Your search keyword '"Dalgarno, Paul"' showing total 7 results

1. Fully angularly resolved 3D microrheology with optical tweezers.

Author

Matheson, Andrew B., Mendonca, Tania, Smith, Matthew G., Sutcliffe, Ben, Fernandez, Andrea Jannina, Paterson, Lynn, Dalgarno, Paul A., Wright, Amanda J., and Tassieri, Manlio

Subjects

OPTICAL tweezers, NEWTONIAN fluids, RHEOLOGY, GELATIN, PRINCIPAL components analysis, IMAGING systems

Abstract

Microrheology with optical tweezers (MOT) is an all-optical technique that allows the user to investigate a materials' viscoelastic properties at microscopic scales, and is particularly useful for those materials that feature complex microstructures, such as biological samples. MOT is increasingly being employed alongside 3D imaging systems and particle tracking methods to generate maps showing not only how properties may vary between different points in a sample but also how at a single point the viscoelastic properties may vary with direction. However, due to the diffraction limited shape of focussed beams, optical traps are inherently anisotropic in 3D. This can result in a significant overestimation of the fluids' viscosity in certain directions. As such, the rheological properties can only be accurately probed along directions parallel or perpendicular to the axis of trap beam propagation. In this work, a new analytical method is demonstrated to overcome this potential artefact. This is achieved by performing principal component analysis on 3D MOT data to characterise the trap, and then identify the frequency range over which trap anisotropy influences the data. This approach is initially applied to simulated data for a Newtonian fluid where the trap anisotropy induced maximum error in viscosity is reduced from ~ 150% to less than 6%. The effectiveness of the method is corroborated by experimental MOT measurements performed with water and gelatine solutions, thus confirming that the microrheology of a fluid can be extracted reliably across a wide frequency range and in any arbitrary direction. This work opens the door to fully spatially and angularly resolved 3D mapping of the rheological properties of soft materials over a broad frequency range. [ABSTRACT FROM AUTHOR]

Published

2024

2. OptoRheo: Simultaneous in situ micro-mechanical sensing and imaging of live 3D biological systems.

Author

Mendonca, Tania, Lis-Slimak, Katarzyna, Matheson, Andrew B., Smith, Matthew G., Anane-Adjei, Akosua B., Ashworth, Jennifer C., Cavanagh, Robert, Paterson, Lynn, Dalgarno, Paul A., Alexander, Cameron, Tassieri, Manlio, Merry, Catherine L. R., and Wright, Amanda J.

Abstract

Biomechanical cues from the extracellular matrix (ECM) are essential for directing many cellular processes, from normal development and repair, to disease progression. To better understand cell-matrix interactions, we have developed a new instrument named 'OptoRheo' that combines light sheet fluorescence microscopy with particle tracking microrheology. OptoRheo lets us image cells in 3D as they proliferate over several days while simultaneously sensing the mechanical properties of the surrounding extracellular and pericellular matrix at a sub-cellular length scale. OptoRheo can be used in two operational modalities (with and without an optical trap) to extend the dynamic range of microrheology measurements. We corroborated this by characterising the ECM surrounding live breast cancer cells in two distinct culture systems, cell clusters in 3D hydrogels and spheroids in suspension culture. This cutting-edge instrument will transform the exploration of drug transport through complex cell culture matrices and optimise the design of the next-generation of disease models. A new instrument named OptoRheo combines light sheet fluorescence microscopy and particle tracking microrheology for live imaging and micromechanical sensing of extracellular matrix-cell interactions. [ABSTRACT FROM AUTHOR]

Published

2023

3. Optical Tweezers with Integrated Multiplane Microscopy (OpTIMuM): a new tool for 3D microrheology.

Author

Matheson, Andrew B., Paterson, Lynn, Wright, Amanda J., Mendonca, Tania, Tassieri, Manlio, and Dalgarno, Paul A.

Subjects

OPTICAL tweezers, OPTICAL properties, RHEOLOGY, A priori, VISCOSITY

Abstract

We introduce a novel 3D microrheology system that combines for the first time Optical Tweezers with Integrated Multiplane Microscopy (OpTIMuM). The system allows the 3D tracking of an optically trapped bead, with ~ 20 nm accuracy along the optical axis. This is achieved without the need for a high precision z-stage, separate calibration sample, nor a priori knowledge of either the bead size or the optical properties of the suspending medium. Instead, we have developed a simple yet effective in situ spatial calibration method using image sharpness and exploiting the fact we image at multiple planes simultaneously. These features make OpTIMuM an ideal system for microrheology measurements, and we corroborate the effectiveness of this novel microrheology tool by measuring the viscosity of water in three dimensions, simultaneously. [ABSTRACT FROM AUTHOR]

Published

2021

4. Optical pumping of a single hole spin in a quantum dot.

Author

Gerardot, Brian D., Brunner, Daniel, Dalgarno, Paul A., Öhberg, Patrik, Seidl, Stefan, Kroner, Martin, Karrai, Khaled, Stoltz, Nick G., Petroff, Pierre M., and Warburton, Richard J.

