Time-dependent photoionization of azulene: Optically induced anisotropy on the femtosecond scale

We measure the photoionization cross-section of vibrationally excited levels in the S2 state of azulene by femtosecond pump-probe spectroscopy. At the wavelengths studied (349-265 nm in the pump) the transient signals exhibit two distinct and well-defined behaviours: (i) Short-term (on the order of a picosecond) polarization dependent transients and (ii) longer (10 ps - 1 ns) time-scale decays. This letter focuses on the short time transient. In contrast to an earlier study by Diau et al.22 [J. Chem. Phys. 110 (1999) 9785.] we unambiguously assign the fast initial decay signal to rotational dephasing of the initial alignment created by the pump transition.Comment: Chemical Physics Letters (2008

P-31 magnetic resonance spectroscopy in skeletal muscle: Experts' consensus recommendations

Skeletal muscle phosphorus-31 31P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31P MRS methods can probe it. Here we consider basic signal-acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near-infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1H MRS measurements) can help in the physiological/metabolic interpretation of 31P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology

Current pretreatment technologies for the development of cellulosic ethanol and biorefineries

Lignocellulosic materials, such as forest, agriculture, and agroindustrial residues, are among the most important resources for biorefineries to provide fuels, chemicals, and materials in such a way to substitute for, at least in part, the role of petrochemistry in modern society. Most of these sustainable biorefinery products can be produced from plant polysaccharides (glucans, hemicelluloses, starch, and pectic materials) and lignin. In this scenario, cellulosic ethanol has been considered for decades as one of the most promising alternatives to mitigate fossil fuel dependence and carbon dioxide accumulation in the atmosphere. However, a pretreatment method is required to overcome the physical and chemical barriers that exist in the lignin–carbohydrate composite and to render most, if not all, of the plant cell wall components easily available for conversion into valuable products, including the fuel ethanol. Hence, pretreatment is a key step for an economically viable biorefinery. Successful pretreatment method must lead to partial or total separation of the lignocellulosic components, increasing the accessibility of holocellulose to enzymatic hydrolysis with the least inhibitory compounds being released for subsequent steps of enzymatic hydrolysis and fermentation. Each pretreatment technology has a different specificity against both carbohydrates and lignin and may or may not be efficient for different types of biomasses. Furthermore, it is also desirable to develop pretreatment methods with chemicals that are greener and effluent streams that have a lower impact on the environment. This paper provides an overview of the most important pretreatment methods available, including those that are based on the use of green solvents (supercritical fluids and ionic liquids)

Muscular function and energetics in a mouse model of sickle cell disease and identification of the mechanisms involved in proton exchanges between muscle and blood

