Nathalie Jarroux

Hyphenation of surface plasmon resonance imaging to matrix-assisted laser desorption ionization mass spectrometry by on-chip mass spectrometry and tandem mass spectrometry analysis.

Most of the recent developments aiming to the coupling between surface plasmon resonance (SPR) and mass spectrometry (MS) are based on the use of a biochip with a limited number of flow cells requiring elution steps for the recovery of the captured biomolecules. In this work, a direct on-chip MALDI-MS detection is presented using a SPRi-sensor biochip in a microarray format that allows a multiplex SPR-MS analysis. The biochip gold surface was functionalized by a self-assembled monolayer (SAM) of short polyoxyethylene (POE) chains carrying a N-hydroxysuccinimide (NHS) group for the immobilization of biomolecules. The SPR measurement of the interaction of grafted antibodies anti-beta-lactoglobulin and anti-ovalbumin with their corresponding antigens indicated that the POE-NHS SAM preserved the binding activity of the antibodies immobilized on the biochips surface. SPR-MS experiments were carried out through MALDI-MS detection of the retained antigens (beta-lactoglobulin and ovalbumin) directly from the biochip surface. Mass spectra were obtained from each distinct spot on the arrayed biochips. Femtomole amounts of specifically retained antigen proteins as determined by SPR were sufficient to obtain good quality mass spectra. These mass spectra showed protein ions corresponding to the specific antigen, without any trace of nonspecific binding. The underivatized portion of the chip was also devoid of nonspecifically bound proteins, indicating that the functionalization of the biochips surface by short polyoxyethylene chains greatly minimizes the unspecific binding. In addition, it allowed on-chip digestion of the specifically bound analyte and coupling with MS/MS experiments, opening numerous applications in the proteomic field.

Comparative analysis of the photo-oxidation of polystyrene and poly(α-methylstyrene)

Abstract The photo-oxidation of poly(α-methylstyrene) (PαMS) has been studied by FTIR and mass spectroscopy. The samples have been submitted to various conditions of irradiation under oxygen, with different irradiation sources and at several temperatures. SF 4 and NH 3 treatments and photolysis under vacuum have been carried out on the photo-oxidized samples. The results obtained were compared to those obtained in the same conditions of irradiation for polystyrene samples. An identification of the photoproducts is proposed with their main ways of formation.

Amphiphilic Poly[(propylene glycol)-block-(2-methyl-2-oxazoline)] Copolymers for Gene Transfer in Skeletal Muscle

Amphiphilic triblock copolymers such as poly(ethylene glycol‐b‐propylene glycol‐b‐ethylene glycol) PE6400 (PEG13‐PPG30‐PEG13) have been recently shown to promote gene transfer in muscle. Herein we investigated the effect of a chemical change of the PEG moiety on the transfection activity of these compounds. We synthesized new amphiphilic copolymers in which the PEG end blocks are replaced by more hydrophilic poly(2‐methyl‐2‐oxazoline) (PMeOxz) chains of various lengths. The resulting triblock PMeOxz‐PPG‐PMeOxz compounds were characterized by NMR, SEC, TGA, and DSC techniques and assayed for in vivo muscle gene transfer. The results confirm both the block structure and the monomer unit composition (DPPG/DPMeOxz) of the new PPG34‐PMeOxz41 and PPG34‐PMeOxz21 triblock copolymers. Furthermore, in vivo experiments show that these copolymers are able to significantly increase DNA transfection efficiency, despite the fact that their chemical nature and hydrophilic character are different from the poloxamers. Overall, these results show that the capacity to enhance DNA transfection in skeletal muscle is not restricted to PEG‐PPG‐PEG arrangements.

Two Independent Ways of Preparing Hypercharged Hydrolyzable Polyaminorotaxane

The aim of this work is to synthesize new PEO-based polyrotaxanes from modified cyclodextrins. Two strategies are discussed and compared. In the first, a pseudopolyrotaxane was formed between alpha,omega- PEO dimethacrylate and alpha-cyclodextrin. A coupling reaction between 1-pyrenebutyric acid N-hydroxysuccinimide ester was carried out to block the cyclic molecules onto the PEO. Cyclodextrins of the supramolecular assemblies were then oxidized using sodium periodate and reacted with spermine to form a potentially highly charged polyrotaxane. In the second strategy, cyclodextrins were first modified, and used to form the polyrotaxane through the pseudopolyrotaxane synthesis followed by the blocking reaction. Acidic titration allowed quantifying the number of amine functions borne by the supramolecular assemblies through two variables: the number of rings per polymer chain and the number of spermine groups per cyclic molecule. The supramolecules obtained by both strategies are discussed.

