The Vanadyl Ribonucleoside Complex Inhibits Ribosomal Subunit Formation in Staphylococcus Aureus

Frazier, Ashley D., Champney, W. Scott

01 September 2012

Objectives: The discovery of new antibiotic targets is important to stem the increase in antibiotic resistance to most currently used antimicrobials. The bacterial ribosome is a major target for a large number of antibiotics that inhibit different aspects of translation. Most of these antimicrobial agents also inhibit ribosomal subunit formation as a second cellular target. Precise subunit assembly requires the activity of several distinct RNases for proper rRNA processing. The present work shows that the vanadyl ribonucleoside complex (VRC) inhibited RNases in Staphylococcus aureus involved in ribosomal subunit formation without an effect on translation. Methods: Methicillin-susceptible and -resistant strains of S. aureus were examined for the inhibitory effects of VRC on cell viability by colony counting. Protein synthesis rates were measured by isotopic methionine incorporation. Ribosome synthesis was measured by radiolabelled uridine incorporation into ribosomal subunits as displayed on sucrose gradients. Pulse and chase radiolabelling was used to measure subunit synthesis rates. RNA turnover was determined by a gel on a chip assay. Results: The rates of subunit synthesis and the amounts of both subunits were significantly reduced in the presence of the compound. Ribosomal RNA was degraded and cell viability was reduced as a consequence. VRC also stimulated the inhibitory effects of a macrolide and an aminoglycoside antibiotic on ribosome formation. Conclusions: Bacterial ribosomal subunit synthesis was specifically impaired in VRC-treated cells, with the rates and amounts of both subunits reduced. Cell viability was significantly reduced and rRNA turnover was stimulated.

aminoglycosides

macrolides

protein synthesis

ribosome formation

VRC

Biomedical Sciences

Design, Analysis and Implementation of Multiphase Synchronous Buck DC-DC Converter for Transportable Processor

Nguyen, Huy

13 May 2004

As laptop mobile users expect more application features and long battery life, the processor current has to increase to response the demanding while the voltage has to decease to save the power loss. Therefore, it is necessary for a system designer to improve the efficiency of the voltage regulator converter (VRC) for the processor. Laptop processor architecture is more complicated than desktop because of different mode operations and their transitions. The laptop processor runs at different voltage levels for each operation mode to save the battery life. Therefore, the VRC needs to supply the correct and stable voltage to the processor. In this thesis, an analysis of power loss is derived to estimate the efficiency and switching frequency, three widely current sensing methods are discussed, two methods to compensate for the thermal resistance in loss less current sense methods are proposed, the tolerance of load line base on the component's tolerance in the converter is analyzed, the equation to estimate the output capacitance is derived, and the small signal analysis of multiphase synchronous buck converter with the droop current loop is derived. A hardware prototype was implemented base on 4-phase synchronous buck topology to provide high efficiency and lower cost solution. The results of load line meets the Intel specification in different modes of operation, provides the best transient responses, and meets the specification during the load transient. The control loop lab measurement is also matched with the analysis and simulation. / Master of Science

Multiphase Synchronous Buck

VRC

Laptop Processor

Load Line

Surveillance non invasive de la réponse neuroimmunitaire fœtale à l’infection

Durosier, Lucien Daniel

12 1900

No description available.

Foetus

RCF

EEG

VRC

monitoring

acidose

asphyxie

hypoxie

inflammation

LPS

Fréquence d'échantillonnage

étude clinique

Travail

Fetus

FHR

HRV

acidosis

asphyxia

hypoxia

sampling rate

clinical study

labour

Heart rate variability and respiration signals as late onset sepsis diagnostic tools in neonatal intensive care units / Variabilité du rythme cardiaque et de la respiration comme outils de diagnostic d'apparition tardive de sepsis dans les unités de soins intensifs néonataux

