This invention relates to a holographic sensor.
WO-A-95/26499 discloses a holographic sensor. The sensor comprises a holographic support medium and, disposed throughout its volume, a hologram. The support medium interacts with an analyte, resulting in a variation of a physical property of the medium. This variation induces a change in an optical characteristic of the holographic element, such as its polarisability, reflectance, refractance or absorbance. If any change occurs whilst the hologram is being replayed (e.g. using incident broad band, non-ionising electromagnetic radiation), then a colour change, for example, may be observed using an optical detector. The optical detector may be a spectrometer or simply the human eye.
WO-A-99/63408 describes an alternative method of producing a holographic sensor. A sequential treatment technique is used, wherein the polymer film is made first and sensitive silver halide particles are added subsequently. These particles are introduced by diffusing soluble salts into the polymer matrix where they react to form an insoluble light-sensitive precipitate. The holographic image is then recorded.
The holographic sensors described above are made by recording a hologram using a plane mirror, which is holographed in a trough of suitable liquid. Furthermore, the support media of the sensors are planar. This arrangement may not always be effective if the sensor is to be used in an environment where there is considerable light scatter, e.g. subcutaneously. In addition, the optical detector must be placed at a particular position with respect to the sensor, in order to detect reflected light.
The present invention is based on a realisation that the above problems can be addressed by forming the hologram as a non-planar mirror. This can be achieved in various ways, e.g. by recording the hologram using a non-planar mirror and using non-planar support media.
Accordingly, a first aspect of the invention is a sensor comprising a medium and, disposed therein, a hologram, wherein an optical characteristic of the hologram changes as a result of a variation of a physical property of the medium, and wherein the hologram is formed as a non-planar mirror.
A second aspect of the invention is a method for the production of a sensor of the invention, which comprises forming, in a medium, a hologram as a non-planar mirror.
Another aspect of the invention is a method for the detection of an analyte, which comprises remotely interrogating, with light, the holographic element of a sensor of the invention; and detecting any change in an optical characteristic of the sensor.
The invention allows for the design of holographic sensors which can reflect incident light in an accurate and predetermined fashion. The invention may obviate the requirement for the optical detector to be “brought” to the sensor. Indeed, the invention provides sensors which can be interrogated from a wider range of angles and distances. Sensors of the invention may be used as subcutaneous implants or in security, for example as authentication tags.
There are numerous ways in which the hologram can be formed as a non-planar planar mirror. It will be appreciated that the various techniques described in herein can be used alone or in combination, to achieve this effect.
A preferred embodiment of the invention involves recording the hologram using a non-planar mirror. The type of mirror selected will depend on the desired effect that the resulting hologram will have on incident light. Many different types of non-planar mirror are known, for example, concave and convex mirrors (e.g. semi-cylindrical mirrors), reflective beads and the like. Alternatively, the mirror may be a prism, for example a corner cube prism, a right angled prism, a Porro prism, an Amici prism, a Dove prism, a Penta prism, a rhomboid prism or a Lernan-Springer prism.
In a preferred embodiment, the mirror is a concave mirror. This allows for the production of a sensor which has a focusing effect on incident light. Such a sensor has a wide range of possible uses, for example as a small subcutaneous implant which can be conveniently interrogated using a fibre optic bundle. Furthermore, to overcome the major obstacle of the problem of light scatter, the replay wavelength range can be adjusted to extend well into the near infra-red. Another advantage associated with the use of a concave mirror is that unwanted specular white light is, in general, not focused by the hologram. Also, if observed from the opposite side, a concave hologram may have a convex mirror effect on incident light, and vice versa.
Another preferred embodiment involves the use of a convex mirror, to produce a hologram having an increased focal length and a collimating effect on incident light. An increased focal length is particularly desirable for applications where remote detection is required, for example the detection of an analyte in a fuel tank.
The non-planar mirror may be one capable of effecting retroreflection, such as a corner cube prism. Corner cube prisms typically reflect, up to a certain (“tolerance”) angle, any light entering the prism back towards the light source, regardless of the orientation of the prism. A hologram recorded using a corner cube prism may therefore have a retroreflecting effect on incident light. Such a sensor is advantageous because the optical detector does not need to be placed at a particular position with respect to the sensor. Another benefit associated with the use of a corner cube prism is that any response of the sensor can be viewed from a wider range of angles (i.e. a greater angular tolerance) than for a conventional sensor.
A retroreflecting holographic sensor may be used to detect changes in atmospheric conditions (e.g. humidity, temperature, levels of carbon dioxide or other chemically active gases) on a planet with an atmosphere. Detection may be achieved by interrogating the sensor with a collimated light beam or other remote light source. Such sensors may also be used to detect changes in underwater environments. For example, changes in the levels of pH or ions could be detected.
Alternatively, the non-planar mirror may consist of one or more reflective beads. Reflective beads can be used to increase the intensity of the reflected light and may also allow retroreflection.
It is preferred that the mirror is a dielectric material, since dielectric materials have a high reflective efficiency. Alternatively, a parabolic mirror may be used, to minimise the effects of chromatic and spherical aberration.
The hologram may be recorded in a non-planar support medium. In this case, the mirror need not necessarily be non-planar since the geometry of the support medium defines that of the hologram.
The hologram may be recorded using a lens and an aperture/obstacle, placed before the holographic recording material, during the recording process. When the hologram is recorded, radiation passes first through the lens and aperture/obstacle, and then the recording material, before reaching the mirror. The resulting hologram may, as a consequence, have a specific diffraction pattern. Such effects are desirable since they may result in a well-defined, specific pattern of replay light. Lenses may also be used to change the object size, collimate light or give a circular beam.
