RU77144U1 - DEVICE FOR NON-INVASIVE DETERMINATION OF BLOOD PARAMETERS - Google Patents

Abstract

The utility model relates to the field of medical technology, in particular, to the measurement of circulating blood characteristics carried out by means of optical control and spectroscopy.

A device for non-invasive determination of blood parameters, comprising an optical observation system with lighting devices and image detectors connected to an electronic signal processing unit and attached to the housing with a tool tray for placing the object of study so that its outer side with the nail faces the visual window of the optical observation system wherein the device contains at least two image receivers, the lighting device further comprises at least one laser source and the radiation and the optical system comprises at least one dichroic mirror to provide a spectral decomposition of the image of the object of the study.

The proposed utility model provides the possibility of stable long-term non-invasive monitoring of the parameters of capillary microcirculation and spectral characteristics of blood and adjacent tissues with real-time data output in single and periodic blood flow measurements using tests specified by the researcher.

1 n.p., 1 Fig.

Description

The utility model relates to the field of medical technology, in particular, to the measurement of circulating blood characteristics carried out by means of optical control and spectroscopy.

The most important part of the bloodstream is the system of capillaries, designed to provide organs and tissues with all the substances necessary for life. Large vessels carry out the delivery of these substances, and in the capillaries they pass into the tissues and at the same time the decomposition products are removed from the tissues into the bloodstream. The study of microcirculation in healthy and sick people with individual disorders of the cardiovascular system can be used to assess the functional state of the human cardiovascular system and its orthostatic stability, in particular, in relation to clinical practice.

Currently, medical laboratory diagnostics with great attention and willingness to use refers to the development of new diagnostic tests without the need for blood sampling. This is determined by the increased likelihood of infection of the patient during the procedure, associated with damage to the skin during puncture of veins and capillary vessels, as well as discomfort and pain associated with blood sampling. Therefore, the creation of devices and methods for diagnostics is experiencing a sharp rise. The main focus is on the development of non-invasive methods, which are most often used in the activities of clinical diagnostic laboratories (general blood count, determination of glucose, etc.).

Obtaining such information is possible during the visualization of the microvasculature using optical microscopy and analysis of diffuse scattering spectra from vascular structures.

The development of such devices has been actively conducted in recent years in the United States and Japan. An analysis of the patent literature showed that the most advanced technical solutions are embedded in the patent [1].

Close technical solutions are incorporated in the American patent [2] of the Japanese company Sysmex Corporation "Noninvasive blood analyzer".

The prospect of a non-invasive determination of these laboratory parameters is confirmed by the inclusion in this patent race of the American giant manufacturer of medical equipment company Abbott Laboratories [3].

Recently, it has been shown that it is possible in principle by spectral features of reflected radiation to distinguish between normal hemoglobin and glycosylated. So in the US patent [4] of June 24, 2003, the amount of glycosylated hemoglobin is determined by the difference in the absorption spectra of Hb and HbA _1c .

Related proposals were previously patented in the US patent [5] of November 13, 2001. It should be noted, however, that the aforementioned approaches for the determination of glycosylated hemoglobin apply to cases where sampling is necessary, and therefore they do not apply to non-invasive methods.

A device for automatically recording the dynamic characteristics of the process [6], containing a holder for the test sample, configured to provide optical control of dynamic characteristics, an optical system for monitoring the object of study, in communication with a system for monitoring and recording the state of the studied object, containing a processor-based unit , designed to convert the system signal into a video signal, and a computer containing a video input card connected to the above indicated block.

These devices can record the mentioned characteristics, but they do not allow determining blood parameters from non-invasive measurements of its characteristics. Devices work as follows. After installing the finger of the subject in the holder and adjusting the device, in which the capillaries get into the focus of the recording optical system, recording of the image of blood cells moving along the capillaries is turned on. In this case, the light beam after being hit by the subject’s finger is reflected from the capillaries located under the nail plate, and after passing through the optical system, the CCD is recorded with the subsequent conversion into an electric signal and enters the computer. However, these devices do not allow to distinguish between red blood cells, platelets and leukocytes, do not allow a quantitative determination of their characteristics. What is especially important, these devices do not use the spectral characteristics of a signal beaten on a photodetector matrix in order to analyze it and obtain such blood characteristics as: the amount of hemoglobin in the blood, the degree of hemoglobin oxygenation, the degree of hemoglobin glycation.

