Caractérisation par microspectroscopie confocale Raman de la diffusion cutanée d'actif : optimisation des paramètres instrumentaux et méthodologiques en vue d'applications in vivo. / Characterization of actives diffusion through the skin by confocal Raman microspectroscopy : optimization of instrumental and methodological parameters for in vivo applications.

Tfaili, Sana

14 February 2012

La microspectroscopie Raman confocale apparait comme un outil à fort potentiel pour l'analyse in vivo de la peau, avec des applications innovantes en dermatologie et cosmétologie. Cette technique biophotonique permet d'accéder à des informations moléculaires très spécifiques d'un échantillon ; et ceci de façon totalement non destructive et sans aucun marquage ni préparation particulière. Les travaux référencés ont porté sur la caractérisation des constituants cutanés, l'évaluation du taux d'hydratation, le suivi de la perméation d'actif ou encore le diagnostic des lésions tumorales de la peau. Ces études ont été réalisées avec des configurations instrumentales très diverses. En vue de la conception d'une nouvelle micro-sonde Raman confocale, cette thèse a permis d'établir un cahier des charges précis ; les paramètres instrumentaux ont été définis et leurs effets sur la qualité des enregistrements Raman (fluorescence parasite, rapport signal sur bruit, atténuation du signal en profondeur) ont été évalués. En particulier, l'effet de la longueur d'onde d'excitation, paramètre clé en spectroscopie Raman, a été analysé. Dans nos expérimentations, la répétabilité et la variabilité du signal Raman ont également été prises en compte. Dans le but d'évaluer l'approche Raman pour l'analyse de la perméation cutanée d'actif, la diffusion cutanée de deux molécules (caféine et resvératrol) appliquées en faibles concentrations a été suivie sur un microspectromètre Raman confocal avec des paramètres d'acquisition similaires à ceux définis pour la micro-sonde. Nous avons montré la possibilité d'enregistrer des cinétiques de diffusion, et également mis en évidence des points limitatifs spécifiques de ces études expérimentales. / Confocal Raman microspectroscopy seems to be a tool with strong potential for in vivo skin analyses, and for innovative applications in dermatology and cosmetology fields. This biophotonic technique allows access to very specific molecular information non-destructively and without any particular skin labeling or sample preparation. The referenced work focused on the characterization of the cutaneous constituents, the evaluation of the rate of skin hydration, the monitoring of active ingredient permeation or diagnosis of tumoral skin lesions. These studies were performed with a variety of instrumental configurations. In view of the design of a new confocal Raman micro-probe, this thesis has established a registry of precise specifications; the instrumental parameters were defined, and their effects on the quality of the Raman records (parasite fluorescence, signal to noise ratio, signal attenuation in depth) were evaluated. In particular, the impact of the excitation wavelength, a key parameter in Raman spectroscopy, was analyzed. In our experiments, the reproducibility and the variability of the Raman signal were also considered. In order to evaluate the Raman approach for the analysis of cutaneous permeation of active ingredients, the cutaneous diffusion of two molecules (caffeine and resveratrol) applied in low concentrations were monitored by confocal Raman microspectroscopy using the acquisition parameters defined for the micro-probe. We have demonstrated the possibility of recording diffusion kinetics and at the same time unraveled specific limitations of these experimental studies.

Microspectroscopie Raman confocale

Caractérisation in vivo de la peau

Perméation cutanée d\'actif

Paramètres instrumentaux

Points limitatifs expérimentaux

Confocal Raman microspectroscopy

In vivo skin characterization

Cutaneous permeation of actives

Instrumental parameters

Limiting experimental points

610

Colonisation de la viande par Escherichia coli O157∶H7 : caractérisation moléculaire, cellulaire et tissulaire des interactions / Meat colonisation by Escherichia coli O157∶H7 : molecular, cellular and tissue characterisation of the interactions

