Improving species-specific IDMS: the advantages of triple IDMS.

Triple isotope dilution mass spectrometry (triple IDMS) has been applied for the first time on protein quantification, especially on transferrin. Transferrin as an acute phase protein is a marker for several inflammation processes in the human body. Therefore, in Germany, the accurate and precise measurement of this important analyte is required. In this work, a new approach to triple IDMS is described and compared to double IDMS. Also, complete uncertainty budgets for both methods were set up to demonstrate the ability of this method to be used as a reference procedure. The relative expanded uncertainty (k=2) for triple IDMS (3.6 %) is smaller than the one for double IDMS (4.0 %). The content of transferrin found in the human serum reference material ERM-DA470k/IFCC ((2.41±0.08) g/kg) with both methods was in good agreement with each other and with the certificate. For triple IDMS ((2.426±0.086) g/kg) and for double IDMS ((2.317±0.092) g/kg), transferrin was determined. Although triple IDMS is a little more time consuming compared to double IDMS, there is the advantage that the isotopic composition of the spike material does not have to be determined. This is very useful especially in case of a marginal isotopic enrichment in the spike or problems with the accurate measurement of the spike isotope ratio.

Reference measurement procedures for the iron saturation in human transferrin based on IDMS and Raman scattering.

Two reference measurement procedures are presented here that allow the determination of the iron saturation in human transferrin, based on different molecular properties. The results, directly derived from the number of ions bound to the protein molecule, are traceable to the SI. Up to now, the iron saturation has only been deduced indirectly from the amount-of-substance ratio of serum iron to transferrin in serum. Interlaboratory tests have shown the need for more accurate methods, as the results from many participant test samples for both parameters do not lie within the acceptable range of deviation given by relevant guidelines when different methods or kits are applied. Using isotope dilution, an HPLC ICP-MS procedure was developed in compliance with the requirements of a primary reference measurement procedure. In this manner, the iron saturation was measured with an associated relative expanded measurement uncertainty of 4%. Based on the results, a straightforward Raman procedure was evolved, which allows the determination of the iron saturation in transferrin with an associated relative expanded uncertainty of 7%.

Silicon isotope ratios affected by sodium-induced broadband interference in high resolution multicollector-ICPMS.

The measurement of isotope ratios of silicon highly enriched in (28)Si ("Si28", x((28)Si) > 99.99%) is influenced by a significant interference (20%) on the (30)Si(+) signal when using a cup configuration of C ((29)Si(+)) and H3 ((30)Si(+)) on a Neptune MC-ICPMS. This interference was observed in silicon solutions with aqueous NaOH (w(NaOH) > 0.001 g/g) and in highly concentrated aqueous NaOH blank solutions (e.g., w(NaOH) = 0.25 g/g) but never in KOH solutions. By redirecting the ions, the interference was detected with all other Faraday cups except the center cup. The interference can be explained by ion scattering induced by the presence of large amounts of sodium. Due to its shielded location, these stray ions were not detected in the center cup. This effect explains an anomalous increase of the abundance of the (30)Si(+) signal in (30)Si/(29)Si isotope ratio measurements made using aqueous NaOH blank solutions with w(NaOH) ≥ 0.001 g/g. For silicon isotopic measurements, it is recommended to use alkaline solutions for sample dissolution and dilution that do not contain sodium. The effects of this interference are extremely important for the experimental determination of the Avogadro constant N(A) using the "silicon sphere approach". It can also have a significant effect on Si isotope analyses in matrices with a naturally high concentration of sodium (e.g., seawater).

Impact of pump flow fluctuations on post column online ID-ICP-MS.

In post column online isotope dilution mass spectrometry (IDMS), the stability of the spike mass flow is a key element. Changes in viscosity or fluctuations in the pump rate of the peristaltic pump may affect the results of post column online IDMS measurements. It was shown by simulating random fluctuations and studying the changes in the resulting integrals of the isotope ratio chromatogram of the sample that even small fluctuations, observable when using peristaltic pumps, can influence the result and especially its uncertainty. The use of a balance to continuously monitor the mass flow of the spike during the measurement which we presented in a previous publication allows now to correct the isotope ratio chromatogram for these fluctuations. Subsequently, the simulated effect was verified experimentally for the determination of Se-Met in the human serum reference material BCR 637, where the corrected mass fraction was plainly closer to the mass fraction obtained by species specific IDMS. Additional attention was paid to the fact that there is a time shift between the observation of the fluctuations in the pump rate and the detection of these fluctuations in the ICP-MS.

Alternative approach to post column online isotope dilution ICP-MS.

An alternative post column online double isotope dilution inductively coupled plasma mass spectrometry (ID-ICP-MS) method was developed. The resulting equation allows a straightforward calculation of the mass concentration of the analyte in the sample from the measured isotope ratio chromatogram. The use of a balance to determine and monitor the mass flow of the spike and a solution of the species under investigation as the reference are the two core components of this new method. Changes in the viscosity of the system eluent-analyte-spike will not affect the results due to the direct determination of the mass flow rate. The use of the species under investigation as the reference makes the method independent of the injected volume. To simplify matters, the integration of the isotope ratio chromatogram was done with Excel using Simpson's rule instead of sophisticated programs for transformation and integration. The advantages of the new approach were demonstrated with the help of the determination of selenomethionine in the selenized yeast reference material SELM-1 with liquid chromatography coupled to ICP-MS (HPLC ID-ICP-MS) applying the new online double IDMS method.

Surface-enhanced Raman scattering based approach for quantitative determination of creatinine in human serum.

A novel surface-enhanced Raman scattering (SERS) based approach for the quantitative determination of creatinine in human serum is described. Using isotopically labeled (2-13C, 2,3-15N2) creatinine as internal standard, SERS acquires the character of a ratio method that works similar to the well-established isotope dilution techniques. In conjunction with multivariate data analysis, the method was successfully applied for quantifying creatinine at clinically relevant levels and below. A partial least-squares regression model was generated from a set of 87 calibration spectra covering the full range of mole fractions of neat creatinine. The prediction performance of the model was thereafter validated with independent reference samples giving a standard deviation of less than 2%. Finally, a conditioning procedure to prepare real serum samples for SERS-based creatinine analysis was worked out and validated. Measured serum creatinine concentrations are within 3% of the values obtained from gas chromatography/isotope dilution mass spectrometry on the same serum starting material.