Online Image Analysis of Jurkat T Cells using in situ Microscopy

Joensuu, Jenny

January 2015

Cell cultivation in bioreactors would benefit from developed monitoring systems with online real-time imaging to evaluate cell culture conditions and processes. This opportunity can be provided with the newly developed in situ Microscope also called ISM. The ISM probe is mounted into the wall of a bioreactor and consists of a measurement zone with an illuminating light source to obtain real-time images of moving cells in suspension. The instrument is linked to advanced imaging analysis software which can be specifically adapted for the objects in study. The aim of this project is to analyze the T lymphocyte cell line Jurkat T cells using the ISM equipment and identify specific features of the cells that can be obtained. The results show that the equipment and linked software are suitable for monitoring cell density, cell size distribution and cell surface analysis of the Jurkat cells during cultivation. The ISM could also detect induced changes in cell size caused by osmotic shifts and the course of an infection occurring in the cell suspension using a developed software for online real-time monitoring.

In Situ Microscopy

Jurkat cells

T lymphocytes

image processing analysis

osmotic shock

Cell Biology

Cellbiologi

FABRICATION, PLASTICITY AND THERMAL STABILITY OF NANOTWINNED AL ALLOYS

Qiang Li (7041092)

12 October 2021

<p>Applications of Aluminum (Al) alloys in harsh environments involving high stress and high temperatures are often hindered because of their inherently low strength and poor performance at high temperatures. The strongest commercial Al alloys reported up to date have a maximum strength less than 700 MPa. Although ultrafine grained Al alloys prepared by severe plastic deformation have higher strength, they encounter grain growth at moderate temperatures. </p> <p>This thesis focuses on adopting transition metal solutes and non-equilibrium approach to fabricate high-strength, thermally stable nanotwinned Al alloys. To understand the underlying deformation mechanisms of nanotwinned Al alloys, <i>in-situ</i> micromechanical tests, high resolution and analytical transmission microscopy and atomistic simulations were used. Our studies show that nanotwinned supersaturated Al-Fe alloys have a maximum hardness and flow stress of ~ 5.5 GPa and 1.6 GPa, respectively. The apparent directionality of the vertical incoherent twin boundaries renders plastic anisotropy and compression-tension asymmetry in the nanotwinned Al-Fe alloys, revealed by systematic <i>in-situ</i> tensile and compressive micromechanical experiments conducted from both in-plane and out-of-plane directions. Moreover, the nanotwinned Al-Fe alloys experience no apparent softening when tested at 200 °C. When selectively incorporating with one additional solute as stabilizer, the ternary nanotwinned Al alloys can preserve an exceptionally high flow stress, exceeding 2 GPa, prior to precipitous softening at an annealing temperature of > 400 °C. The thesis offers a new perspective to the design of future strong, deformable and thermally stable nanostructured Al alloys. </p>

Metals and Alloy Materials

Al alloys

Fabrication

Plasticity

Thermal Stability

in-situ microscopy

nanocrystalline

solid solution

In-Situ Environmental TEM Studies of Electro- and Photo-Electrochemical Systems for Water Splitting

Ronge, Emanuel

18 December 2020

No description available.

530

Physik (PPN621336750)

water splitting

oxygen evolution

hydrogen evolution

manganese oxide

photo-cathode

electrochemical corrosion

TiO2 protection layer

molybdenum sulfides

catalysis

ion-exchange

in-situ microscopy

surface dynamics