Chagnot, Caroline

02 April 2014

Escherichia coli O157:H7 est le sérotype le plus souvent incriminé lors de toxi-infection alimentaire par les E. coli entérohémorragiques (EHEC). Il peut être associé, dans les cas les plus graves, à des colites hémorragiques mortelles et au syndrome hémolytique et urémique (SHU), touchant essentiellement les jeunes enfants. Le vecteur alimentaire le plus courant lors de ces contaminations est le boeuf haché. L’étape primaire de la contamination bactérienne se situe lors de l'abattage où les bactéries peuvent être transférées de la peau à la carcasse. Une gaine conjonctive entoure les muscles, sa composition protéique, similaire à la matrice extracellulaire (ECM), pourrait jouer un rôle dans l'adhésion bactérienne. Dans un premier temps, l’étude de l'adhésion et de la colonisation des bactéries aux protéines majeures de l’ECM musculaire, a révélé une forte influence des conditions de croissances sur l’adhésion, l'adhésion étant maximale à 25°C et pH7, en particulier aux collagènes I et III. Chez les EHEC, diverses protéines de surfaces peuvent être potentiellement impliquées dans l’adhésion à l’ECM. Le rôle d'un autotransporteur, l'antigène 43 (Ag43), dans l'autoagrégation, l'adhésion et la formation de biofilm, a été établit chez E. coli O157:H7 EDL933. Par la suite, les interactions entre E. coli O157:H7 et la viande ont été étudiées sur deux muscles modèles de types métabolique et contractile opposés (Soleus oxidatif lent et EDL, glycolytique rapide), caractérisés par microspectroscopie de fluorescence UV couplée au rayonnement synchrotron. Les différents types de fibres musculaires ainsi que l’effet d’une anoxie prolongée simulant la maturation des viandes ont été discriminés par leurs réponses spectrales après une excitation à 275 nm. Un tropisme bactérien plus élevé pour le muscle soleus que pour le muscle EDL a été clairement observé. Bien qu'E. coli O157:H7 adhère de manière similaire aux différents types de fibres musculaires, l'adhésion des bactéries se fait essentiellement au niveau de l'ECM, mettant en évidence le rôle clé de l'ECM et du tissu conjonctif musculaire dans l’adhésion des E. coli O157:H7 à la viande. Ces travaux de recherche sur l’adhésion bactérienne aux muscles squelettiques aux niveaux moléculaires, cellulaires et tissulaires fournissent les premières connaissances sur la physiologie des EHEC lors de la contamination de la viande et constituent un pré-requis indispensable au développement de pratiques et de stratégies innovantes afin de réduire le risque de contamination des viandes. / Escherichia coli O157:H7 is the most prevalent serotype involved in foodborne infection by enterohemorrhagic E. coli (EHEC). It is associated with life-threatening hemorrhagic colitis and the hemolyticuremic syndrome (HUS), which essentially affect young children. The major food vector of EHEC contamination is ground beef. The primary bacterial contamination occurs during the slaughter, essentially at dehiding stage where bacteria can be transferred from hides to carcasses. The connective tissue surrounding the muscle, highly similar to extracellular matrix (ECM) could potentially be a support for bacterial adhesion. When investigating the adhesion and colonization to the main muscle fibrous ECM proteins, the great influence of growth conditions on subsequent bacterial attachment was shown. Maximal adhesion to ECM proteins occurred at 25°C and pH 7, especially to collagens I and III. In EHEC, various surface-exposed protein determinants can be expressed and potentially involved in ECM adhesion. Investigating the autoaggregation, bacterial adhesion and biofilm formation, the involvement of Antigen 43 (Ag43), an autotransporter protein, was demonstrated in E. coli O157:H7 EDL933. Then, the attachment of E. coli O157:H7 to the meat was determined on two different model muscles, with different contractile and metabolic characteristic (Soleus oxidative, slow and EDL glycolytic, fast), previously characterized by UV microspectroscopy coupled to synchrotron radiation fluorescence. The different of muscle fiber types and the effect of a prolonged anoxia simulating maturing meat were discriminated by their spectral responses after excitation at 275 nm. It clearly appeared that bacteria displayed differential tropism as function of the muscle types, higher for the Soleus than the EDL muscles. While E. coli O157:H7 adhered similarly to the different types of muscle fibers, bacterial adherence essentially occurred at the ECM, pinpointing the key role of connective tissue for E. coli O157:H7 adhesion to meat. This first comprehensive investigation of bacterial adhesion to skeletal muscles at molecular, cellular and tissue levels provides new insight in the physiology of the colonization of meat by EHEC and constitutes a prerequisite for the development of innovative practices and strategies to minimize the risk of meat contamination.

