Spatially-Resolved Eigenmode Decomposition of Red Blood Cells Membrane Fluctuations Questions the Role of ATP in Flickering

Daniel Boss, Christian Depeursinge, Annick Hoffmann, Pierre Magistretti, Pierre Marquet, Benjamin Rappaz, Dimitri Nestor Alice Van De Ville
Public Library Science, 2012
Article

Résumé

Red blood cells (RBCs) present unique reversible shape deformability, essential for both function and survival, resulting notably in cell membrane fluctuations (CMF). These CMF have been subject of many studies in order to obtain a better understanding of these remarkable biomechanical membrane properties altered in some pathological states including blood diseases. In particular the discussion over the thermal or metabolic origin of the CMF has led in the past to a large number of investigations and modeling. However, the origin of the CMF is still debated. In this article, we present an analysis of the CMF of RBCs by combining digital holographic microscopy (DHM) with an orthogonal subspace decomposition of the imaging data. These subspace components can be reliably identified and quantified as the eigenmode basis of CMF that minimizes the deformation energy of the RBC structure. By fitting the observed fluctuation modes with a theoretical dynamic model, we find that the CMF are mainly governed by the bending elasticity of the membrane and that shear and tension elasticities have only a marginal influence on the membrane fluctations of the discocyte RBC. Further, our experiments show that the role of ATP as a driving force of CMF is questionable. ATP, however, seems to be required to maintain the unique biomechanical properties of the RBC membrane that lead to thermally excited CMF.

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https://infoscience.epfl.ch/record/184467?ln=fr

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Daniel Boss, Christian Depeursinge, Annick Hoffmann, Pierre Magistretti, Pierre Marquet, Benjamin Rappaz, Dimitri Nestor Alice Van De Ville
Public Library Science, 2012
Article

Résumé

Official source

https://infoscience.epfl.ch/record/184467?ln=fr

À propos de ce résultat

Concepts associés (14)

Concepts associés

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Publications associées (3)

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Publications associées (3)

Cellular dynamics explored with digital holographic microscopy

Benjamin Rappaz

Obtaining high resolution 3D quantitative images is critical for elucidating the relationship between cell dynamics and physiological or pathological processes. However the feasibility of such cellular dynamic studies is limited by the resolution of the 3D images, the required acquisition time and the degree of invasiveness of the currently available imaging techniques as well as their limitation to provide quantitative information. Digital Holographic Microscopy (DHM) is an optical imaging technique developed to meet most of these requirements to accurately explore cell dynamics. In short, DHM allows to quantitatively measure the wavefront transmitted through a specimen and magnified by a microscope objective. A hologram, which contains the whole information of the transmitted wavefront, is formed by the interference of the wave coming from the object with a reference wave, and recorded with a camera. The hologram reconstruction process, based on the electromagnetic wave propagation theory, permits to numerically process the hologram in order to extract both amplitude and phase information. This process allows to obtain an exact replica of the wave diffracted or transmitted by the observed specimen. Thanks to its interferometric nature, DHM yields phase images with a nanometric sensitivity along the optical axis of the microscope, revealing extremely detailed minute information about the cell morphology and internal structure, as well as cellular micromovements in the nanometer range. So far, DHM has proven its efficiency on numerous fields in material sciences. This thesis presents some technical developments achieved with DHM and extends the applications of this technique to life sciences in general and cellular structure and dynamics in particular. The quantitative phase images generated by DHM represent an endogenous contrast signal which contains dual information about both the cell morphology and the refractive index (RI), which is essentially related to the intracellular (protein) content. The first part of this thesis (chapter 2) presents two different approaches to separately extract these two contributions and obtain an independent measurement of both the cell morphology and RI, thus providing an interpretation of the phase signal which is more readily exploitable and more relevant for cell biologists. The RI is a function of the dry mass, thus the phase signal variation in time can be related to biomass production and provides a direct interpretation of the phase signal. In section 3.1 this relation is exploited to study the dry mass production during the cell cycle of fission yeast. The decoupling procedure presented in section 2.1 allows to measure the thickness and RI of cells. In section 3.2, we use this decoupling procedure to measure the Mean Corpuscular Volume (MCV) and RI of red blood cells. These measurements are also compared to those obtained by other techniques. In addition, as far as red blood cell are concerned, the RI can be related to the Mean Corpuscular Hemoglobin Content (MCHC). The MCV, RI and MCHC are important clinical parameters that can be non-invasively and instantly measured with DHM. The membrane of red cells presents a flickering at a nanometric scale which can reflect their metabolic state, related to ATP content. Due to the technical difficulty to measure this flickering, it has been difficult to investigate the origin of these fluctuations. DHM, thanks to its nanometric and microsecond sensitivity, allows to monitor these Cell Membrane Fluctuations (CMF). In section 3.3 DHM is used to measure CMF of healthy and metabolically-impaired red blood cells. The last section of this thesis (section 3.4) assesses how DHM can quantitatively monitor minute cell morphological and optical changes induced by agonist-mediated activation of specific membrane receptors. This is illustrated by tracking the phase signal variations during excitotoxic activation of neurons by the neurotransmitter glutamate.