The technical result of the proposed invention is the elimination of these disadvantages of the prototype, namely, improving the accuracy of measurement of characteristics due to non-invasive monitoring of the characteristics of capillaries, capillary blood flow and adjacent tissues through an optical monitoring system with lighting devices and image receivers connected to an electronic signal processing unit and attached to the housing lodgement for placing the finger of the subject so that its outer side with the nail is about It is connected to the visual window of the optical observation system, characterized in that the device contains at least two image receivers, in addition to the standard lighting source, at least one laser radiation source is introduced into the lighting device, at least one dichroic mirror is introduced into the optical system, which provides spectral decomposition of the object image research (base of the nail).

The device (Fig. 1) consists of an optical observation system (1) with at least one dichroic mirror (2) inserted into it for spectral decomposition of the image of the object of study, lighting devices (5) and at least two image receivers (3) connected with an electronic signal processing unit (4), and a lodgement (6) for placing the examined finger so that its outer side with the base of the nail (object of study) is facing the visual window of the optical observation system (1). In the lighting system (5), in addition to the standard illuminator, at least one laser radiation source is located.

The use of effective dichroic mirrors allows the decomposition of the image of an object into spectral ranges. In addition, the mirrors allow independent illumination of the object under study in various spectral ranges, including laser radiation sources, and independently receive images of the object in individual spectral ranges on separate photodetector arrays.

The use of laser sources makes it possible to use the dynamics of speckle structure to determine the dynamic characteristics of cellular structures moving in the blood. In particular, the dynamics of speckle structures makes it possible to determine the velocities of individual cell structures. It becomes possible to monitor the internal dynamics of red blood cells.

The installation of several cameras, each working in its own range, allows us to study the dynamic characteristics of the reflection spectra of tissues and blood. This allows you to monitor the processes of oxygen transfer from hemoglobin of red blood cells.

into the surrounding tissue right during their passage through the capillaries, which allows one to obtain the spectral characteristics of objects of study with time-lapse resolution and spatial resolution that is limiting for a given optical system.

The device operates as follows:

Light from light sources (5) through auxiliary translucent mirrors (7) is introduced into the optical system of the device (1) and, passing through the lens of the optical system (1), falls on the object of study (6). The reflected light enters the image receivers (3) and on the monitor screen of the signal processing system (4), an image of microcapillaries of the perivascular zone appears.

The examined person places a finger (preferably anonymous) in the lodgement (6) from the side of its open end so that its nail part with the perivascular zone is placed under the lens of the optical system (1).

After installation in the lodgement (6) of the finger, the nail bed of the finger is moved. At the same time, the character of microcapillaries is observed on the monitor screen of the signal processing system (4). As a result of the movement, the most suitable (for a sufficient number of capillaries and their type) monitoring section of the study is determined, and then calculation and static processing of parameters such as capillary density, degree of tortuosity, capillary diameters, perivascular area sectors, its volumetric characteristics, sizes and depth.

Next, they begin to monitor the state of blood flow and blood parameters in the capillaries in the selected area. To monitor the state of blood microcirculation and blood parameters, the image from the receivers is entered into the processor and processed.

For each image, measurement and storage in the array of static parameters of the capillaries, the image in different spectral ranges are carried out. When comparing two adjacent images, blood flow velocity is determined in the arterial, venous and transitional sections of the capillaries. The sites and rate of loss of oxygen by red blood cells are also determined.

To eliminate light reflexes and obtain the highest quality image of capillaries and shaped elements of the blood flowing in them, an immersion liquid is introduced between the finger and the inner surface of the lodgement, which allows you to eliminate the intermediate air between the optical system

instrument and skin surface, thereby creating the most favorable conditions for research.

The proposed utility model provides the possibility of stable long-term non-invasive monitoring of the parameters of capillary microcirculation and spectral characteristics of blood and adjacent tissues with real-time data output in single and periodic blood flow measurements using tests specified by the researcher.

Information sources:

1. US patent No. 6,104,939 of August 15, 2000

2. US Patent No. 6,061,583 of May 9, 2000.

3. US Patent US 6,662,031 of May 9, 2003.

4. US Patent US 6,582,964 dated June 24, 2003.

5. US patent US 6,316,265 from November 13, 2001

6. Patent RU No. 2294689 of 05/18/05.

Claims (1)

A device for non-invasive determination of blood parameters, comprising an optical observation system with lighting devices and image receivers connected to an electronic signal processing unit, and a lodgement attached to the housing to place the object of study so that its outer side with the nail faces the visual window of the optical system observation, characterized in that the device contains at least two image receivers, the lighting device further comprises at least one laz Nogo radiation source and the optical system comprises at least one dichroic mirror to provide a spectral decomposition of the image of the object of the study.