Wang, Yuan

19 December 2013

Le sepsis tardif, défini comme une infection systémique chez les nouveaux nés âgés de plus de 3 jours, survient chez environ 7% à 10% de tous les nouveau-nés et chez plus de 25% des nouveau-nés de très faible poids de naissance qui sont hospitalisés dans les unités de soins intensifs néonatals (USIN). Les apnées et bradycardies (AB) spontanées récurrentes et graves sont parmi les principaux indicateurs précoces cliniques de l'infection systémique chez les prématurés. L'objectif de cette thèse est de déterminer si la variabilité du rythme cardiaque (VRC), la respiration et l'analyse de leurs relations aident au diagnostic de l'infection chez les nouveaux nés prématurés par des moyens non invasifs en USIN. Par conséquent, on a effectué l'analyse Mono-Voie (MV) et Bi-Voies (BV) sur deux groupes sélectionnés de nouveau-nés prématurés: sepsis (S) vs. non-sepsis (NS). (1) Tout d'abord, on a étudié la série RR non seulement par des méthodes de distribution (moy, varn, skew, kurt, med, SpAs), par les méthodes linéaire: le domaine temporel (SD, RMSSD) et dans le domaine fréquentiel (p_VLF, p_LF, p_HF), mais aussi par les méthodes non–linéaires: la théorie du chaos (alphas, alphaF) et la théorie de l'information (AppEn, SamEn, PermEn, Regul). Pour chaque méthode, nous étudions trois tailles de fenêtre 1024/2048/4096, puis nous comparons ces méthodes afin de trouver les meilleures façons de distinguer S de NS. Les résultats montrent que les indices alphaS, alphaF et SamEn sont les paramètres optimaux pour séparer les deux populations. (2) Ensuite, la question du couplage fonctionnel entre la VRC et la respiration nasale est adressée. Des relations linéaires et non-linéaires ont été explorées. Les indices linéaires sont la corrélation (r²), l'indice de la fonction de cohérence (Cohere) et la corrélation temps-fréquence (r2t,f) , tandis que le coefficient de régression non-linéaire (h²) a été utilisé pour analyser des relations non-linéaires. Nous avons calculé les deux directions de couplage pendant l'évaluation de l'indice h2 de régression non-linéaire. Enfin, à partir de l'ensemble du processus d'analyse, il est évident que les trois indices (r2tf_rn_raw_0p2_0p4, h2_rn_raw et h2_nr_raw) sont des moyens complémentaires pour le diagnostic du sepsis de façon non-invasive chez ces patients fragiles. (3) Après, l'étude de faisabilité de la détection du sepsis en USIN est réalisée sur la base des paramètres retenus lors des études MV et BV. Nous avons montré que le test proposé, basé sur la fusion optimale des six indices ci-dessus, conduit à de bonnes performances statistiques. En conclusion, les mesures choisies lors de l'analyse des signaux en MV et BV ont une bonne répétabilité et permettent de mettre en place un test en vue du diagnostic non invasif et précoce du sepsis. Le test proposé peut être utilisé pour fournir une alarme fiable lors de la survenue d'un épisode d'AB tout en exploitant les systèmes de monitoring actuels en USIN. / Late-onset sepsis, defined as a systemic infection in neonates older than 3 days, occurs in approximately 10% of all neonates and in more than 25% of very low birth weight infants who are hospitalized in Neonatal Intensive Care Units (NICU). Recurrent and severe spontaneous apneas and bradycardias (AB) is one of the major clinical early indicators of systemic infection in the premature infant. Various hematological and biochemical markers have been evaluated for this indication but they are invasive procedures that cannot be repeated several times. The objective of this Ph.D dissertation was to determine if heart rate variability (HRV), respiration and the analysis of their relationships help to the diagnosis of infection in premature infants via non-invasive ways in NICU. Therefore, we carried out Mono-Channel (MC) and Bi-Channel (BC) Analysis in two selected groups of premature infants: sepsis (S) vs. non-sepsis (NS). (1) Firstly, we studied the RR series not only by distribution methods (moy, varn, skew, kurt, med, SpAs), by linear methods: time domain (SD, RMSSD) and frequency domain (p_VLF, p_LF, p_HF), but also by non-linear methods: chaos theory (alphaS, alphaF) and information theory (AppEn, SamEn, PermEn, Regul). For each method, we attempt three sizes of window 1024/2048/4096, and then compare these methods in order to find the optimal ways to distinguish S from NS. The results show that alphaS, alphaF and SamEn are optimal parameters to recognize sepsis from the diagnosis of late neonatal infection in premature infants with unusual and recurrent AB. (2) The question about the functional coupling of HRV and nasal respiration is addressed. Linear and non-linear relationships have been explored. Linear indexes were correlation (r²), coherence function (Cohere) and time-frequency index (r2t,f), while a non-linear regression coefficient (h²) was used to analyze non-linear relationships. We calculated two directions during evaluate the index h2 of non-linear regression. Finally, from the entire analysis process, it is obvious that the three indexes (r2tf_rn_raw_0p2_0p4, h2_rn_raw and h2_nr_raw) were complementary ways to diagnosticate sepsis in a non-invasive way, in such delicate patients.(3) Furthermore, feasibility study is carried out on the candidate parameters selected from MC and BC respectively. We discovered that the proposed test based on optimal fusion of 6 features shows good performance with the largest Area Under Curves (AUC) and the least Probability of False Alarm (PFA). As a conclusion, we believe that the selected measures from MC and BC signal analysis have a good repeatability and accuracy to test for the diagnosis of sepsis via non-invasive NICU monitoring system, which can reliably confirm or refute the diagnosis of infection at an early stage.

Nouveau-nés prématurés

Sepsis

Non-sepsis

Système nerveux autonome (SNA)

Variabilité du rythme cardiaque (VRC)

Système respiratoire

Respiration

Méthodes linéaires

Méthodes non-linéaires

Analyse statistique

Étude de faisabilité

Fusion optimale

Courbe ROC

Prise de décision clinique

Informatique médicale

Prédiction

Neonatal intensive care units (NICU)

Premature newborns

Sepsis

Non-sepsis

Autonomic nervous system (ANS)

Heart rate variability (HRV)

Respiratory system

Respiration

Linear methods

Non-linear methods

Statistical analysis

Feasibility study

Optimal fusion

Receiver operating characteristic (ROC)

Clinical decision making

Medical informatics

Prediction