Untersuchungen zur Eignung der Mikrokalorimetrie als Screeningmethode in der Entwicklung von Formulierungen /

Stendel, Gerald.

January 1999

Thesis (doctoral)--Rheinische Friedrich-Wilhelms-Universität zu Bonn, 1999.

Mikrokalorimetrie. Screening.

Microcalorimetric studies of human erythrocytes and lymphocytes

Ikomi-Kumm, Julie A.

January 1984

Thesis (doctoral)--Lund, 1984.

Einsatzmöglichkeiten der Mikrokalorimetrie bei der Formulierungsentwicklung in der Veterinärpharmazie /

Ziegenbalg, Oliver.

January 2005

Univ., Diss--Bonn, 2005.

Charakterisierung von exothermen Zersetzungsreaktionen mit thermoanalytischen und numerischen Methoden

Fischer, Sabine

January 2008

Zugl.: Halle (Saale), Univ., Diss., 2008

Erkennung und Charakterisierung gefährlicher selbstzersetzlicher Substanzen

Antelmann, Olivia.

Unknown Date

Techn. Universiẗat, Diss., 2001--Berlin.

Einsatz der isothermen Wärmeleitungsmikrokalorimetrie zur Stabilitätsbeurteilung von Transdermalen Therapeutischen Systemen (TTS)

Latsch, Silvia.

Unknown Date

Universiẗat, Diss., 2003--Frankfurt (Main).

The coverage dependent adsorption of carbon monoxide on copper catalysts studied by a combination of adsorption microcalorimetry, temperature programmed desorption and Fourier transform infrared spectroscopy

Naumann d'Alnoncourt, Raoul.

January 2005

Bochum, Univ., Diss., 2005.

Biokompatibilní amfifilní látky v interakcích s polymery / Biocompatible Amphiphilic Compounds and their Interactions with Polymers

Burdíková, Jana

January 2018

This work is focused on the study of interaction between hyaluronan and high-biocompatible amphiphilic molecules. Using fluorescent probe method, screening of the interaction of cationic lipid 1,2-dipalmitoyl-3-trimethylammonium-propane (DPTAP), mixture of this cationic lipid with zwitterionic lipid, 1,2-dipalmitoyl-sn-glycero-3-phosphochloline (DPPC), with hyaluronan, both native and hydrophobically modified was carried out. Results showed the self-aggregation of DPPC and DPTAP independently on lipids ratio in the mixture and the interaction of DPTAP and DPPC/DPTAP aggregates with hyaluronan at specific ratio of DPTAP and hyaluronan concentration. Physical properties of formed membranes and the influence of cholesterol were also investigated at different DPPC and DPTAP concentration ratio. Last but not least, the non-ionic surfactant-DPPC systems were studied, namely, the size of the formed aggregates, the thermodynamics of solubilisation and the interaction with native hyaluronan.

Využití mikrokalorimetrie při studiu hydratace biopolymerů / Use of microcalorimetry in the study of hydration of biopolymers

Bola, Tomáš

January 2018

This master thesis deals with the using of microcalorimetry in the study of hydration of biopolymers. Lactose has been selected together with the other biopolymers although it is not among biopolymers but disaccharides. Selected biopolymers are alginate, dextrane, chitosan and hyaluronan of two molecular weights. Lactose has been selected for these purposes mainly because it is a model example to determine whether or not the reaction to moisture between the other samples and the saturated salt solution occurs. The biopolymer hydration study, as opposed to the commonly used perfusion calorimetry method using the possibility of measuring with adjustable moisture has been used an isothermal microcalorimetry method where at two constant temperatures the reaction of the sample to the different moisture released by the saturated salt solution was monitored.

Chip-Calorimetric Monitoring and Biothermodynamic Analysis of Biofilm Growth and Interactions with Chemical and Biological Agents / Chipkalorimetrisches Monitoring und Biothermodynamische Analyse von Biofilmen und ihren Wechselwirkungen mit chemischen und biologischen Agentien