Subjects

QUANTUM dots, ELECTRONS, ELECTRON spin echoes, ELECTRON paramagnetic resonance, MAGNETIC fields, QUANTUM electronics, PHOTONS, OPTICAL polarization, NANOTUBES

Abstract

The spin of an electron is a natural two-level system for realizing a quantum bit in the solid state. For an electron trapped in a semiconductor quantum dot, strong quantum confinement highly suppresses the detrimental effect of phonon-related spin relaxation. However, this advantage is offset by the hyperfine interaction between the electron spin and the 104 to 106 spins of the host nuclei in the quantum dot. Random fluctuations in the nuclear spin ensemble lead to fast spin decoherence in about ten nanoseconds. Spin-echo techniques have been used to mitigate the hyperfine interaction, but completely cancelling the effect is more attractive. In principle, polarizing all the nuclear spins can achieve this but is very difficult to realize in practice. Exploring materials with zero-spin nuclei is another option, and carbon nanotubes, graphene quantum dots and silicon have been proposed. An alternative is to use a semiconductor hole. Unlike an electron, a valence hole in a quantum dot has an atomic p orbital which conveniently goes to zero at the location of all the nuclei, massively suppressing the interaction with the nuclear spins. Furthermore, in a quantum dot with strong strain and strong quantization, the heavy hole with spin-3/2 behaves as a spin-1/2 system and spin decoherence mechanisms are weak. We demonstrate here high fidelity (about 99 per cent) initialization of a single hole spin confined to a self-assembled quantum dot by optical pumping. Our scheme works even at zero magnetic field, demonstrating a negligible hole spin hyperfine interaction. We determine a hole spin relaxation time at low field of about one millisecond. These results suggest a route to the realization of solid-state quantum networks that can intra-convert the spin state with the polarization of a photon. [ABSTRACT FROM AUTHOR]

Published

2008

5. Unveiling the multi-step solubilization mechanism of sub-micron size vesicles by detergents.

Author

Dalgarno, Paul A., Juan-Colás, José, Hedley, Gordon J., Piñeiro, Lucas, Novo, Mercedes, Perez-Gonzalez, Cibran, Samuel, Ifor D. W., Leake, Mark C., Johnson, Steven, Al-Soufi, Wajih, Penedo, J. Carlos, and Quinn, Steven D.

Subjects

*SOLUBILIZATION, *DETERGENTS, *MEMBRANE proteins, *SPECTROMETRY, *QUARTZ crystal microbalances

Abstract

The solubilization of membranes by detergents is critical for many technological applications and has become widely used in biochemistry research to induce cell rupture, extract cell constituents, and to purify, reconstitute and crystallize membrane proteins. The thermodynamic details of solubilization have been extensively investigated, but the kinetic aspects remain poorly understood. Here we used a combination of single-vesicle Förster resonance energy transfer (svFRET), fluorescence correlation spectroscopy and quartz-crystal microbalance with dissipation monitoring to access the real-time kinetics and elementary solubilization steps of sub-micron sized vesicles, which are inaccessible by conventional diffraction-limited optical methods. Real-time injection of a non-ionic detergent, Triton X, induced biphasic solubilization kinetics of surface-immobilized vesicles labelled with the Dil/DiD FRET pair. The nanoscale sensitivity accessible by svFRET allowed us to unambiguously assign each kinetic step to distortions of the vesicle structure comprising an initial fast vesicle-swelling event followed by slow lipid loss and micellization. We expect the svFRET platform to be applicable beyond the sub-micron sizes studied here and become a unique tool to unravel the complex kinetics of detergent-lipid interactions. [ABSTRACT FROM AUTHOR]

Published

2019

6. Multiplexed single-mode wavelength-to-time mapping of multimode light.

Author

Chandrasekharan, Harikumar K, Izdebski, Frauke, Gris-Sánchez, Itandehui, Krstajić, Nikola, Walker, Richard, Bridle, Helen L., Dalgarno, Paul A., MacPherson, William N., Henderson, Robert K., Birks, Tim A., and Thomson, Robert R.

Published

2017

7. Smart-aggregation imaging for single molecule localisation with SPAD cameras.

Author

Gyongy, Istvan, Davies, Amy, Dutton, Neale A. W., Duncan, Rory R., Rickman, Colin, Henderson, Robert K., and Dalgarno, Paul A.

Abstract

Single molecule localisation microscopy (SMLM) has become an essential part of the super-resolution toolbox for probing cellular structure and function. The rapid evolution of these techniques has outstripped detector development and faster, more sensitive cameras are required to further improve localisation certainty. Single-photon avalanche photodiode (SPAD) array cameras offer single-photon sensitivity, very high frame rates and zero readout noise, making them a potentially ideal detector for ultra-fast imaging and SMLM experiments. However, performance traditionally falls behind that of emCCD and sCMOS devices due to lower photon detection efficiency. Here we demonstrate, both experimentally and through simulations, that the sensitivity of a binary SPAD camera in SMLM experiments can be improved significantly by aggregating only frames containing signal, and that this leads to smaller datasets and competitive performance with that of existing detectors. The simulations also indicate that with predicted future advances in SPAD camera technology, SPAD devices will outperform existing scientific cameras when capturing fast temporal dynamics. [ABSTRACT FROM AUTHOR]

Published

2016