La drépanocytose est la maladie génétique la plus répandue au monde. Elle est caractérisée par la synthèse d’une hémoglobine anormale S (HbS) et associée à une altération des processus de distribution d’oxygène. Bien que ces anomalies puissent impacter le muscle strié squelettique, ce tissu n’a que très rarement été étudié. L’objectif de ce travail de thèse était de décrire les réponses fonctionnelles et énergétiques du muscle à l’exercice aigu, à l’ischémie – reperfusion et à l’entraînement en endurance dans un modèle de souris drépanocytaires, et d’identifier les mécanismes responsables des échanges de protons entre le muscle et le sang.Des souris drépanocytaires sédentaires et entraînées ont été soumises à des protocoles standardisés de repos – stimulation – récupération et repos – ischémie – reperfusion pendant lesquels la force et le métabolisme énergétique (par spectroscopie de résonance magnétique du phosphore 31) étaient mesurés. Des souris hétérozygotes pour le transporteur de monocarboxylate 1 (MCT1) ont également été soumises au protocole de stimulation. Des analyses in vitro du métabolisme énergétique et des mécanismes de régulation du pH ont également été réalisées.Ce travail a permis de démontrer que les réponses fonctionnelles et énergétiques à l’exercice musculaire et l’ischémie - reperfusion étaient affectées par la présence d’HbS et que l’entraînement en endurance permettait d’améliorer une partie de ces anomalies. Nous avons également observé que MCT1 était responsable de l’entrée des protons dans la cellule au repos, mais peu actif pendant l’exercice.Sickle cell disease (SCD) is the most frequent inherited disorder in the world. It is characterized by the synthesis of an abnormal hemoglobin S (HbS) and associated with impairments in oxygen delivery processes. If these abnormalities could impact skeletal muscle, this tissue has been rarely investigated. The aim of this thesis was to investigate muscular function and energetics in response to acute exercise, ischemia – reperfusion and endurance training in a mouse model of SCD, as well as identify the mechanisms involved in proton exchanges between muscle and blood.Sedentary and trained SCD mice were submitted to protocols of rest – stimulation – recovery and rest – ischemia – reperfusion during which muscular force and energetics (by magnetic resonance spectroscopy of phosphorus 31) were measured. Monocarboxylate transporter 1 (MCT1) haploinsufficient mice were also submitted to the stimulation protocol. Several muscles were sampled and permitted to analyze in vitro enzyme activities, content of proteins involved in pH regulation and some markers of oxidative stress.This thesis demonstrated that muscular function and energetics were impaired in SCD mice in response to both exercise and ischemia – reperfusion and that endurance training could alleviate some of these abnormalities, particularly acting on oxidative processes. We have also observed that MCT1 is involved in proton uptake by myocytes at rest, but its action is less important during exercise

Exacerbated in vivo metabolic changes suggestive of a spontaneous muscular vaso-occlusive crisis in exercising muscle of a sickle cell mouse

International audienceWhile sickle cell disease (SCD) is characterized by frequent vaso-occlusive crisis (VOC), no direct observation of such an event in skeletal muscle has been performed in vivo. The present study reported exacerbated in vivo metabolic changes suggestive of a spontaneous muscular VOC in exercising muscle of a sickle cell mouse. Using magnetic resonance spectroscopy of phosphorus 31, phosphocreatine and inorganic phosphate concentrations and intramuscular pH were measured throughout two standardized protocols of rest – exercise – recovery at two different intensities in ten SCD mice. Among these mice, one single mouse presented divergent responses. A statistical analysis (based on confidence intervals) revealed that this single mouse presented slower phosphocreatine resynthesis and inorganic phosphate disappearance during the post-stimulation recovery of one of the protocols, what could suggest an ischemia. This study described, for the first time in a sickle cell mouse in vivo, exacerbated metabolic changes triggered by an exercise session that would be suggestive of a live observation of a muscular VOC. However, no evidence of a direct cause-effect relationship between exercise and VOC has been put forth

Comparative NMR and NIRS analysis of oxygen-dependent metabolism in exercising finger flexor muscles

International audienceMuscle contraction requires the physiology to adapt rapidly to meet the surge in energy demand. To investigate the shift in metabolic control, especially between oxygen and metabolism, researchers often depend on near-infrared spectroscopy (NIRS) to measure noninvasively the tissue O 2 . Because NIRS detects the overlapping myoglobin (Mb) and hemoglobin (Hb) signals in muscle, interpreting the data as an index of cellular or vascular O 2 requires deconvoluting the relative contribution. Currently, many in the NIRS field ascribe the signal to Hb. In contrast, 1 H NMR has only detected the Mb signal in contracting muscle, and comparative NIRS and NMR experiments indicate a predominant Mb contribution. The present study has examined the question of the NIRS signal origin by measuring simultaneously the 1 H NMR, 31 P NMR, and NIRS signals in finger flexor muscles during the transition from rest to contraction, recovery, ischemia, and reperfusion. The experiment results confirm a predominant Mb contribution to the NIRS signal from muscle. Given the NMR and NIRS corroborated changes in the intracellular O 2 , the analysis shows that at the onset of muscle contraction, O 2 declines immediately and reaches new steady states as contraction intensity rises. Moreover, lactate formation increases even under quite aerobic condition

Do we have to consider acidosis induced by exercise as deleterious in sickle cell disease?

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