DE4410888A1 - Apparatus for irradiating human tissue using multi-wavelength IR light - Google Patents

Abstract

An apparatus for irradiating human tissue uses differing wavelengths in the IR spectrum ie. 600 to 1100 nm and ensures that the wavelengths chosen differ by at least 150 nm. The light energy is partially absorbed and undergoes scattering in passing through the tissue as a result of which the characteristic distribution patterns generated by different illumination spectra are registered by a CCD camera (1, 2, 3) for presentation as video images (4). Various devices for optimising the ergonomic design of the sensor equipment (7) are shown and algorithmic processing (8) of the recorded data (5) is used to reveal changes in tissue structure or metabolism.

Description

The invention relates to an arrangement for irradiating human Tissue, preferably by means of IR radiation.

It is already known, after irradiation of infrared light in one space to be represented, which is part of the human body, one after the Radiation visible image after electronic-optical conversion by means of to represent photographic or television technology processes. (DD 1 21 479)

DE-C2 30 37 983 describes the light-induced, scanning microscopic representation of Sample parameters in their spatial distribution, among others by Illumination with IR radiation described.

The sample is scanned in the form of a grid by a light beam on the illumination side and detects the radiation emanating from the sample in time with the raster, wherein at least two different radiation components are detected whose one is not in the spectral range used on the lighting side.

In DD 2 10 202 is a device for radiography and Coarse structure examination, preferably described on medical objects, which uses infrared or visible circularly polarized light to do that examining object penetrates and on an analyzer on a photoelectric radiation receiver falls.

A matrix-like scanning of the sample is carried out, with Rotating the device around any angle values a "tomographic" Acquisition of all unit cells of the body shown is achieved.

In DE-A 40 15 988 an infrared tomograph is described, which with Infrared radiation and the principle of confocal imaging works, whereby by suitable means the infrared inherent radiation of biological tissue should be made visible, and the scattered radiation is eliminated.

DE-A 41 30 369 describes a lighting device for light in the red to described infrared light, being a two-dimensional, spatially resolving Image sensor for detecting the rays emanating from the object is provided.  

Scattered radiation correction is carried out.

It has also been proposed (DE 4 24 416), the tissue examined to be irradiated with light of two wavelength ranges and either in Transmission or in remission to change the scattered light distribution detect.

Furthermore, it was proposed (DE 42 41 772), changes in the optical Density distribution using an optical-synthetic aperture method temporally spatially segmental point lighting with simultaneous location and to detect correlated detection of the scattered light, the one to be examined Tissue can be positioned in a double line scanner, the first of which Scan process the distribution of intensity distribution dependent on the distribution angle diaphanoscopic tissue radiation detected using a point light source.

The object of the invention is now, while evaluating the radiation with infrared light scattering light distributions on parts of the body generate that allow a metabolic and structural assessment and imaging can be detected.

The object of the invention is achieved by the characterizing features of the first and second main claim solved. Preferred further developments are in the Subclaims described.

Starting from the known state of the art, surprisingly shown that in the spectral range between 600 and 1100 nm, especially at about 800 nm, a much more effective penetration of biological tissue is possible, but the better transmission at the expense of one higher scatter due to the shorter wavelength. Contrary to everything Expectation, however, turned out to be completely surprising that the Light scattering in biological tissue has a high forward anisotropy in it Spectral range, so that when illuminating thick tissue structures of approx. 5 cm and more with a collimated light beam the center of the  Streuhof still transmitted a high directional memory of the Has radiation pattern. According to the invention, therefore Lighting unit developed, the one with the smallest possible outlet opening has a high degree of collimation and by means of which diagnostically relevant Body parts can be illuminated with a suitable shape such that the diametrically opposite surfaces with a likewise location or space-filtered imaging optics according to the invention on a highly sensitive infrared detector, typically a CCD component, can be mapped.

In particular, preferred embodiments of the invention Agreement structured as follows.

For the introduction of the radiation into the pharynx, an applicator is advantageously used for the symmetrical irradiation of both maxillary sinuses, which is equipped with fiber optics, which has collimation stacker at the distal ends. For a more detailed description of a preferred exemplary embodiment of the invention, the most important details are shown in more detail in FIG. 1.

Fig. 1 Schematic representation of the radiation applicator adapted to the object symmetry for the diaphanoscopic fluoroscopy of the maxillary sinuses.

