Dry-Reagent Double-Monoclonal Assay for Cystatin C

Insights into the mechanism of cystatin C oligomer and amyloid formation and its interaction with β-amyloid

Cystatin C (CysC) is a versatile and ubiquitously-expressed member of the cysteine protease inhibitor family that is present at notably high concentrations in cerebrospinal fluid. Under mildly denaturing conditions, CysC forms inactive domain-swapped dimers. A destabilizing mutation, L68Q, increases the rate of domain-swapping and causes a fatal amyloid disease, hereditary cystatin C amyloid angiopathy. Wild-type (wt) CysC will also aggregate into amyloid fibrils under some conditions. Propagated domain-swapping has been proposed as the mechanism by which CysC fibrils grow. We present evidence that a CysC mutant, V57N, stabilized against domain-swapping, readily forms fibrils, contradicting the propagated domain-swapping hypothesis. Furthermore, in physiological buffer, wt CysC can form oligomers without undergoing domain-swapping. These non-swapped oligomers are identical in secondary structure to CysC monomers and completely retain protease inhibitory activity. However, unlike monomers or dimers, the oligomers bind fluorescent dyes that indicate they have characteristics of pre-amyloid aggregates. Although these oligomers appear to be a pre-amyloid assembly, they are slower than CysC monomers to form fibrils. Fibrillation of CysC therefore likely initiates from the monomer and does not require domain-swapping. The non-swapped oligomers likely represent a dead-end offshoot of the amyloid pathway and must dissociate to monomers prior to rearranging to amyloid fibrils. These prefibrillar CysC oligomers were potent inhibitors of aggregation of the Alzheimer's-related peptide, β-amyloid. This result illustrates an example where heterotypic interactions between pre-amyloid oligomers prevent the homotypic interactions that would lead to mature amyloid fibrils.

Europium nanoparticle-based simple to perform dry-reagent immunoassay for the detection of hepatitis B surface antigen

Hepatitis B infection, caused by hepatitis B virus (HBV), presents a huge global health burden. Serological diagnosis of HBV mainly relies on the detection of hepatitis B surface antigen (HBsAg). Although there are high sensitivity commercial HBsAg enzyme immunoassays (EIAs) available, many low-resource laboratories lacking trained technicians continue to use rapid point-of-care assays with low sensitivities for HBsAg detection, due to their simplicity to operate. We developed a time-resolved fluorometric dry-reagent HBsAg immunoassay which meets the detection limit of high sensitivity EIAs but is simple to operate. To develop the assay, anti-HBsAg monoclonal antibody coated on europium nanoparticles was dried atop of biotinylated anti-HBsAg polyclonal antibody immobilized on streptavidin-coated microtiter wells. To test a sample in dry-reagent assay, serum sample and assay buffer were added to the wells, incubated, washed and europium signals were measured. The assay showed a detection limit of 0.25 ng/ml using HBsAg spiked in serum sample. When evaluated with 24 HBV positive and 37 negative serum samples, assay showed 100% sensitivity and specificity. Assay wells are stable for at least 26 weeks when stored at 4°C, and can tolerate elevated temperatures of up to 35°C for two weeks. The developed assay has high potential to be used in low-resource laboratories.

All-in-one dry-reagent time-resolved immunofluorometric assay for the rapid detection of HIV-1 and -2 infections

An all-in-one (AIO) dry-reagent time-resolved fluorometric immunoassay that requires minimal liquid handling was developed for the detection of anti-HIV-1 and -2 antibodies. To prepare the AIO wells, in vivo biotinylated capture antigens (r-Bio-HIV-1env and r-Bio-HIV-2env) were immobilized on streptavidin-coated microtitration wells and Eu(III) chelate labelled non-biotinylated tracer antigens [r-HIV-1env-Eu(III) and r-HIV-2env-Eu(III)] were dried in stable form in the same wells. The HIV AIO assay was evaluated with serum/plasma samples (n=148) from in-house and commercial panels at two different incubation times of 15 min and 1h. The overall sensitivity of the AIO assay was 98.6% and specificity was 100% for both the incubation times. The AIO assay can accept whole blood matrix. This assay is envisioned to fill the gap between the rapid point-of-care assays and traditional enzyme immunoassays (EIA) in terms of complexity and turnaround time, without compromising the performance.

Cystatin C as a predictor of all-cause mortality and myocardial infarction in patients with non-ST-elevation acute coronary syndrome

OBJECTIVES

To investigate the predictive value of cystatin C among patients diagnosed with non-ST-elevation acute coronary syndrome (nSTE-ACS).

DESIGN AND METHODS

Admission serum samples from 245 nSTE-ACS patients were measured with a novel cystatin C immunoassay based on a dry-reagent, double monoclonal design. Creatinine concentrations, estimated glomerular filtration rates (eGFR) and one-year follow-up data were available for these patients.

RESULTS

During the follow-up period, 34 (14%) of patients had myocardial infarction (MI) and 25 (11%) died. Increased serum cystatin C was an independent predictor of all-cause mortality and combined events (all-cause mortality and MI) after adjustment to non-biomarker baseline factors, hazard ratio (HR) 2.19 (per increase of 1 tertile; 95% Cl 1.28-3.78, p=0.0046) and 1.75 (1.22-2.51, p=0.0024), respectively. Corresponding values for eGFR were 2.56 (1.43-4.59, p=0.0016) and 1.76 (1.23-2.53, p=0.0022), respectively. Creatinine was not an independent predictor of endpoints (p>0.05).