A holographic sensor of the type used in this invention generally comprises a holographic support medium and, disposed throughout the volume of the medium, a hologram. The support medium interacts with an analyte resulting in a variation of a physical property of the medium. This variation induces a change in an optical characteristic of the holographic element, such as its polarisability, reflectance, refractance or absorbance. If any change occurs whilst the hologram is being replayed by incident broad band, non-ionising electromagnetic radiation, then a colour or intensity change, for example, may be observed.
There are a number of basic ways to change a physical property, and thus vary an optical characteristic. The physical property that varies is preferably the size of the holographic element. This variation may be achieved by incorporating specific groups into the support matrix, where these groups undergo a conformational change upon interaction with the analyte, and cause an expansion or contraction of the support medium. Such a group is preferably the specific binding conjugate of an analyte species. Another way of changing the physical property to change the active water content of the support medium.
A holographic sensor may be used for detection of a variety of analytes, simply by modifying the composition of the support medium. The medium preferably comprises a polymer matrix, the composition of which must be optimised to obtain a high quality film, i.e. a film having a uniform matrix in which holographic fringes can be formed. The matrix may be formed from the copolymerisation of, say, (meth)acrylamide and/or (meth)acrylate-derived monomers, and may be cross-linked. In particular, the monomer HEMA (hydroxyethyl methacrylate) is readily polymerisable and cross-linkable. PolyHEMA is a versatile support material since it is swellable, hydrophilic and widely biocompatible.
Other examples of holographic support media are gelatin, K-carageenan, agar, agarose, polyvinyl alcohol (PVA), sol-gels (as broadly classified), hydro-gels (as broadly classified), and acrylates. Further materials are polysaccharides, proteins and proteinaceous materials, oligonucleotides, RNA, DNA, cellulose, cellulose acetate, polyamides, polyimides and polyacrylamides. Gelatin is a standard matrix material for supporting photosensitive species, such as silver halide grains. Gelatin can also be photo-cross-linked by chromium III ions, between carboxyl groups on gel strands.
The sensor may be prepared according to the methods disclosed in WO-A-95/26499 and WO-A-99/63408. A suitable arrangement for this purpose is shown in
The invention will now be described by way of example only, with reference to the accompanying drawings.
As indicated above, a sensor of the invention is particularly suitable for use in conjunction with a unit, e.g. of optical fibres, whereby light can be transmitted to and from the hologram. A suitable bundle of fibres, ending in a probe tip, is shown in
In the particular embodiment shown in
Corner cube devices are such that, if the incident light is diverging, then the retroreflected lightwill continue to diverge, possibly resulting in a poor signal. Thus, it may be desirable to ensure that incident light is collimated or converged. In the case of the fibre optic arrangement of
The utility of the invention will now be described, with particular reference to
In
The holographic concave mirror image focuses the coloured light onto the central fibre. A valuable feature of working on axis (unlike conventional techniques, where the diffracted light is arranged to reflect off at a slightly different angle to the specularly reflected light) is that, as the diffracted wavelength changes, it remains focused on the central position.
In use, the intention is not necessarily to track changes in intensity of the returning light. If as much as 99% of the light is lost due to scatter, then being able to track a small wavelength shift in the remaining 1% from a very highly diffracting implanted smart hologram may be satisfactory. In order to reduce the problem of scattered light, it may sometimes be helpful to make the hologram with an off-axis concave mirror.
For use as an implant, the sensor may have to be covered with material to reduce rejection problems. This should not affect the detection of analytes found in the body, such as glucose or ions.
In a particular embodiment of the invention, a concave mirror sensor can have its centre removed or covered so that it is in the form of a ring. This is illustrated in
The following Example illustrates the invention.
A support medium was formed by polymerising a mixture of 60 mole % acrylamide, 30 mole % methacrylamide, 4.9 mole % methylene bisacrylamide, and 5.1 mole % 2-acrylamido-2-methyl-1-propanesulphonic acid. DMPA in DMSO (433 ml) was used per 0.1961 g of dry constituents. 100 μl of mixture was used per slide and polymerised for 30 minutes at 20.7° C.
AgNO3(0.25 M, 400 ml) was then soaked into the polymer for 2 minutes, the excess wiped off and the slide dried for five minutes under a stream of warm air. The slide was then agitated for one minute using 4% (v/v) QBS dye in 1:1 methanol:water containing 4% KBr (v/v), and then rinsed in distilled water to remove excess bromide ions and any silver bromide remaining on the surface.
The slide was placed polymer side down in a dish containing two adjacent concave mirrors and a 60% ethanol (v/v) and water solution, and allowed to settle for five minutes. The holographic image of the two mirrors was then recorded using a laser.
The image was developed by using a 4:1 ratio of Saxby A: Saxby B developer, rinsing in deionised water, placing in a stop solution (5% acetic acid {v/v}) and rinsing in deionised water a final time. The slide was then placed in sodium thiosulphate and agitated for 5 minutes, to remove excess silver and QBS dye. The slide was then placed in methanol for around twenty minutes, to remove any remaining dye.
The hologram was observed using a probe, which consisted of a fibre optic bundle in conjunction with a 12.5 mm focal lens. The separation between the bundle and the lens was the same as that between the lens and the sensor, i.e. 25 mm. Observation was made using a rig which allowed the angle of viewing to be adjusted, at a constant probe distance. The peak diffraction wavelength was noted at each angle until the peak disappeared into background noise.
The results are shown in
Number | Date | Country | Kind |
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0317092.5 | Jul 2003 | GB | national |
0400350.5 | Jan 2004 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB04/03176 | 7/21/2004 | WO | 1/16/2007 |