We developed and validated a measurement instrument (CLASI-Cutaneous Lupus Erythematosus Disease Area and Severity Index) for lupus erythematosus that could be used in clinical trials. The instrument has separate scores for damage and activity. A group of seven American Dermato-Rheumatologists and the "American College of Rheumatology Response Criteria Committee on SLE (systemic lupus erythematosus)" assessed content validity. After a preliminary session, we conducted standardized interviews with the raters and made slight changes to the instrument. The final instrument was evaluated by five dermatologists and six residents who scored nine patients to estimate inter- and intra-rater reliability in two sessions. Consultation with experts has established content validity of the instrument. Reliability studies demonstrated an intra-class correlation coefficient (ICC) for inter-rater reliability of 0.86 for the activity score (95% confidence interval (CI) = 0.73-0.99) and of 0.92 for the damage score (95% CI = 0.85-1.00). The Spearman's rho (Sp) for intra-rater reliability for the activity score was 0.96 (95% CI = 0.89 to 1.00) and for the damage score Sp was 0.99 (95% CI = 0.97-1.00). Clinical responsiveness needs to be evaluated in a prospective clinical trial, which is ongoing.
Development of a fully automated electrochemiluminescence (ECL) DNA assay for multiplex detection of six biowarfare agents is described. Aminated-DNA capture probes were covalently immobilised on activated-carbon electrodes and subsequently hybridised to target strands. Detection was achieved via a sandwich-type assay after Ru(bpy)3(2+)-labelled reporter probes were hybridised to the formed probe-target complexes. The assay was performed in an automated microsystem in a custom designed ECL detection box with integrated fluidics, electronics,and movable photomultiplier detector. The obtained limits of detection were 0.6-1.2 nmol L(-1) for six targets ranging from 50 to 122 base pairs in size, with linear range 1-15 nmol L(-1). Non-specific adsorption and cross-reactivity were very low. Detection of six targets on a single chip was achieved with subnanomolar detection limits.
An electrochemiluminescence (ECL) immunosensor for the rapid detection of the Francisella tularensis pathogen using whole antibodies or antibody fragments as capture biomolecule is described. A sandwich immunoassay was used with either lipopolysaccharide (LPS) or the whole inactivated bacterial cell (LVS) as a target, while Ru(bpy)3 (2+)-encapsulated silicate nanoparticles were linked to the secondary antibody and used as ECL labels. The assay was performed in a fluidic chip housed in a custom-built black box incorporating electronics, optics and fluidics. The obtained limit of detection for LPS was 0.4 ng/mL, while for the LVS it was 70 and 45 bacteria/mL when the capturing molecule was the whole antibody and the antibody F(ab) fragment, respectively.
Background
One of the most prevalent causes of fetal hypoxia leading to stillbirth is placental insufficiency. Hemodynamic changes evaluated with Doppler ultrasound have been used as a surrogate marker of fetal hypoxia. However, Doppler evaluation cannot be performed continuously. As a first step, the present work aimed to evaluate the performance of miniaturized electrochemical sensors in the continuous monitoring of oxygen and pH changes in a model of acute hypoxia-acidosis.
Methods
pH and oxygen electrochemical sensors were evaluated in a ventilatory hypoxia rabbit model. The ventilator hypoxia protocol included 3 differential phases: basal (100% FiO2), the hypoxia-acidosis period (10% FiO2) and recovery (100% FiO2). Sensors were tested in blood tissue (ex vivo sensing) and in muscular tissue (in vivo sensing). pH electrochemical and oxygen sensors were evaluated on the day of insertion (short-term evaluation) and pH electrochemical sensors were also tested after 5 days of insertion (long-term evaluation). pH and oxygen sensing were registered throughout the ventilatory hypoxia protocol (basal, hypoxia-acidosis, and recovery) and were compared with blood gas metabolites results from carotid artery catheterization (obtained with the EPOC blood analyzer). Finally, histological assessment was performed on the sensor insertion site. One-way ANOVA was used for the analysis of the evolution of acid-based metabolites and electrochemical sensor signaling results; a t-test was used for pre- and post-calibration analyses; and chi-square analyses for categorical variables.
Results
At the short-term evaluation, both the pH and oxygen electrochemical sensors distinguished the basal and hypoxia-acidosis periods in both the in vivo and ex vivo sensing. However, only the ex vivo sensing detected the recovery period. In the long-term evaluation, the pH electrochemical sensor signal seemed to lose sensibility. Finally, histological assessment revealed no signs of alteration on the day of evaluation (short-term), whereas in the long-term evaluation a sub-acute inflammatory reaction adjacent to the implantation site was detected.
Conclusions
Miniaturized electrochemical sensors represent a new generation of tools for the continuous monitoring of hypoxia-acidosis, which is especially indicated in high-risk pregnancies. Further studies including more tissue-compatible material would be required in order to improve long-term electrochemical sensing.
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