CONCLUSIONS

Cystatin C was associated with an increased risk of death and combined events in patients with nSTE-ACS.

Quantification of cystatin C by time-resolved fluorometry-based immunoassays

Plasma cystatin C is increasingly used as a marker of glomerular filtration rate. Most assays for cystatin C are based on turbidimetric or nephelometric detection and studies of other rapid methods are limited. This study aimed to develop and compare differently configured immunoassays for quantification of plasma cystatin C, using recombinant cystatin C and two cystatin C-specific antibodies. Method 1 was a two-step sandwich assay with polyclonal antibody as capture and europium chelate-labeled monoclonal antibody as tracer. Method 2 was a one-step heterogeneous competitive assay using immobilized polyclonal antibody and europium-labeled cystatin C. Method 3 was a one-step homogeneous competitive assay with europium-labeled polyclonal antibody as donor and cyanine 5-labeled cystatin C as acceptor. All three assays were evaluated with plasma samples and their performance was compared to a conventional particle-enhanced turbidimetric immunoassay (PETIA). Method 3 was the easiest to perform, with incubation at ambient temperature for 10 min and 20 μL of sample, while methods 1 and 2 had washing steps, took 40 min and 15 min at 37°C, respectively, but used only 10 μL of 100- or 10-fold diluted sample, respectively. The working ranges for methods 1, 2 and 3 were 0.0005-0.2, 0.05-1.0 and 0.25-20mg/L, respectively. Kinetics for method 3 was the fastest with >95% binding completion and for method 2 the slowest with 60% binding completion. All three methods showed good correlation to PETIA, but produced higher cystatin C levels than PETIA. Methods 1 and 3 offered the most favorable performance characteristics and especially method 3 enabled rapid and simple measurement of circulating cystatin C.

Evaluation of a new immunoassay for cystatin C, based on a double monoclonal principle, in men with normal and impaired renal function

Background.

Elevated cystatin C in blood reflects impaired glomerular filtration rate (GFR), but current cystatin C assays, based on polyclonal antibodies and immunoturbidimetric or nephelometric detection, have several limitations. We evaluated a new immunoassay based on monoclonal antibodies in samples from patients with and without chronic kidney disease (CKD).

Methods.

The study enrolled 170 men without known CKD (Group A) and 104 men with CKD (Group B). All patients were assessed with iohexol clearance, plasma creatinine and plasma cystatin C by a conventional particle-enhanced immunoturbidimetric assay (PETIA) and by the new double monoclonal assay. In Group A, three serial blood draws were performed at median intervals of 4 h and 12 days between samples, to also allow assessments of the variability in cystatin C values with the new assay. Concordance correlation coefficients and the 95% limits of agreement were used to estimate the agreement of reciprocal cystatin C and reciprocal creatinine with iohexol clearance.

Results.

Median iohexol clearance (mL/min/1.73 m²) was 81 [interquartile range (IQR) 70, 92] in Group A and 23 (IQR 16, 34) in Group B. The concordance correlation with GFR for the new cystatin C assay compared to the established assay was similar in Group A (0.441 versus 0.465) but higher in Group B (0.680 versus 0.593). Cystatin C measured by both assays exhibited closer agreement with GFR than creatinine. The agreement between the two cystatin C assays was high, with concordance correlations of 0.815 in Group A and 0.935 in Group B. Compared to the conventional assay, the new assay tended to yield lower values of cystatin C at the low end of the range in Group A. The new cystatin C assay exhibited small intraindividual variability across serial samples (coefficient of variation ≤6%).

Conclusions.

In this first clinical evaluation, the new cystatin C assay performed similarly to the established PETIA in patients with normal GFR and better in patients with CKD. The new assay may offer an alternative to current commercial assays to detect and monitor impaired kidney function.

Non-invasive estimation of glomerular filtration rate (GFR). The Lund model: Simultaneous use of cystatin C- and creatinine-based GFR-prediction equations, clinical data and an internal quality check

Knowledge of glomerular filtration rate (GFR) is required to detect and follow impairment of renal function, to allow correct dosage of drugs cleared by the kidneys, and for the use of nephrotoxic contrast media. Correct determination of GFR requires invasive techniques, which are expensive, slow and not risk-free. Therefore, GFR-prediction equations based solely upon cystatin C or creatinine and anthropometric data or upon cystatin C, creatinine and anthropometric data have been developed. The combined prediction equations display the best diagnostic performance, but in several easily identifiable clinical situations (e.g. abnormal muscle mass, treatment with large doses of glucocorticoids) prediction equations based upon either cystatin C or creatinine are better than the combined equations. In Lund, where cystatin C has been used as a GFR-marker in the clinical routine since 1994, a strategy based upon this knowledge has therefore been developed. This comprises simultaneous use of a cystatin C-based and a creatinine-based GFR-prediction equation. If the GFRs predicted agree, the mean value is used as a reliable GFR-estimate. If the GFRs predicted do not agree, clinical data is evaluated to identify reasons for not using one of the two prediction equations and the GFR predicted by the other one is used. If no reasons for the difference in predicted GFRs are found, an invasive gold standard determination of GFR is performed. If the GFRs predicted agree for a patient, the creatinine value is reliably connected to a specific GFR and can be used to follow changes in GFR of that patient.