EPFL2008

Chargement

Some methods of dynamic nuclear polarization for use in metabolic imaging

Fiodar Kurdzesau

It has been suggested already more than 60 years ago to use polarized nuclei in particle scattering experiments1, but only with the discovery of the solid effect dynamic nuclear polarization process2 the realisation of polarized solid targets became possible in the early sixties. In parallel to the technical development of these instruments, the theoretical basis for the understanding of the various dynamic nuclear polarization (DNP) processes has been established3. The knowledge accumulated in all these years has not been of immediate interest for NMR/MRI applications until recently, when an experiment of Golman, Ardenkjær-Larsen and colleagues has put it into a new context4. They demonstrated that it is actually possible to transform a dynamically polarized organic sample from its initial frozen state into a liquid room temperature solution, while retaining a big part of the nuclear polarization, by rapidly dissolving it in superheated water. The nuclear relaxation times in such polarized liquid solutions are long enough to open the possibility of injecting them into biological subjects to investigate (e.g. in vivo) metabolic processes in a nearby MRI installation. With this approach an amplification of NMR signals in the order of 10,000 can be achieved for 13C nuclei in labelled compounds, thus opening a breath of new experimental possibilities. The well-established DNP techniques, where the electron polarization from paramagnetic impurities is transferred to the surrounding nuclei in an external field at low temperature (∼1 K), need now to be adapted to the requirements of NMR/MRI/MRS. A main challenge is to find biologically compatible solutions containing a small concentration of an efficient paramagnetic centre well suited for DNP in which the labelled molecule of biological interest, e.g. metabolic precursors, can be easily dissolved. The DNP process in such samples has to be thoroughly studied and optimized and therefore suitable hardware for this specific application needs to be developed (polarizer, dissolution and injection set-ups etc.). These are problems which are addressed in the presented thesis work. Extensive DNP studies have been performed on frozen solutions of several compounds of biological interest with 13C (Na acetate, Na pyruvate, Na bicarbonate, urea, glycine, glucose), 15N (urea, choline chloride) and 6Li (Li chloride) nuclei in water-ethanol and water-glycerol solvents doped with TEMPO free radicals. Two different W-band DNP set-ups operating around 3.5 T and 1.2 K were used: one at PSI Villigen and second at EPFL Lausanne specially developed for dissolution experiments. The main mechanism of DNP processes in all frozen samples was found to be dynamic cooling where spin temperatures of ∼10 mK were routinely reached which corresponds to a polarization level of 40 %, 8 %, 5 % and 3 % for protons, 13C, 6Li and 15N nuclei respectively5. The obtained solid state data were treated within existing theoretical models (Provotorov-thermal spin mixing equations), which were expanded to allow a multinuclear (1H/13C/23Na/2H) analysis. This allowed to explain some newly observed experimental results, namely the linear polarization increase with a higher degree of sample deuteration and the difference in the polarization build-up and relaxation rates, as well as to choose the criteria for the optimum sample composition and DNP process. Fast dissolution experiments on the EPFL polarizer have shown that 70-80 % of the initial solid state polarization can be retained for all studied nuclei (13C, 6Li, 15N) while the liquid state NMR amplification factor reaches the order of 10,000 and mainly depends on the relaxation speed of the specific nuclei after the dissolution6. Optimum samples are now routinely used in metabolic/MRI experiments at CIBM Lausanne employing the developed DNP and dissolution apparatus operated according to established protocols. ______________________________ 1 C.J. Gorter, Physica 14 (1948) 504; M.E. Rose, Phys. Rev. 75 (1949) 213. 2 A. Abragam, W. G. Proctor, Compt. Rend. 246 (1958) 2253. 3 A. Abragam, M. Goldman, Rep. Prog. Phys. 41 (1978) 395. 4 J.H. Ardenkjaer-Larsen et al, PNAS. 100 No 18 (2003) 10158. 5 F. Kurdzesau et al, J. Phys. D: Appl. Phys., 41 (2008) 155506. 6 A. Comment et al, Conc. Magn. Res. B, 31B (2007) 255.

