BIOENGINEERED SCAFFOLDS TO INDUCE ALIGNMENT AND PROMOTE AXON REGENERATION FOLLOWING SPINAL CORD INJURY

Scaffolds delivered to injured spinal cords to stimulate axon connectivity often act as a bridge to stimulate regeneration at the injured area, but current approaches lack the permissiveness, topology and mechanics to mimic host tissue properties. This dissertation focuses on bioengineering scaffolds through the means of altering topology in injectables and tuning mechanics in 3D-printed constructs as potential therapies for spinal cord injury repair. A self-assembling peptide scaffold, RADA-16I, is used due to its established permissiveness to axon growth and ability to support vascularization. Immunohistochemistry assays verify that vascularized peptide scaffolds promote axon infiltration, attenuate inflammation and reduce astrogliosis. Furthermore, magnetically-responsive (MR) RADA-16I injections are patterned along the rostral-caudal direction in both in-vitro and in-vivo conditions. ELISA and histochemical assays validate the efficacy of MR hydrogels to promote and align axon infiltration at the site of injury. In addition to injectable scaffolds, this thesis uses digital light processing (DLP) to mimic the mechanical heterogeneity of the spinal cord caused by white and gray matter, and demonstrate that doing so improves axon infiltration into the scaffold compared to controls exhibiting homogeneous mechanical properties. Taken together, this work contributes to advancing the field of tissue engineering and regenerative medicine by demonstrating the potential of bioengineered scaffolds to repair the damaged spinal cord

Lubricant as a sticking-scale inhibitor on high temperature sliding contact

Sticking oxide scale is one of the most serious concerns on moving steel surfaces at elevated temperature. However, there has been limited research dedicated to overcoming this issue. In the present work, pin-on-disc testing was carried out to reveal the effects of lubrication on wear characteristics of High Speed Steel sliding against Stainless Steel 316 at 700 °C. Apart from improved friction behavior, the use of inorganic lubricant significantly inhibits material transfer onto the HSS surface which otherwise suffers growing adhered scale during dry sliding contact. In addition, it was found that prolonged exposure to lubrication induces phase transformation of the subsurface iron oxides. The Hematite-to-Magnetite conversion is believed to be a result of complex oxidation and tribological reactions. Multiple characterization techniques were used to thoroughly analyze the worn surfaces, the underlying oxide microstructure and the chemical nature of lubricated interface

Understanding the tribological impacts of alkali element on lubrication of binary borate melt

Melt lubricants have been regarded as an effective class to deliver lubrication on moving mechanical contacts at extreme temperatures. Among the elementary constituents, alkali elements play a critical role in governing the physical-chemical characteristics of the lubricant despite the obscurity regarding their intrinsic roles on the rubbing interfaces. The present study attempts to unfold the effects of sodium on the tribological responses of mating steel pair under borate melt lubrication. It has been found that the involvement of Na inspires a total reversal in lubricating potentials of the lone B2O3melt manifested by remarkable friction reduction, wear inhibition and prolonged load-bearing capacity. These exceptional performances are attributed to the accretion of nanothin Na layers on the contact interfaces. The interfacial occurrences are interpreted from a physico-chemistry perspective while the influences of surface microstructure are also discussed in detail. Multiple characterizations are employed to thoroughly examine the sliding interfaces in multi-dimensions including Scanning Electron Microscopy (SEM), Scanning Transmission Electron Microscopy (STEM) and Atomic Force Microscopy (AFM). In addition, chemical fingerprints of relevant elements are determined by Energy Dispersive Spectroscopy (EDS) and Electron Loss Energy Spectroscopy (EELS)

Microscopic Observation Drug Susceptibility Assay (MODS) for Early Diagnosis of Tuberculosis in Children

MODS is a novel liquid culture based technique that has been shown to be effective and rapid for early diagnosis of tuberculosis (TB). We evaluated the MODS assay for diagnosis of TB in children in Viet Nam. 217 consecutive samples including sputum (n = 132), gastric fluid (n = 50), CSF (n = 32) and pleural fluid (n = 3) collected from 96 children with suspected TB, were tested by smear, MODS and MGIT. When test results were aggregated by patient, the sensitivity and specificity of smear, MGIT and MODS against “clinical diagnosis” (confirmed and probable groups) as the gold standard were 28.2% and 100%, 42.3% and 100%, 39.7% and 94.4%, respectively. The sensitivity of MGIT and MODS was not significantly different in this analysis (P = 0.5), but MGIT was more sensitive than MODS when analysed on the sample level using a marginal model (P = 0.03). The median time to detection of MODS and MGIT were 8 days and 13 days, respectively, and the time to detection was significantly shorter for MODS in samples where both tests were positive (P<0.001). An analysis of time-dependent sensitivity showed that the detection rates were significantly higher for MODS than for MGIT by day 7 or day 14 (P<0.001 and P = 0.04), respectively. MODS is a rapid and sensitive alternative method for the isolation of M.tuberculosis from children

Evaluation of microscopic observation drug susceptibility assay for diagnosis of multidrug-resistant Tuberculosis in Viet Nam