Escherichia coli entérohémorragiques

Contamination alimentaire

Adhésion bactérienne

ECM

Muscle squelettique

Types de fibres

Viande

Microspectroscopie de fluorescence UV

Enterohemorrhagic Escherichia coli

Food contamination

Bacterial adhesion

ECM

Skeletal muscle

Fiber types

Meat

UV microspectroscopy

Vibrational Microspectroscopic Studies of Biomedical Conditions Using Model Systems

Gautam, Rekha

January 2014

Over the last century, despite enormous advancements in biomedical research and the development of sophisticated analytical instruments many diseases continue to be a burden on humankind particularly on the aged. This is because of a lack of complete understanding of the pathogenesis and specific therapies. Due to the complexity involved, we need to explore all facets of diagnosis and therapies. Therefore, there is a requirement for different strategies to combat these diseases. A quick diagnosis is the primary step towards improving treatment and increasing the chance of survival. To realize this goal we entail to monitor multiple biomarkers which will also help us to understand the progression of disease. Mid-Infrared (MIR) and Raman spectroscopic techniques are well established analytical methods to understand the molecular structure and chemical composition of heterogeneous systems. These techniques are rapid, non-destructive and offer multiple component analysis (global/multiplex) in a single measurement without any labels. Importantly, biological materials like proteins, carbohydrates, lipids, nucleic acids etc. have unique structures and therefore we can obtain unique spectral fingerprints of these molecules in different physiological and pathological conditions. This will provide a potential route to obtain diagnostic markers for diseases. Also, to improve the ability to diagnose and treat human diseases much more efficiently, understanding the mechanisms involved in the progression of disease is necessary. It would be time consuming and often unethical to perform these studies directly on humans. Therefore, there is a need for model organisms to explore the complexity of various diseases. A model organism is an animal, plant or microbe that is being studied to understand a range of biological phenomena. They should meet certain criteria such as short life cycles, easy to breed and maintain in large numbers under laboratory conditions, and the data generated through use of the model should be applicable to other higher organisms like humans. The microbial system, mouse, rat, Drosophila (fruitfly), C Elegans (nematode worm) and zebrafish are being used extensively for this purpose. The most adaptable organisms to study diseases in humans are the mice as they share almost 99% of their genes with humans. Mice are similar to humans in most physiological and pathological features such as nervous, cardiovascular, immune, liver etc. In addition to mice, Drosophila melanogaster (fruitfly) has been used for years as an attractive model organism to understand the mechanisms of underlying human diseases. This is because 75% of human disease genes have counterparts in Drosophila and it meets the above mentioned criteria to be a model organism. It also plays an important role for studying genetics and development biology. The average life span of Drosophila is 60-80 days; therefore it is a suitable model to study age related diseases. In the present thesis, the ability to probe low-micrometer domains using Raman and Fourier Transform Infrared (FTIR) microspectroscopy was utilized to monitor the chemical changes during various biomedical conditions using model systems. Chapter 1 of the thesis discusses about the origin of Raman and FTIR microspectroscopy along with instrumentation and applications. Various data analysis methods (both univariate & multivariate) and the validation criterion are described in chapter 2. Depending on the objective of the study and based on the technique (Raman or FTIR) used, one (or more) of these methods can be applied for effective interpretation of the data. Further, the thesis includes four different investigations; a) the FTIR spectroscopic study of hepatotoxicity due to acetaminophen using mice as model, b) the Raman spectroscopic studies of muscle-related disorders using Drosophila as a model, c) Vibrational spectroscopic study of septic shock using mice as model, d) Surface Enhanced Raman Spectroscopy (SERS) study of serum components using Lab-on-a-chip (LOC). The first part comprises mainly the FTIR microspectroscopy study of hepatotoxicity in mice post oral dosing of acetaminophen (paracetamol), which is extensively used worldwide as an analgesic and antipyretic drug (chapter 3). The infrared spectra of acetaminophen treated livers in BALB/c mice show a decrease in glycogen and an increase in amounts of cholesteryl esters and DNA. Importantly, analysis of sera identified the lowering of glycogen and increase in DNA and chlolesteryl esters earlier than the increase in alanine aminotransferase, which is routinely