The fiber-optic leg elements ( 1 ) provided with the collimation taper for point-by-point irradiation into the tissue are contained in a clamp-pliers arrangement ( 2 ), which allow the lateral irradiation angle to be adjusted to match the current anatomical geometry. In principle, motor-controlled angle rotary devices can also be used to improve the ergonomics of the device. The fiber-optic elements are guided by front coupling to a flexible Y light guide ( 3 ) from the clamp pliers to an optical band filter (600 nm-1300 nm) ( 4 ) of the light source ( 5 ). In principle, the light source can also be operated in a modulated manner in order to enable different detection and evaluation methods on the receiver side (time and frequency range) and to improve the signal-to-noise ratio in a known manner. Furthermore, one or two laser diodes ( 6 ) as a radiation source could be coupled directly to the applicator or via beam splitters ( 7 ). Radiations at two wavelengths (in the optical window of the tissue) can then advantageously be irradiated. In order to determine optimally disease-related changes in scatter and absorption, one radiation wavelength must be between 600 nm and 700 nm and the other must have a minimum wavelength distance of + 150 nm. When using laser diodes, the extension to the presented modulation principle also makes sense. The second group of essential sub-elements of the device is arranged in the receiving and evaluating device. The disease-specific scattered radiation that arises during the irradiation is recorded on the front of the head with a highly sensitive camera (advantageously CCD camera) with a limit sensitivity better than 0.1 lux.

Fig. 2 schematic representation of the cameras with their electrically coupled evaluation elements.

As shown in FIG. 2, the recording camera ( 3 ) has an optical pass filter which is adapted to the radiation wavelengths mentioned above and which, as a dielectric filter ( 1 ), advantageously also mirrors the recording situation so that it is visible to the patient. This offers the advantage of only roughly positioning the camera mounted on a wall arm or movable tripod. As described, the light-scattering fabric is characterized by a high forward anisotropy. If the camera ( 3 ) is optionally supplemented by an optical spatial filter ( 2 ) in a known manner, then, in continuation of the idea according to the invention, the chaining of these two conditions results in an optimal directional evaluation of the scattered radiation and thus a higher selectivity for the information parameter of the signal a. To make the scattered light distribution visible, both a monitor ( 4 ) and a video printer ( 5 ), which is usefully operated with a foot switch, must be connected to the camera.

Since lying patients also have to be examined, it is advisable to supplement the arrangement with video glasses ( 7 ). Since the result of the fluoroscopy can only be seen by one miniature monitor and optics on these glasses, the patient can still be checked in the horizontal exposure situation with the patient lying down. As a further option, the computer connection ( 8 ) can be implemented in a known manner with the aim of image storage and evaluation. Since the scattered light distribution reacts depending on the type of tissue and the state of the tissue, known methods of image evaluation, such as densitometric evaluation of alphanumeric stored signal values, false color representation, reflectance analysis and weighted image subtraction of 2-wavelength images lead to new effects. In all algorithmic implementations, signal and / or patterns correlate with the metabolic and / or structural changes in illuminated tissue volumes. Since the device follows the ergonomic conditions of the in vivo investigations, the spatial arrangement of the detector is of great importance.

Fig. 3 schematic representation of elements of the device for the detection and display of scattered light distributions in the special arrangement on the browband.

The arrangement of a miniature recording camera ( 1 ) on a browband ( 2 ) is advantageous. The detected signal can be displayed directly on a miniature monitor ( 3 ) (combined with an optical adjustment) on the front section of the headband. There is also the possibility of presenting the result of an image processing after the signals have been sent back and forth to an image processing module ( 6 ) on the monitor screen in real time. At the same time, the current image of the scattered light distribution can be obtained via a module ( 4 ) with filter collimation, optics and electronic-optical image converter, which receives its high voltage from the supply module ( 5 ). In continuation of the inventive concept, fluorescence angiographic images can be optically derived in parallel, with a recording detecting the NIR-filtered scattered light distribution, while the recording channel is matched to the fluorescence band of the fluorescence marker in terms of filter technology. The method and device can thus advantageously be used for the screening of inflammatory, edematous and tumorous processes, primarily in the ear, nose and throat area. In addition, there is the possibility of intraoperative use to determine acute cerebral hemorrhage and in open heart surgery. In addition to ENT follow-up checks, methods and devices for examining stray light changes in rheumatic diseases can be used.

