Torsten Mueller scite author profile

Reproducibility in research can be compromised by both biological and technical variation, but most of the focus is on removing the latter. Here we investigate the effects of biological variation in HeLa cell lines using a systems-wide approach. We determine the degree of molecular and phenotypic variability across 14 stock HeLa samples from 13 international laboratories. We cultured cells in uniform conditions and profiled genome-wide copy numbers, mRNAs, proteins and protein turnover rates in each cell line. We discovered substantial heterogeneity between HeLa variants, especially between lines of the CCL2 and Kyoto varieties, and observed progressive divergence within a specific cell line over 50 successive passages. Genomic variability has a complex, nonlinear effect on transcriptome, proteome and protein turnover profiles, and proteotype patterns explain the varying phenotypic response of different cell lines to Salmonella infection. These findings have implications for the interpretation and reproducibility of research results obtained from human cultured cells.

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Global and Site-Specific Effect of Phosphorylation on Protein Turnover

et al. 2021

Developmental Cell

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Size and location control of Si nanocrystals at ion beam synthesis in thin SiO2 films

Mueller

Heinig

Moeller

2002

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Binary collision simulations of high-fluence 1 keV Si + ion implantation into 8 nm thick SiO 2 films on (001)Si were combined with kinetic Monte Carlo simulations of Si nanocrystal (NC) formation by phase separation during annealing. For nonvolatile memory applications, these simulations help to control size and location of NCs. For low concentrations of implanted Si, NCs form via nucleation, growth and Ostwald ripening, whereas for high concentrations Si separates by spinodal decomposition. In both regimes, NCs form above a thin NC free oxide layer at the SiO 2 /Si interface. This, self-adjusted layer has just a thickness appropriate for NC charging by direct electron tunneling. Only in the nucleation regime the width of the tunneling oxide and the mean NC diameter remain constant during a long annealing period. This behavior originates from the competition of Ostwald ripening and Si loss to the Si/SiO 2 interface. The process simulations predict that, for nonvolatile memories, the technological demands on NC synthesis are fulfilled best in the nucleation regime.Recently, nonvolatile memory concepts based on nanocrystals (NCs) embedded in the gate oxide of MOS transistors have attracted much interest [1]. For that aim, NCs have been synthesized by a variety of techniques like chemical vapor deposition [2], ion implantation [3,4], and Si aerosol deposition [5]. Ion implantation followed by thermally activated precipitation of the implanted impurity atoms is most compatible with current silicon technology. By low-energy Si + ion implantation into thin SiO 2 layers on (001)Si, NCs of Si were formed a few nanometers above the Si/SiO 2 interface [3]. This allows charging of the NCs by direct electron tunneling, which is a prerequisite for high endurance and low operation voltages [6]. Further optimization of location and size of ion beam synthesized NCs for memory application requires a deeper understanding of the mechanisms involved, which determine (i) the built-up of Si supersaturation by high-fluence ion implantation and (ii) NC formation by phase separation. For that aim, process simulations were divided into two steps. The Si implantation was studied using the binary collision code TRIDYN [7], which includes dynamic target changes. The phase separation of Si from SiO 2 during subsequent annealing has been simulated with a kinetic lattice Monte-Carlo code, which describes the thermally activated processes.The TRIDYN depth profiles are shown in Fig. 1 for 1 keV Si + ion implantation into SiO 2 . TRIDYN takes into account dynamic target changes due to ion deposition, ion erosion and ion beam mixing. The input parameters required by the simulation include the displacement and surface binding energies of target atoms. The displacement energies E d for both, Si and O, were assumed to be 8 eV. This value proved to yield satisfactory agreement between earlier TRIDYN simulations of ion mixing and experiments [8] and is also consistent with the choice of Sigmund and Gras-Marti [9] in their theoretical treatment of ion m...

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Thermometry in dielectrophoresis chips for contact-free cell handling

Jaeger¹,

Mueller²,

Schnelle³

2006

J. Phys. D: Appl. Phys.

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Cell biology applications, protocols in immunology and stem cell research, require that individual cells are handled under strict control of their contacts to other cells or synthetic surfaces. Dielectrophoresis (DEP) in microfluidic chips is an established technique to investigate, group, wash, cultivate and sort cells contact-free under physiological conditions: microelectrode octode cages, versatile dielectrophoretic elements energized with radio frequency electric fields, stably trap single cells or cellular aggregates. For medical applications and cell cultivation, possible side effects of the dielectrophoretic manipulation, such as membrane polarization and Joule heating, have to be quantified. Therefore, we characterized the electric field-induced warming in dielectrophoretic cages using ohmic resistance measurements, fluorometry, liquid crystal beads, infra-red thermography and bubble size thermometry. We compare the results of these techniques with respect to the influences of voltage, electric conductivity of buffer, frequency, cage size and electrode surface. We conclude that in the culture medium thermal effects may be neglected if low voltages and an electric field-reducing phase pattern are used. Our experimental results provide explicit values for estimating the thermal effect on dielectrophoretically caged cells and show that Joule heating is best minimized by optimizing the cage geometry and reducing the buffer conductivity. The results may additionally serve to evaluate and improve theoretical predictions on field-induced effects. Based on present-day chip processing possibilities, DEP is well suited for the manipulation of cells.

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Torsten Mueller

Multi-omic measurements of heterogeneity in HeLa cells across laboratories

Global and Site-Specific Effect of Phosphorylation on Protein Turnover

Size and location control of Si nanocrystals at ion beam synthesis in thin SiO2 films

Thermometry in dielectrophoresis chips for contact-free cell handling

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