used to diagnose liver damage. Similar changes are also observed in C57BL/6 and Nos2−/− mice. Revert experiments using an antidote (L-methionine) demonstrate that depletion in glycogen and increase in DNA are abrogated with pre-treatment, but not post-treatment, with L-methionine. In the second study Raman spectroscopy is applied to discriminate between various muscle defects in Drosophila, since it can provide a unique molecular fingerprint of tissues on the basis of their biochemical composition (chapter 4). Raman spectra were collected from Indirect Flight Muscles (IFM) of mutants upheld1 (up1), heldup2 (hdp2), Myosin heavy chain7 (Mhc7), Actin88FKM88 (Act88FKM88), upheld101 (up101) and Canton-S (CS) for both 2 and 12-days old flies. The difference spectra (mutant minus CS) of all mutants have shown an increase in nucleic acids (DNA/RNA) content along with an increase in β-sheet and/or random coil content at the expense of α-helix. Interestingly, 12th day sample of up1 & Act88FKM88 exhibit significantly higher levels of glycogen and carotenoids than CS. A Principal Components based Linear Discriminant Analysis (PC-LDA) classification model was developed, which classifies the mutants according to their pathophysiology and yielded overall accuracy (OA) of 97% and 93% for 2 and 12-days old flies respectively. up1 & Act88FKM88 (nemaline myopathy phenotypes) form a group which is clearly separated in a Linear Discriminant (LD) Plane from up101 & hdp2 (cardiomyopathy phenotypes). In the third part we investigated septic shock, a life threatening condition associated with multiple organ dysfunctions, in mice (chapter 5). Salmonella typhimurium were given to BALB/c and 129/SvJ mice via the intraperitoneal route to induce infection. Liver, spleen and sera samples were studied using FTIR microspectroscopy. The infrared spectra of liver, spleen and serum samples in BALB/c (Nramp1-deficient) mice show significant spectral changes as early as 1 hour post infection but spleen shows changes only after 6 hour. Interestingly, 129/SvJ (Nramp1-sufficient) mice were resistant to sepsis and show significant spectral changes only at 12 hour post infection. This study demonstrates that suppression of Nramp-1, a renowned gene known to control susceptibility to infections by intracellular bacteria can be an effective cure for sepsis. The final study presented in this thesis demonstrates the use and benefits of lab-on-a-chip (LOC) devices in surface enhanced Raman spectroscopy (SERS) which is used to enhance the weak Raman signals (chapter 6). Most of the diseases have related proteins or analytes present in serum although in early stages their concentration in blood are low. The idea is to detect at low concentration using SERS the serum components which are related to progression of disease. Here, we have compared the effect of different aggregating agents on silver colloids and the resulting enhancement in Raman signals for tryptophan and Bovine Serum Albumin (BSA). Reproducibility issues, the key concern of static phase SERS, can be overcome by performing SERS spectroscopic measurements in automated flow cells. Further, pyridine and tryptophan were used to demonstrate SERS in a segmented flow system. The spectra from different drops were compared and demonstrate the high reproducibility in comparision to static SERS. Lastly, chapter 7 summarizes the entire work of the present thesis with future prospects of Raman and FTIR microspectroscopy to study the progression mechanism of various diseases like neurodegenerative diseases which is easy to follow in drosophila due to their short life span. Also, technological developments in the field of nanotechnology and micro-fluidics will enable the detection of early biochemical changes in bodily fluids such as urine, cerebral spinal fluid, tears etc. Building on the results demonstrated in this thesis, hopefully label-free vibrational (Raman and FTIR) microspectroscopic studies using model organisms would help in understanding the underlying mechanisms of progression of various other diseases which in turn would facilitate the development of effective therapies.

Vibrational Microspectroscopy

Raman Spectroscopy

Fourier Transform Infrared Spectroscopy

Biomedical Vibrational Spectroscopy

Mid-Infrared (MIR) Spectroscopy

Raman Microspectrometer

Biomedical Vibrational Spectroscopy

Surface Enhanced Raman Spectroscopy

Biomedical Engineering

Cardio-myopathy Phenotypes

Inorganic and Physical Chemistry

The Scanning Transmission X-Ray Microscope at BESSY II / Das Rasterröntgenmikroskop bei BESSY II

Wiesemann, Urs

09 December 2003

No description available.

Mathematics and Computer Science

Rasterröntgenmikroskop

STXM

NEXAFS

XANES

BESSY II

Spektromikroskopie

Mikrospektroskopie

Spektroskopie

530 Physik

Scanning Transmission X-Ray Microscope

STXM

NEXAFS

XANES

BESSY II

Spectromicroscopy

Microspectroscopy

Spectroscopy

33.18

33.07

RQE 920: Röntgenmikroskopie

Röntgenanalyse {Physik}

RRG 000: Molekülspektroskopie {Physik}