[Tauopathies : From molecule to therapy]. / Tauopathien : Vom Molekül zur Therapie.

BACKGROUND: The microtubule-associated tau protein is the defining denominator of a group of neurodegenerative diseases termed tauopathies. OBJECTIVE: Provide a timely state of the art review on recent scientific advances in the field of tauopathies. MATERIAL AND METHODS: Systematic review of the literature from the past 10 years. RESULTS: Tau proteins are increasingly being recognized as a highly variable protein, underlying and defining a spectrum of molecularly defined diseases, with a clinical spectrum ranging from dementia to hypokinetic movement disorders. Genetic variation at the tau locus can trigger disease or modify disease risk. Tau protein alterations can damage nerve cells and propagate pathologies through the brain. Thus, tau proteins may serve both as a serological and imaging biomarker. Tau proteins also provide a broad spectrum of rational therapeutic interventions to prevent disease progression. This knowledge has led to modern clinical trials. CONCLUSION: The field of tauopathies is in a state of dynamic and rapid progress, requiring close interdisciplinary collaboration.

Characterization of yeast cultivations by steric sedimentation field-flow fractionation.

The characterization and quantification of biomass is often time consuming and dependent on the cultivation media and gives no detailed information between cell size and shape and their productivity. By monitoring the bioprocess with steric sedimentation field-flow fractionation (Sd/StFFF) in combination with laser light scattering, not only cell growth, but also the variation of cell size and shape during the cultivation, can be observed. In this work, the feasibility of separating and characterizing cell populations by steric sedimentation field-flow fractionation is demonstrated by its application to three different yeast cultivation broths. For this purpose samples which were collected at different cultivation times were injected into an FFF system. Fractograms were obtained in less than 4 min. Due to the relatively high resolution of the method, a cell sample could be fractionated in several subpopulations differing in their size as well as in their number of buds.