Mariana, Frida

16 February 2016

Over the last years, varieties of technologies for biofilm analysis were developed and established. They work on different principles and deliver information about biofilms on different information levels. In this work, chip-calorimetry was applied as an analytical tool that measures heat produced from biofilms. Any change of metabolism in biofilms is reflected by a changed heat flow. The heat, which is the integral of the heat flow vs. time, is quantitatively related to the growth stoichiometry of the biofilm, as described by the Hess’ Law. The heat flow is related to the growth kinetics with the reaction heat as proportionality factor. The results from the calorimetric measurement thus, deliver general information about growth stoichiometry and kinetics. The other interpretation of calorimetric results bases on the assumed proportionality between heat flow and oxygen consumption rate (- 460 kJ/mol ). This ratio is called oxycaloric equivalent. Because in case of aerobic growth the majority of oxygen is consumed in catabolic processes during the electron transport phosphorylation, calorimetry is assumed to provide information about the catabolic side of the metabolism. The newly developed chip-calorimeter applied in this work is much more suitable for biofilm studies compared to conventional microcalorimeters due to the flow-through design of the calorimetric chamber. The measurement of undisturbed growing biofilms and the comparison with conventional biofilm analysis tools (i.e. plate counts, confocal laser scanning microscopy (CLSM), and the determination of intermediates’ concentrations (e.g. ATP)) demonstrate the proper functionality of the calorimetric method and the related cultivation procedure by delivering measurement results in the range of literature values. However, when the biofilms were challenged with antimicrobial agents i.e. antibiotics, bacteriophage, and predatory bacteria, the calorimetric results surprisingly deviated from the reference analyses. By combining the results of the calorimetric and reference analyses, additional information about the antimicrobial effects on biofilms can be acquired. Combination of heat measurement and plate counts, which is one of the most conventional approaches, demonstrated that antimicrobials (especially the bactericidal acting kanamycin) could cause the loss of culturability while the cells were still metabolically active. The measurement of ATP content resulted in values out of the typical range, which indicated that antimicrobial treatments disturbed the cellular ATP regulation and the ATP concentration was no longer linearly correlated to the cell number. ATP measurements are therefore not suitable for antimicrobial susceptibility testing. The comparison of heat profiles with the biovolume determined by quantification of microscopic images shows an elevated cell specific heat production rate after the introduction of some antimicrobials (antibiotics and bacteriophage). In case of antibiotics, this can be explained as a consequence of the bacterial defense mechanisms. Most of the described defense mechanisms against antibiotics need biological energy and therefore drive the electron transport phosphorylation (ETP). In case of biofilm treatments with bacteriophage, the trigger of increasing ETP might be the synthesis of phage proteins, hull material, and genetic information molecules. In aerobic conditions, oxygen is used as terminal electron acceptor. Elevated ETP leads therefore to an increase in oxygen consumption, which correlates to the heat production using oxycaloric equivalent as a factor. These correlations explain the increase of cell specific heat productions as biofilms were challenged by antibiotics and bacteriophage. However, also a decrease of specific heat production was observed (in case of predatory bacteria). Here, the predatory bacteria activity caused various damages in host cells, including the interruption of ETP. With these experiments, chip-calorimetry was demonstrated as a promising complementary tool in biofilm research, which provides deeper insights about metabolic activity and alterations. It benefits from the noninvasive handling and the online, real-time measurement that allow the method to be applied for monitoring purposes. Furthermore, its miniaturized dimension allows easy integration in more complex analytic systems and also reduces experiment costs with minimal media/chemical consumption. This thesis also demonstrates the potential development of chip-calorimetry to be more suitable for routine analyses. The use of superparamagnetic beads as matrix to grow biofilms allows regulated transfer of biofilm samples into and from the measurement chamber. This was an initial step towards automation and higher-throughput analysis. One further outcome of the thesis is based on the highly interesting fact about the elevated heat production rate of the host cells induced by the phage infection observed in the chip- calorimetric experiments. The volume specific detection limit of the chip-calorimeter is lower compared to a commercial microcalorimeter. Thus, the infection effect of phages was additionally measured in microcalorimeter to get better quantitative information about the thermal effect of the infection. The results showed that the immediate heat increase after the addition of phage into the solution of the host cells appeared to be quantitatively related to the infection factor, MOI (Multiplicity of Infection). Unfortunately, microcalorimetric measurements in closed ampoules are often subjected to the oxygen limitation. Thus, this problem of microcalorimetric measurement has been addressed. The combination of experimental results and mathematical modeling showed that the rate of metabolism in the static ampoules is defined by the diffusion rate of oxygen into media. This factor has to be considered while designing biological experiments in closed calorimetric measuring chambers and interpreting the calorimetric results for their biological meaning. Some possible solutions to overcome the oxygen bioavailability problem are e.g. to design the experiments with low biomass, or by using media with elevated density to float the biomass at the interface to air and thus to reduce the diffusion path.

Chip-Kalorimetrie

Kalorimetrie

Biofilm

Biofilmen-Quantifikation

Antibiotika

räuberische Bakteria

Bakteriophage

Mikrokalorimetrie

chip-calorimetry

calorimetry

biofilm

biofilm quantification

antibiotics

predatory bacteria

bacteriophage

microcalorimetry

ddc:620

rvk:WF 1350