Biomarkers probed in saliva by surface plasmon resonance imaging coupled to matrix-assisted laser desorption/ionization mass spectrometry in array format

Detection of protein biomarkers is of major interest in proteomics. This work reports the analysis of protein biomarkers directly from a biological fluid, human saliva, by surface plasmon resonance imaging coupled to mass spectrometry (SPRi-MS), using a functionalized biochip in an array format enabling multiplex SPR-MS analysis. The SPR biochip presented a gold surface functionalized by a self-assembled monolayer of short poly(ethylene oxide) chains carrying an N-hydroxysuccinimide end-group for the immobilization of antibodies. The experiments were accomplished without any sample pre-purification or spiking with the targeted biomarkers. SPRi monitoring of the interactions, immune capture from the biochip surface, and finally on-chip matrix-assisted laser desorption/ionization-MS structural identification of two protein biomarkers, salivary α-amylase and lysozyme, were successively achieved directly from saliva at the femtomole level. For lysozyme, the on-chip MS identification was completed by a proteomic analysis based on an on-chip proteolysis procedure and a peptide mass fingerprint.

Analysis of a Polydisperse Polyrotaxane Based on Poly(ethylene oxide) and α-Cyclodextrins Using Nanoelectrospray and LTQ-Orbitrap

Polyrotaxanes (PR) are among the most studied interlocked molecules in the field of supramolecular chemistry. Cyclodextrin based polyrotaxanes (CD based PRs) are well-known to be difficult to analyze by mass spectrometry (MS). Nanoelectrospray (nanoESI) employed during mass spectrometry (MS) and tandem mass spectrometry (MS/MS) experiments turns out to be particularly useful to analyze these noncovalent assemblies. While ESI/nanoESI based spectra usually contain multicharged species which greatly complicate the interpretation, particularly for such complex mixtures analysis, the hyphenation with a high resolution analyzer such as Orbitrap could overcome this limitation. This Article reports efforts to achieve a detailed structural deciphering by nanoESI-MS and nanoESI-MS/MS of CD based PRs constituted of αCDs, unmodified or surrounded by 1 or 2 sulfation(s), which were threaded along polydisperse poly(ethylene oxide) α,ω-dipyrenyl chains. The described method is more sensitive and less sample consuming than a typical NMR experiment and in good agreement with size-exclusion chromatography (SEC) results. Moreover, as compared to MALDI-TOF MS analysis, all populations were presumably elucidated without discrimination effect. Therefore, this MS development allowed us to estimate the PR sample content with 16 to 35 ethylene oxide units, 1 to 5 αCDs threaded, and 0 to 10 sulfo groups grafted on the overall CDs. Finally, the method afforded the possibility to unambiguously attribute supramolecular architectures from 2276.0278 to 7767.8342 g·mol(-1) corresponding to poly[2]- to poly[6]rotaxanes.

Optimized Synthesis According to One-Step Process of a Biobased Thermoplastic Polyacetal Derived from Isosorbide

This paper describes both the synthesis and characterization of a biobased and non-aromatic polyacetal produced from the reaction between isosorbide and methylene chloride. The reaction was conducted in an aprotic dipolar and harmless solvent using a one-step, fast and economical procedure. The chemical composition of this polymer was investigated using Nuclear Magnetic Resonance and Fourier Transform Infra-Red spectroscopies. The molecular weights were examined by size exclusion chromatography and MALDI-TOF spectrometry. The synthesis conditions (concentration, mixing speed, solvent nature, stoichiometry, addition mode of one reactan) were found to strongly influence both polymer architecture and reaction yield. Under moderated stirring conditions, the polyacetal was characterized by a larger amount of macro-cycles. Inversely, under higher intensity mixing and with an excess of methylene chloride, it was mainly composed of linear chains. In this latter case, the polymeric material presented an amorphous morphology with a glass transition temperature (Tg) close to 55 °C. Its degradation temperature was evaluated to be close to 215 °C using thermogravimetry according to multi-ramp methodology. The chemical approach and the physicochemical properties are valuable in comparison with that characteristic of other isosorbide-based polyacetals.

Evaluation of the Effect of Chemical or Enzymatic Synthesis Methods on Biodegradability of Polyesters

This work compares the biodegradability of polyesters produced by an esterification reaction between glycerol and oleic di-acid (D 18:1) issued from green chemical pathways, via either classical thermo-chemical methods, or an enzymatic method using the immobilized lipase of Candida antartica B (Novozym 435). An elastomeric polymer synthesized by enzymatic catalysis is more biodegradable than an elastomeric thermo-chemical polyester synthesized by a standard chemical procedure. This difference lies in percentage of the dendritic motifs, in values of the degree of substitution, and certainly in cross-links inducing an hyper-branched structure less accessible to the lipolytic enzymes in a waste treatment plant. However, when the elastomeric polymer synthesized by enzymatic catalysis is processed at high temperature as required for certain industrial applications, it presents an identical rate of biodegradation than the chemical polyester. The advantages of the thermo-chemical methods are greater speed and lower cost. Enzymatic synthesis appears be suited to producing polyesters, devoid of metallic catalysts, which must be used without processing at high temperature to keep a high biodegradability.