the studies led on cultured cells and on skin within the framework of a research program financed by the ANR, National Agency of the Research.

Décharges à barrière diélectrique

Ondes d’ionisation guidées

Température rotationnelle

Hélium

Applications biomédicales

Cellules

Réparation tissulaire

Spectroscopie d’émission optique

Electrochimie

Chronoampérométrie

Volamétrie cyclique

Spectroscopie d’absorption UV-visible

Peroxyde d’hydrogène

Cold atmospheric plasmas

Dielectric barrier discharges

Guided ionisation waves

Rotational temperature

Helium

Reactive oxygen and nitrogen species

Biomedical applications

Cells

Skin wound healing

Optical emissive spectroscopy

Electrochemisry

Chronoampérométry

Cyclic voltametry

UV-visible absorption spectroscopy

Hydrogen peroxide

541.3

Synthesis, adsorption and catalysis of large pore metal phosphonates

Pearce, Gordon M.

January 2010

The synthesis and properties of metal phosphonates prepared using piperazine-based bisphosphonic acids have been investigated. The ligands N,N’-piperazinebis(methylenephosphonic acid) (H₄L), and the 2-methyl (H₄L-Me) and 2,5-dimethyl (H₄L 2,5-diMe) derivatives have been prepared using a modified Mannich reaction. Hydrothermal reaction of gels prepared from metal (II) acetates and the bisphosphonic acids results in the synthesis of four structures: STA-12, Ni VSB-5, Co H₂L.H₂O and Mg H₂L. STA-12, synthesised by reaction of Mn, Fe, Co or Ni acetate with H₄L or H₄L-Me, has been investigated further. STA-12 crystallises in the space group R⁻₃, and Ni STA-12 is the most crystalline version. Its structure was solved from synchrotron data (a = b = 27.8342(1) Å, c = 6.2421(3) Å, α = β = 90°, γ = 120°), and it has large 10 Å hexagonal shaped pores. Helical chains of Ni octahedra are coordinated by the ligands, resulting in phosphonate tetrahedra pointing towards the pore space. Water is present, both coordinated to the Ni²⁺ cations and physically adsorbed in the pores. Mixed metal structures based on Ni STA-12, where some Ni is replaced in the gel by another divalent metal (Mg, Mn, Fe or Co) can also be synthesised. Dehydration of STA-12 results in two types of behaviour, depending on the metal present. Rhombohedral symmetry is retained on dehydration of Mn and Fe STA-12, the a cell parameter decreasing compared to the as-prepared structures by 2.42 Å and 1.64 Å respectively. Structure solution of dehydrated Mn STA-12 indicates changes in the torsion angles of the piperazine ring bring the inorganic chains closer together. Fe and Mn STA-12 do not adsorb N₂, which is thought to be due to the formation of an amorphous surface layer. Dehydration of Ni and Co STA-12 causes crystallographic distortion. Three phases were isolated for Ni STA-12: removal of physically adsorbed water results in retention of rhombohedral symmetry, while dehydration at 323 K removes some coordinated water forming a triclinic structure. A fully dehydrated structure (dehydrated at 423 K) was solved from synchrotron data (a = 6.03475(5) Å, b = 14.9156(2) Å, c = 16.1572(7) Å, α = 112.5721(7)°, β = 95.7025(11)°, γ = 96.4950(11)°). The dehydration mechanism, followed by UV-vis and Infra-red spectroscopy, involves removal of water from the Ni²⁺ cations and full coordination of two out of three of the phosphonate tetrahedra forming three crystallographically distinct Ni and P atoms. No structural distortion takes place on dehydration of Ni and Co STA-12 prepared using the methylated bisphosphonate, and the solids give a higher N₂ uptake as a result. Dehydrated Ni and Co STA-12 were tested for adsorption performance for fuel related gases and probe molecules. Investigations were undertaken at low temperature with H₂, CO and CO₂, and ambient temperature with CO₂, CH₄, CH₃CN, CH₃OH and large hydrocarbons. Due to the presence of lower crystallinity, Co STA-12 has an inferior adsorption performance to Ni STA-12, although it has similar adsorption enthalpies for CO₂ at ambient temperature (-30 to -35 kJ mol⁻¹). Ni STA-12 adsorbs similar amounts of CO₂ and N₂ at low temperature, indicating the adsorption mechanisms are similar. Also, it adsorbs 10 × more CO₂ than CH₄ at low pressure, meaning it could be used for separation applications. Ni STA-12 adsorbs 2 mmol g⁻¹ H₂ with an enthalpy of -7.5 kJ mol⁻¹, the uptake being due to adsorption on only one-third of the Ni²⁺ cations. The uptake for CO is 6 mmol g⁻¹, with adsorption enthalpies ranging from -24 to -14 kJ mol⁻¹. This uptake is due to adsorption on all the Ni²⁺, meaning the adsorption enthalpies are high enough to allow the structure to relax. This is also observed for adsorption of CH₃CN and CH₃OH, where there is a return to rhombohedral symmetry after uptake. The adsorption sites in dehydrated Ni and Co STA-12 were investigated via Infra-red spectroscopic analysis of adsorbed probe molecules (H₂, CO, CO₂, CH₃CN and CH₃OH). The results indicate the adsorption sites at both low and ambient temperature are the metal cations and the P=O groups. The metal cation sites are also characterised as Lewis acids with reasonable strength. STA-12 was shown to have acidic activity for the liquid phase selective oxidations of 1-hexene and cyclohexene, although there is evidence active sites are coordinated by products and/or solvents during the reaction. STA-12 also demonstrates basic activity for the Knoevenagel condensation of ethyl cyanoacetate and benzaldehyde. Modification of STA-12 by adsorption of diamine molecules causes a slight increase in the basicity, and the highest conversions are where water and diamine molecules are both present.

546.3