RU2271741C2 - Device for non-invasive finding of sugar content in patient's blood - Google Patents

Abstract

FIELD: analysis of material; testing of materials.

SUBSTANCE: device can be used for finding amount of glucose from time of spin-lattice relation of T₁ nuclei in blood. Device has NMR detector made in form of inductance coil for finger which detector is disposed in space of permanent magnet. Detector is connected with analyzer made in form of NMR-spectrometer. Description of spectrometer is provided.

EFFECT: improved precision; improved truth of measurements.

4 dwg

Description

The invention relates to the field of research or analysis of materials by determining their chemical or physical properties by special methods, in particular by determining the time of nuclear magnetic relaxation in serum and in blood plasma T ₁ based on nuclear magnetic resonance.

A device for non-invasive determination of sugar content in human blood containing a monocular tube, a strictly fixed length of 330 nm, in which there are sources of spectral radiation, made in the form of AL 360 LEDs in red and yellow.

Patent of the Russian Federation No. 2023270, IPC: G 01 N 33/66, 1994.

A normal peak brightness of yellow and red pulses is applied to the patient’s eye with normal color perception, the critical flicker fusion frequency is determined, and then the desired concentration is calculated. The device makes it possible to determine the deviation of glucose in the blood by the value of the derivative. The use of the device is limited in violation of color perception, with myopia and hyperopia, when the eye ceases to be an optical device.

A device for non-invasive determination of sugar content in human blood, containing a sensor and an analyzer, the sensor is made in the form of a high-frequency generator, the analyzer is in the form of a measuring bridge and a sensitive inductive element included in the diagonal of the bridge.

Measurements and analysis are carried out using high-frequency oscillations, through the action of a finger on the sensitive inductive element of the analyzer.

Patent of the Russian Federation No. 2088927, IPC: G 01 N 33/49, 1997 (prototype).

In this device, the human finger is essentially a core that changes the inductance of the analyzer sensitive element. These changes depend on the size of the finger, on the surface of the skin, which can be soft or rough, which brings significant changes in inductance.

Neither the analog nor the prototype have a high accuracy in estimating blood glucose. They make it possible to obtain only qualitative information about deviations of the sugar content in one’s own blood in one direction or another, if the mandatory individual calibration has been previously carried out using the invasive method.

This device eliminates the disadvantages of analog and prototype.

The technical result of this invention is the possibility of non-invasive diagnostics for any patients, improving the accuracy of measurements.

The technical result is achieved by the fact that in the device for non-invasive determination of sugar content in human blood containing a finger sensor with an analyzer, the analyzer is made in the form of an NMR spectrometer containing a magnetic field generator with coils, an asymmetric pulse generator for low-frequency modulation with remote coils, high-frequency weak oscillation generator connected to a finger sensor, sound frequency modulating voltage generator with remote coils, sound amplifier frequency, microprocessor, program control unit and magnet with a uniform magnetic field, in areas with a uniform field of the magnet there are asymmetric pulse generator coils for low-frequency modulation, sound frequency modulating voltage generator coils, an NMR sensor with an inductance coil for the finger and is located in the gap of the permanent magnet, the generator of the change in the magnetic field is configured to abruptly change the magnetic field, and the generator of asymmetric pulses is made to generate triangular pulses.

In zones with a uniform magnet field, the coils of the asymmetric pulse generator for low-frequency modulation are located.

The invention is illustrated in figures 1-4.

Figure 1 shows the experimental dependence of the spin-lattice relaxation time T ₁ on the glucose concentration for the finger obtained by the authors.

Figure 2 presents the scheme for obtaining two alternating amplitudes of signals with asymmetric modulation of the field. To create asymmetric modulation, a system of modulating coils is used, in which the current changes according to a triangular law. To change the time interval inside a pair of signals, a system of coils is used in which the direct current is changed abruptly according to the program embedded in the control unit.

Figure 3 schematically shows a schematic diagram where: 1 - a constant current source with coils 1s, 2 - a triangular pulse generator for low-frequency modulation with 2m coils, 3 - an audio modulating voltage generator with coils 3z, 4 - a high-frequency (HF) generator small vibrations with an NMR sensor for a finger 4e, 5 - an audio frequency amplifier, 6 - a program control unit, 7 - a processor for controlling, recording and processing NMR signals, 8 - a magnet (in this example, a constant).

Figure 4 presents a sequence of pairs of pulses experimentally obtained on a breadboard installation with a variable time interval between them. The amplitude of the first signal (left vertical line) remains constant, and the amplitude of the second signal increases as the time interval between them increases. (Based on these measurements, the spin-lattice relaxation time T ₁ is calculated.)

The basis of this device for non-invasive determination of blood sugar in humans, including measurements based on nuclear magnetic resonance (NMR) of the spin-lattice relaxation time T ₁ , is a direct dependence of this time T ₁ on the concentration of glucose in the blood (figure 1).

