RU239180U1 - Ultrasonic sensor for ultrasound imaging device for lipid assessment - Google Patents

Abstract

The invention relates to medical equipment, specifically cardiovascular surgery and ultrasound diagnostics, and can be used for the simultaneous non-invasive ultrasound assessment of atherosclerotic lesions in peripheral arteries, including the location, length, and degree of stenosis, and spectroscopic analysis of optical data with the creation of a chemogram and the assessment of lipid content in the vessel wall. The invention relates to an ultrasound imaging system for assessing lipid content, consisting of a housing with a built-in signal generator of various wavelengths, connected by a cable containing a current conductor and optical fibers with a protective Teflon coating, a damper, a piezoelectric array, matching layers, and an acoustic lens, photodiodes located in the lateral walls of the system, and sensor photodiodes located along the longitudinal axis of the system at a distance of 2, 4, 6, and 8 cm and connected by optical fibers sealed into the system. The technical result of the utility model consists in increasing the information content of non-invasive ultrasound examination of peripheral arteries by obtaining information on the quantitative and qualitative content of lipids in the vessel wall and atherosclerotic plaque. 1 ill.

Description

The utility model relates to medical technology, namely to cardiovascular surgery and ultrasound diagnostics, and can be used for simultaneous non-invasive ultrasound assessment of atherosclerotic lesions of peripheral arteries, including the location, length and degree of stenosis, and spectroscopic analysis of optical data with the creation of a chemogram and assessment of lipid content in the vessel wall.

Using a device that combines two technologies allows not only to detect atherosclerotic plaque (ASP) and assess the degree of stenosis, but also to determine plaque structure, quantify lipid content, and identify a lipid-rich necrotic core. Numerous studies and three meta-analyses have shown that a lipid-rich necrotic core is a risk factor for carotid plaque complications and stroke [1-3]. Detection of ASP with high lipid content indicates a high risk of disease progression and complications, which influences treatment strategies and the choice of surgical method. Furthermore, detection of oxidized lipids is not only a marker of ASP instability but also of inflammation in the vessel wall, which can be used to assess disease activity in inflammatory arteritis.

Near-infrared spectroscopy (NIR) technology is based on the ability of various organic molecules to scatter and absorb near-infrared light of varying intensity and wavelength (from 800 to 2500 nm). For cholesterol and triglycerides, absorption peaks and maximum signal are observed at 930-980 and 1150-1220 nm. Unsaturated fats (the lipid core of adenosine bicarbonate) are detected by a shift in peaks at 1200-1300 nm. Oxygenated and oxidized low-density lipoproteins can produce shifts in the spectra at 1650-1750 nm.

A number of devices are known for invasive assessment of lipid content in coronary artery plaques using intravascular ultrasound (IVUS) - NIRS-IVUS (near-infrared spectroscopy + intravascular ultrasound): LipiScan IVUS (Infraredx TVC Imaging system, approved by the FDA in 2010), Makoto Imaging System (approved in Japan in 2014). These devices are an intravascular catheter with a sensor that allows for the construction of a 3D map of the vessel (ultrasound) and the identification of areas with high lipid content (NIR spectroscopy). To date, experience has been accumulated in using NIR spectroscopy of lipids in IVUS of the coronary arteries, which has confirmed the safety, efficacy, and benefits of this technology [4]. Based on comparisons with coronary tissue pathology at autopsy, the sensitivity of lipid plaque detection using NIRS-IVUS is 90%, and the specificity is 93% [5]. Several studies have demonstrated that NIRS-IVUS can help identify early non-obstructive atherosclerotic lesions with a high risk of adverse outcomes [6, 7]. The combination of ultrasound and NIRS-IVUS allows us to overcome the limitations of ultrasound and more accurately characterize the composition of atherosclerotic plaques, since calcification is not a limitation for spectroscopy. NIRS-IVUS technology has been evaluated in carotid artery lesions [8, 9], where it also demonstrated effectiveness in identifying complicated plaques with a lipid-rich necrotic core.

However, NIRS-IVUS is an invasive technique that requires expensive consumables and cannot be widely used in the primary outpatient and pre-hospital settings.

Currently, there are no devices with sensors for noninvasive multimodal vascular ultrasound using NIR spectroscopy. A method for multimodal ultrasound assessment combined with assessment of atherosclerotic plaque stiffness (strain elastography) is currently being studied in carotid artery pathology [10]. However, stiffness is a secondary indicator that does not provide qualitative or quantitative information about atherosclerotic plaque composition, unlike spectroscopy.

The closest analogue to the proposed utility model is the multipurpose ultrasound imaging device RU 190270 U1, June 26, 2019, which is an improved ultrasound transducer and console capable of producing three-dimensional volumetric ultrasound images. However, there are currently no analogues of a non-invasive linear ultrasound transducer capable of NIR spectroscopy.

The problem that this utility model is aimed at solving is the possibility of non-invasively assessing the lipid content in the vessel wall and the ASP.

The technical result of the proposed device is to increase the information content of non-invasive ultrasound examination of peripheral arteries by obtaining information on the quantitative and qualitative content of lipids in the vessel wall and atherosclerotic plaque.

The technical result is achieved due to the fact that during ultrasound duplex scanning the researcher visualizes the artery in the longitudinal and transverse scanning plane and at the selected scanning depth evaluates the presence and distribution of lipids in the vessel wall and atherosclerotic plaque.