Fig. 4 schematic representation of a spatial filtering and cross-sectional adjustment.

In continuation of the idea according to the invention, it is advantageous to optically couple a cross-sectional, ordered fiber-optic taper ( 1 ) to the CCD chip of the camera ( 2 ) in a known manner for the diagnosis of small joints. This fiber-optic element can also be provided with a space-filtering shaft matrix ( 3 ) on the front. In the case of collimated irradiation ( 4 ), the scattering and absorption characteristics of the irradiated tissue as well as the directional information of the photons are decoded at the same time.

Claims (23)

1. Arrangement for irradiating human tissue, preferably by means of IR radiation using at least two wavelengths in a radiation range from 600 nm to 1100 nm, characterized in that the wavelengths are at a minimum distance of 150 nm and the tissue-specific, when radiating, generated scattered light distribution is detected with an image recording system. 2. Arrangement for radiography of human tissue, preferably using IR radiation preferably in symmetrically arranged human Body cavities, characterized in that, preferably simultaneously, in at least two Areas the tissue-specific light distribution, preferably the Scattered radiation is detected and a comparison of the detected radiation images he follows. 3. Arrangement according to claim 1 or 2, characterized in that a at least two-leg fiber optic radiation applicator for Irradiation is provided. 4. Arrangement according to one of claims 1-3, characterized in that the Irradiation direction is changeable. 5. Arrangement according to one of claims 1-4, characterized in that the Radiation applicator at least one fiber optic with a collimation taper has at the distal end. 6. Arrangement according to one of claims 1-5, characterized in that the Radiation applicator as a two-leg, expandable clamp with two fiber optic elements is formed.   7. Arrangement according to one of claims 1-6, characterized in that the lateral angle change of the fiber optic elements a symmetrical Adaptation to bidirectional irradiation implemented. 8. Arrangement according to one of claims 1-7, characterized in that the Directional adjustment of the fiber optic elements of the radiation applicator, independently of one another, in at least one direction. 9. Arrangement according to one of claims 1-8, characterized in that about the applicator is irradiated with several wavelengths. 10. Arrangement according to one of claims 1-9, characterized in that a Radiation of a wavelength of approximately 800 nm is used. 11. Arrangement according to one of claims 1-10, characterized in that the Irradiation takes place via laser diodes. 12. Arrangement according to one of claims 1-11, characterized in that Both filtered conventional light sources and laser diodes are modulated or operated in pulsed mode. 13. Arrangement according to one of claims 1-12, characterized in that a light sensitive camera is used which is a mirror of the edge filter for position control of the patient. 14. Arrangement according to one of claims 1-13, characterized in that the Camera is provided with a special lens that filters space enables. 15. Arrangement according to one of claims 1-14, characterized in that the detecting camera parallel video printer with foot switch, monitor, Video glasses and computers for image evaluation are connected.   16. Arrangement according to one of claims 1-15, characterized in that the video glasses the observation of the fluoroscopic situation in everyone Position of the patient. 17. Arrangement according to one of claims 1-16, characterized in that an image processing the symmetrical comparison of the scattered light distribution enables including such procedures as densitometric Evaluation, false color representation, remission analysis and weighted Image subtraction. 18. Arrangement for screening body parts according to one of the claims 1-17, characterized in that optional camera, miniature monitor, optoelectric image converter element and high voltage source to one Headband can be mounted. 19. Arrangement according to one of claims 1 to 18, characterized in that a detection channel optically on the scattered light distribution and a Detection channel optically for the fluorescence of an angiographic Fluorescence of an angiographic fluorescent marker are matched. 20. Arrangement according to one of claims 1 to 19, characterized in that a collimated, scannable light source is a fiber optic taper the cross section is adapted to biological structures Receiving image without lens is coupled into the CCD sensor. 21. Arrangement according to one of claims 1-20, characterized in that on distal end of the fiber optic tapers a layer is applied, which in the Diameter grid of the sensory pixels through a shaft ratio 5 a Room filtering implemented. 22. Arrangement according to one of claims 1-21, characterized in that an optical spatial filter is arranged upstream of the image recording system.   23. Arrangement according to one of claims 1-22, characterized in that the Image recording system connected to a flat image display unit is.