Cell adhesion and chemotaxis are two key factors determining cell behaviour and
differentiation which are currently analysed by microscopic examination of the cell or
membrane-associated fluorescence labels. These analyses are often slow, labour intensive
and of limited informational content. This thesis describes the physical theory and
experimental aspects of an optical method suitable for monitoring cell contact, adhesion
to a surface and chemotaxis beyond the conventional limit of optical microscopy by
means of a device that utilises both a plain bare surface and arrays of apertures
nanolithographically-produced in the surface of a Surface Plasmon Resonance (SPR)
sensor structure. Any minute vertical movement of the cell, within the near-field of the
SPR active surface or actual cell/surface contact, creates intensity fluctuations,
detectable in the far-field. This was demonstrated during experiments with non-apertured
devices. (A video demonstrating the biological features of the device accompanies this
thesis and may be obtained by contacting University of Plymouth's LRC.) The light
scattered by each nanolithographically-produced aperture also fluctuates as a
consequence of the cell approaching to within a few hundred nanometres of the aperture
bearing surface and demonstrated detection of minute vertical movement on the surface
of the apertured device. The combination of apertured and non-apertured detection
results in a highly spatially-sensitive 3-dimensional sensor. Digitising the output from a
CCD camera allows patterns of intensity fluctuation to be correlated with the contact and
adhesion of individual cells on the active surface over a short period of time (2-3
minutes).
Initial trials of an apertured device (diameter (^) « wavelength of incident light ( X ) )
carried out by our collaborating partners Drs R. Carr and S. Al-shukri at the Centre for
Applied Microbiology and Research, Porton Down demonstrated that the use of
apertures etched in a SPR metal surface produced a highly sensitive dielectric monitor,
i.e. sensitive to very small changes in the refractive index of the micro-environment
adjacent to the aperture. This was proposed as being of potentially great value in the
development of extremely sensitive probes of dielectric particulates of sub-micron
dimensions, i.e. biological macromolecules and supramolecular structures.
Characterisation of the associated radiative and non-radiative evanescent fields on the
surface of the device was conducted in order to gain a greater knowledge of the
mechanisms by which the interactions between the cells adjacent to and in direct contact
with the apertures and evanescent fields produced such significant intensity fluctuations
in the results at CAMR.
A combinational Scanning Probe Microscope was developed and used in Scanning Nearfield
Optical Microscope and Photon Scanning Tunnelling Microscope modes of
operation to detect the evanescent and radiative fields respectively. Detailed mapping of
the radiative pattern in the near-field of the large apertures {<p » X) demonstrated a
diffraction of approximately 25% of the Surface Plasmon Wave (SPW) either side of the
centre of the aperture with the remainder being contained within the metal layer.
Scattering at the second aperture interface, i.e. air/metal, was shown to be of a lower
magnitude as a result of non-surface plasmon enhancement within the non-resonant
aperture. Characterisation of the intensity profile of small apertures (^ < A) was beyond
the scope of this project due to its limited time and finance and was not undertaken. A
section in the conclusions is dedicated to giving a possible cause of the intensity profiles
IV
detected during the initial studies at CAMR with possible procedures required to verify
and expand such work.
In order to investigate the potential of the device in the biological environment,
biological trials were carried out with collaborating establishments at Salisbury and
Exeter and demonstrated that this dual sensing microscopic technique had great potential
in the 3-dimensional monitoring of cell movement together with the capability of
extending our knowledge of cell behaviour with the view to a system of rapid screening
for tumour cells. This technique has produced real-time images of cell behaviour, which
to our knowledge has not been previously seen before by any other microscopy
technique. The finding of these trials are documented in this thesis with possible theories
as to what the biological effects responsible for these results may possibly be. Future
work into the verification of these effects and more biological trials and procedures are
described in the hope that afler further work the device may be developed into a
commercial and readily available scientific unit for use in the laboratory.
Date of Award | 1997 |
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Original language | English |
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Awarding Institution | |
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A Novel Biosensor Using Nanolithographically-Produced Submicron Optical Sources for the Study of Cell Adhesion and Chemotaxis
Hood, A. S. (Author). 1997
Student thesis: PhD