<p>Abstract</p> <p>Background</p> <p>Early diagnosis of tuberculosis (TB) and multidrug resistant tuberculosis (MDR TB) is important for the elimination of TB. We evaluated the microscopic observation drug susceptibility (MODS) assay as a direct rapid drug susceptibility testing (DST) method for MDR-TB screening in sputum samples</p> <p>Methods</p> <p>All adult TB suspects, who were newly presenting to Pham Ngoc Thach Hospital from August to November 2008 were enrolled into the study. Processed sputum samples were used for DST by MODS (DST-MODS) (Rifampicin (RIF) 1 μg/ml and Isoniazid (INH) 0.4 μg/ml), MGIT culture (Mycobacterial Growth Indicator Tube) and Lowenstein Jensen (LJ) culture. Cultures positive by either MGIT or LJ were used for proportional DST (DST-LJ) (RIF 40 μg/ml and INH 0.2 μg/ml). DST profiles on MODS and LJ were compared. Discrepant results were resolved by multiplex allele specific PCR (MAS-PCR).</p> <p>Results</p> <p>Seven hundred and nine TB suspects/samples were enrolled into the study, of which 300 samples with DST profiles available from both MODS and DST-LJ were analyzed. Cording in MODS was unable to correctly identify 3 Mycobacteria Other Than Tuberculosis (MOTT) isolates, resulting in 3 false positive TB diagnoses. None of these isolates were identified as MDR-TB by MODS. The sensitivity and specificity of MODS were 72.6% (95%CI: 59.8, 83.1) and 97.9% (95%CI: 95.2, 99.3), respectively for detection of INH resistant isolates, 72.7% (95%CI: 30.9, 93.7) and 99.7% (95%CI: 98.1, 99.9), respectively for detecting RIF resistant isolates and 77.8% (95%CI: 39.9, 97.1) and 99.7% (95%CI: 98.1, 99.9), respectively for detecting MDR isolates. The positive and negative predictive values (PPV and NPV) of DST-MODS were 87.5% (95%CI: 47.3, 99.6) and 99.3% (95%CI: 97.5, 99.9) for detection of MDR isolates; and the agreement between MODS and DST-LJ was 99.0% (kappa: 0.8, <it>P </it>< 0.001) for MDR diagnosis. The low sensitivity of MODS for drug resistance detection was probably due to low bacterial load samples and the high INH concentration (0.4 μg/ml). The low PPV of DST-MODS may be due to the low MDR-TB rate in the study population (3.8%). The turnaround time of DST-MODS was 9 days and 53 days for DST-LJ.</p> <p>Conclusion</p> <p>The DST-MODS technique is rapid with low contamination rates. However, the sensitivity of DST-MODS for detection of INH and RIF resistance in this study was lower than reported from other settings.</p

Tribochemistry and lubrication of alkaline glass lubricants in hot steel manufacturing

Nowadays, the increasing demand to reduce energy consumption and improve process reliability requires an alternative lubricant with an effective tribological performance and environmentally friendly properties to replace traditional lubricants in hot steel manufacturing. The current work reviews recent comprehensive experimental and theoretical investigations in a new generation of alkaline-based glass lubricants, with phosphate, borate, and silicate being intensively researched. This class of lubricants showed an outstanding friction reduction, anti-wear, and anti-oxidation performance on coupled steel pairs over a wide range of temperatures (from 650 °C to 1000 °C). Each type had different tribochemical reactions within itself and with oxidized steel surfaces, which were largely determined by their chemical nature. In addition, the critical role of each structural component was also determined and corroborated by computational simulation. The theoretical studies at quantum and atomic levels reinforced our experimental findings by providing insights into the reaction mechanism using the static and dynamic simulations of the adsorption of lubricant molecules onto iron oxide surfaces. Additionally, the new reactive molecular dynamics (MD) model developed for alkali phosphate will need to be extended further to consider the realistic operating conditions of these lubricants at the atomic scale

Conversion catalytique de dérivés de l'huile de colza (une nouvelle voie de valorisation chimique)

Dans ce travail de thèse, nous avons étudié la transformation chimique par catalyse hétérogène de l'oléate de méthyle et l'acide oléique, les deux principaux produits issus de l'huile de colza. Les acides gras sont obtenus par une hydrolyse des huiles suivie par une purification par distillation. Les esters méthyliques sont issus de la transestérification des huiles par du méthano1. L'étude paramétrique du craquage catalytique de l'acide oléique a été réalisée sur l'alumine activée, les zéolithes Y et (bêta) et sur les hydrotalcites. Les hydrocarbures aliphatiques en C 15-C21 sont formés majoritairement par le craquage avec l'alumine activée et les hydrotalcites, alors que les zéolithes favorisent la formation des hydrocarbures aromatiques (du benzène au naphtalène). Deux mécanismes de décomposition de l'acide oléique ont pu être proposés et mettent en jeu des réactions d'isomérisation, protonation, craquage en B, cétonisation, transfert d'hydrogène, réduction et déshydratation. L'étude cinétique a permis de calculer des ordres de réaction et des constantes cinétiques qui sont toutefois incorrects car la réaction catalytique a lieu en régime diffusionnel. L'étude paramétrique du craquage catalytique de l'oléate de méthyle (pur à 82%) sur l'alumine activée, silice-alumine et kaolinite a donné des conversions élevées à des températures comprises entre 400 et 450ʿC. Les alphaoléfines en CI0-C14, utilisées par la suite pour l'industrie des lubrifiants et tensioactifs, ne sont pas obtenues sélectivement en forte proportion. Un mécanisme de conversion de l'oléate de méthyle n'a pas pu être proposé parce que trop de produits de coupes d'hydrocarbures différents sont formés. Les perspectives de cette thèse seraient la modélisation du craquage catalytique de l'acide oléique afin de valider les résultats obtenus expérimentalement, et l'application de cette étude au recyclage des boues et des huiles de fritures usagées riches en acides gras.NANCY/VANDOEUVRE-INPL (545472102) / SudocSudocFranceF