The human finger is an almost perfect object for such measurements. There are many capillaries in the fingers, in which the blood speed is small 0.5-1.2 mm / s, and the effect of artifacts on movement is minimized. The volume occupied by the intercellular fluid, blood and muscle tissue, allows to obtain the amplitudes of the NMR absorption signals from the liquid component of the finger, sufficient for further amplification and processing. Small changes in the ratio of volumes occupied by bone and muscle tissue, which may be in different people, do not make significant changes in the measured value of T ₁ .

Thus, when registering a magnetic resonance absorption signal from a finger, the signal from blood and intercellular fluid is actually measured, and since the glucose concentration in the latter depends on its content in the blood, the relaxation time behavior is directly related to the glucose concentration in human blood. Essentially, the finger functions as a vessel that weakly affects the measurement of blood parameters.

A non-invasive device for determining glucose in human blood works as follows.

The finger is placed in the inductive sensor 4e, which is an inductor with a diameter of 15 mm and a height of 15-20 mm, located in the gap of the permanent magnet 8 and which is part of the oscillating circuit of the high-frequency oscillation generator 4. High-frequency oscillations of electromagnetic energy are generated by the generator 4 in the mode of weak oscillations, when in which small changes in the quality factor of its master circuit lead to a change in the amplitude of the generated oscillations, and a change in inductance or capacitance leads to a change in the frequency of these oscillations niy. A finger placed inside the coil significantly (by several percent) reduces the oscillation frequency of the generator. To eliminate this undesirable effect, the device provides a system for automatically adjusting the frequency of the RF generator. They apply voltage to the asymmetric modulation generator 2, which feeds the coil 2m, to the audio frequency generator 3, which feeds the coil 3s, and the control pulses from the program control unit 6 to the direct current source with coils 1s, which creates in this embodiment jumps of a constant magnetic field using coils 1s .

The decrease in the amplitude of oscillation of the generator circuit, caused by the absorption of electromagnetic energy at the time of resonance, modulated by the sound frequency, is amplified by a high-frequency resonant amplifier. After the amplitude detector, the signal is amplified by a narrow-band amplifier 5 at the modulation sound frequency. After the second amplitude and pulse detectors, the signal is fed to the ADC and then to the memory cell of the microprocessor 7. Thus, all NMR signals, as well as time intervals between absorption signals, are recorded in the microprocessor memory.

Absorption signals appear twice during one period of triangular modulation when the NMR conditions are satisfied

H ₀ = ω ₀ / γ _p = H _pm + nΔH _u + 2H _m 2t ₁ / T _m ,

where ω ₀ is the frequency of the generator of weak oscillations,

γ _p - gyromagnetic ratio for hydrogen nuclei,

H ₀ - magnetic field at which there is a resonant absorption of electromagnetic energy,

N _pm - the magnetic field created by a permanent magnet,

ΔН _u - abrupt change in the magnetic field when applying one control pulse,

n is the number of pulses supplied,

2N _m - doubled amplitude of the triangular modulation of the magnetic field,

t ₁ - the time elapsed from the beginning of the period to the appearance of the first absorption signal,

t ₂ = T _m -t ₁ - the time of occurrence of the second signal, while the time between two signals τ = T _m -2t ₁ ,

T _m - the period of triangular modulation, when one control pulse is applied, the time interval between pulses will change by Δτ = T _m ΔН _u / 4Н _m .

The use of double modulation can significantly increase the signal-to-noise ratio and thereby reduce the error in determining the time T ₁ .

The requirements for the stability of the source creating jumps in the magnetic field are significantly reduced, because the measurements are carried out in a modulation mode, the amplitude of which is many orders of magnitude higher than the amplitude of the fluctuations in the current source. Additional modulation of the magnetic field is carried out at the frequency of the sound range. The period of current jumps is a multiple of the period of triangular modulation T _ck = nT _m .

The spin-lattice relaxation time T ₁ is determined from the relation

T ₁ = τ / -ln (lA (τ) / A ₁ ,

where τ is the time between a pair of signals,

And (τ) is the amplitude of the second signal,

A ₁ - the amplitude of the first signal, which is not lower than the amplitude of the second signal A (τ) and remains unchanged during measurements.

Some variation in the amplitude of the first signal A ₁ determines the measurement error of the spin-lattice relaxation time T ₁ . All information about the amplitudes of the first and second signal, as well as the time interval between them, is sent to a computer, where, according to a given program, the spin-lattice relaxation time T ₁ is determined and the glucose concentration is determined using a calibration coefficient.

Claims (1)

A non-invasive device for determining the sugar content in human blood, containing a finger sensor associated with the analyzer, characterized in that the analyzer is made in the form of an NMR spectrometer containing a magnetic field change generator with coils, an asymmetric pulse generator for low-frequency modulation with remote coils, high frequency weak oscillation generator connected to a finger sensor, sound frequency modulating voltage generator with remote coils, sound frequency amplifier, m a cropping processor, a program control unit and a magnet with a uniform magnetic field, in areas with a uniform magnetic field there are asymmetric pulse generator coils for low-frequency modulation, sound frequency modulating voltage generator coils, the sensor is made in the form of an NMR sensor with an inductance coil for the finger and is located in the gap of a permanent magnet, the generator of the change in the magnetic field is configured to abruptly change the magnetic field, and the asymmetric pulse generator is made with the ability to form triangular pulses.

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