EPFL2009

Chargement

In principle, a major goal in drug development is to design a high-affinity compound with an appropriate pharmacological response, which requires understanding of physical processes underlying the drug-target interaction, affinity and specificity. This drug key information can be obtained by measuring drug binding kinetics in real time as the quantity of a ligand binding to a receptor immobilized on a biosensor chip surface. Almost all drugs independently of their targets interact with a complex cell membrane that incorporate various transmembrane proteins whose impact cannot be disregarded. Therefore, it is highly desirable that preclinical drug development is performed under conditions that are as close as possible to a native cell environment. The above reasons enhance the need for alternative approaches, such as whole-cell assays that are able to examine in vitro potential drug compounds. However, nowadays fragments of cell membranes have to be routinely isolated from the native cell environment due to limitations of currently available label-free technologies. In recent years, attempts were made to measure binding kinetics on living bacteria by surface plasmon resonance-based biosensors. Nevertheless, the experiments were not fully successful because of an insufficient penetration depth of the sensing evanescent field into living bacteria. Label-free biosensors based on metal-free photonic crystals support electromagnetic surface waves with a deeper penetration depth into the sample medium offering a solution for measuring binding interactions with living bacterial and, possibly, also eukaryotic cells. The deeper penetration of the surface waves creates a significant advantage for this non-disruptive technology over conventional immunoassays such as ELISA. For these reasons, label-free biosensors have been attracting a growing interest from pharmaceutical companies and research institutions by avoiding any experimental artefacts induced by labeling and allowing for real-time kinetic measurements. In this work, I contributed to the development of a label-free optical biosensor based on a photonic crystal that can be exploited for living bacteria. Moreover, I designed an experimental protocol and demonstrated how binding kinetics of various ligands, including antibodies and bacteriophages can be measured by the biosensor in vitro. Furthermore, this study attempts to apply the biosensor technology for bacterial viability tests exploring the ways in which the biosensor can detect metabolic activity of bacteria. Additionally, we performed theoretical studies on application of the Hillâs and Mathieuâs equations to study the effect of the photonic crystal design on the wave equation describing electromagnetic field distribution in the photonic crystal. This Thesis work demonstrates capabilities of a versatile biophysical method based on light interaction with living matter. In particular, the device sensitivity allows for measurements on living intact cells in vitro, which is a key technological advantage. Finally, this Thesis provides experimental evidence for future applications of the photonic crystal-based biosensor for antibody and bacteriophage therapies contributing to implementation of this technology in drug development process.

EPFL2017

Chargement

Cellular dynamics explored with digital holographic microscopy

Benjamin Rappaz

EPFL2008

Some methods of dynamic nuclear polarization for use in metabolic imaging

Fiodar Kurdzesau

EPFL2009

EPFL2017