Tissue distribution and activity testing suggest a similar but not identical function of fetuin-B and fetuin-A.

Fetuins are serum proteins with diverse functions including the regulation of osteogenesis and inhibition of unwanted mineralization. Besides the alpha2-Heremans and Schmid glycoprotein/fetuin-A, the recently identified fetuin-B is a second member of the fetuin family [Olivier, Soury, Risler, Smih, Schneider, Lochner, Jouzeau, Fey and Salier (1999) Genomics 57, 352-364; Olivier, Soury, Ruminy, Husson, Parmentier, Daveau and Salier (2000) Biochem. J. 350, 589-597], which belongs to the cystatin superfamily. We compared the expressions of fetuin-B and fetuin-A at the RNA level and established that both genes are most highly expressed in liver tissue. Like fetuin-A, fetuin-B mRNA is also highly expressed in tongue and placenta tissues. We demonstrated for the first time that fetuin-B is also expressed at the protein level in sera and several organs of mouse, rat and human. We isolated contiguous genomic clones containing both fetuin-B and fetuin-A genes, indicating that these genes are closely linked at the genome level. The close proximity of both these genes may explain our observation that fetuin-B expression was decreased in fetuin-A-deficient mice. Unlike fetuin-A, the amount of fetuin-B protein in human serum varied with gender and was higher in females than in males. Functional analysis revealed that fetuin-B, similarly to fetuin-A, is an inhibitor of basic calcium phosphate precipitation, albeit less active when compared with fetuin-A. Therefore fetuin-B may have a function that is partly overlapping, if not identical, with the function of fetuin-A

Rapid calcification propensity testing in blood using a temperature controlled microfluidic polymer chip

Phosphate toxicity is a major threat to cardiovascular health in chronic kidney disease. It is associated with oxidative stress, inflammation and the accumulation of calcium phosphate commonly known as calcification in soft tissues leading to functional disorders of blood vessels. An improved calcification propensity test for the assessment of phosphate toxicity was developed, which measures the velocity of calcium phosphate mineralization from colloidal precursors in vitro. This so called T50 test measures the transformation from a primary into a secondary form of nanosized colloidal plasma protein-calcium phosphate particles known as calciprotein particles. The T50 test in its previous form required a temperature controlled nephelometer and several hours of continuous measurement, which precluded rapid bed side testing. We miniaturized the test using microfluidic polymer chips produced by ultrasonic hot embossing. A cartridge holder contained a laser diode for illumination, light dependent resistor for detection and a Peltier element for thermo control. Increasing the assay temperature from 37°C to 75°C reduced the T50 test time 36-fold from 381 ± 10 min at 37°C to 10.5 ± 0.3 min at 75°C. Incorporating sputtered micro mirrors into the chip design increased the effective light path length, and improved signal-to-noise ratio 9-fold. The speed and reproducibility of the T50 chip-based assay run at 75°C suggest that it may be suitable for rapid measurements, preferably in-line in a dialyser or in a portable microfluidic analytic device with the chip inserted as a disposable cartridge

Rapid calcification propensity testing in blood using a temperature controlled microfluidic polymer chip.

Phosphate toxicity is a major threat to cardiovascular health in chronic kidney disease. It is associated with oxidative stress, inflammation and the accumulation of calcium phosphate commonly known as calcification in soft tissues leading to functional disorders of blood vessels. An improved calcification propensity test for the assessment of phosphate toxicity was developed, which measures the velocity of calcium phosphate mineralization from colloidal precursors in vitro. This so called T50 test measures the transformation from a primary into a secondary form of nanosized colloidal plasma protein-calcium phosphate particles known as calciprotein particles. The T50 test in its previous form required a temperature controlled nephelometer and several hours of continuous measurement, which precluded rapid bed side testing. We miniaturized the test using microfluidic polymer chips produced by ultrasonic hot embossing. A cartridge holder contained a laser diode for illumination, light dependent resistor for detection and a Peltier element for thermo control. Increasing the assay temperature from 37°C to 75°C reduced the T50 test time 36-fold from 381 ± 10 min at 37°C to 10.5 ± 0.3 min at 75°C. Incorporating sputtered micro mirrors into the chip design increased the effective light path length, and improved signal-to-noise ratio 9-fold. The speed and reproducibility of the T50 chip-based assay run at 75°C suggest that it may be suitable for rapid measurements, preferably in-line in a dialyser or in a portable microfluidic analytic device with the chip inserted as a disposable cartridge

Measuring of calcification risk with polymer microchips

It has been shown that the formation of calcium phosphate crystals can be detected in patient blood using a polymer microchip manufactured by ultrasonic processing. Ultrasonic processing is recently evolving for the fabrication of low-cost microfluidic devices from thermoplastic polymers. The formation of calcium phosphate crystals can be measured in the blood serum of a patient both optically from a change in turbidity or in electrical resistance