The cause-and-effect relationship between the features of the utility model and the technical result consists of providing the possibility of non-invasive ultrasound multimodal assessment of atherosclerotic lesions of peripheral arteries, including the location, length and degree of stenosis, and spectroscopic analysis of optical data with the creation of a chemogram and assessment of the lipid content in the vessel wall.

The ultrasound imaging system with NIR spectroscopy consists of the following components: a main unit (consisting of an electronic unit, monitor, and control panel, housed in a single housing) for data processing and control; signal preamplifiers; a multifunctional ultrasonic linear transducer; and extension, power, and amplifier cables. Power is supplied at 100-240 V and a frequency of 50/60 Hz. The combined technical solutions employed in the proposed utility model allow for the creation of a device with optimal shape, geometric dimensions, and physical and mechanical properties. The arrangement of all working elements within a protective shell allows for simultaneous ultrasound and NIR spectroscopy without the risk of damage to photodiodes and optical fibers. The proposed system is made of inert materials that do not cause systemic or local allergic reactions and do not change their physicochemical properties when in contact with the body's biological environments. This includes not causing a significant local increase in temperature and not causing thermal injury in the area being examined.

The essence of the claimed utility model is further explained by figures, where

Fig. 1 shows an ultrasound imaging system with NIR spectroscopy.

The ultrasound imaging system comprises a housing 1 with a built-in signal generator of various wavelengths (930-980, 1150-1220, 1650-1750 nm) and a power of 10-20 mW per wavelength (the total power on the skin is less than 50 mW), connected by a cable containing a current conductor 2 and optical fibers with a protective coating of Teflon 3, a damper 4, a grid of piezoelectric elements 5, matching layers 6 and an acoustic lens 7 for standard generation and recording of an ultrasound signal. In addition, light of various wavelengths is transmitted from the parainfrared signal generator through optical fibers with a protective Teflon coating to generating photodiodes 8 built into the side walls of the system. The light reflected from the tissues is recorded by sensor photodiodes 9, located along the longitudinal axis of the system at a distance of 2, 4, 6 and 8 cm, connected via optical fibers with a protective Teflon coating 3 sealed into the system with a laser spectroscopy analyzer.

The device works as follows.

The patient lies supine. The physician applies gel to the area being examined to improve sensor contact with the skin. During duplex ultrasound scanning in the neck area anterior to the sternocleidomastoid muscle, the carotid artery is visualized in the longitudinal scanning plane at a specific depth. The vessel walls, intima-media complex, and the presence of atherosclerotic plaques are determined. The chemogram display is activated automatically upon startup or manually from the device's front panel. Spectroscopy mode is activated, and parainfrared light of a specific wavelength (930-980, 1150-1220, 1650-1750 nm) is emitted via LEDs through a generating photodiode. The reflected light is recorded by sensor silicon photodiodes located at distances of 20, 40, 60, and 80 mm from the generating photodiode. According to the Beer-Lambert law, the depth from which readings are taken is equal to half the distance from the emitter to the detector. Light passes through the tissue, is absorbed, refracted, and reaches the detectors. Reflected signals from superficial tissues (skin, subcutaneous fat, muscle) are automatically subtracted, allowing for quantitative lipid content to be determined at a specific depth for accurate chemogram evaluation based on the location of the vessel and the atherosclerotic plaque. The signal is transmitted via optical fibers to the laser spectroscopy analyzer, and a chemogram of lipid distribution in the vessel wall or atherosclerotic plaque is displayed on the ultrasound screen as a chemogram with a quantitative lipid assessment.

Raw NIRS spectra estimate the probability of the presence of an atherosclerotic lipid core, and the measurements are displayed as a chemogram—a digital code map. The chemogram, with a pull-down in millimeters on the x-axis (scan depth) and y-axis (extent), shows the probability of lipid presence in each pixel using 128 color tones that transition from red (indicating low probability) to yellow (indicating high probability). Pixels with insufficient data (e.g., due to shading) are displayed in black. For quantitative assessment, the lipid core load index is determined, defined as the proportion of valid pixels indicating lipids with a probability greater than 0.6 in the scanned area, multiplied by 1000. The lipid core load index can be calculated over the entire length of the vessel scan, in a scan segment, or a specific window within segments (e.g., a 4 mm sliding window with a maximum lipid core load index). In addition, automated backprojection and superimposition of the chemogram onto the B-mode ultrasound image of the vessel with atherosclerotic plaque is performed. This allows for an assessment of the spatial content and distribution of lipids in the vessel wall and atherosclerotic plaque. Oxidized lipid content (wavelength 1650-1750 nm) is separately assessed to assess inflammation in the vessel wall.

The advantage of this utility model is a comprehensive assessment of not only echo signs of arterial damage, but also the quantitative content of lipids in the vessel wall or atherosclerotic plaques; the ability to assess inflammation in the vessel wall by the presence of oxidized lipids; non-invasiveness (the radiation penetration depth of up to 6 cm allows the use of a low-power emitter of 10-20 mW per wavelength (the total power on the skin is less than 50 mW) and does not lead to a significant increase in the temperature of the surrounding tissues); ease of use (NIR spectroscopy photodiodes are built into a conventional linear ultrasound transducer); the possibility of widespread implementation in outpatient, pre-hospital, and hospital settings. A limitation of the method is the impossibility of performing spectroscopy in deep-seated vessels (deeper than 5-6 cm) due to the scattering of infrared radiation. The use of more powerful radiation will lead to an increase in tissue temperature.

The achievement of the technical result in using an ultrasound imaging system for lipid assessment is confirmed by the effective use of similar technology in catheter-based intravascular lipid assessment systems in the coronary and carotid arteries. Existing analogs of multifunctional ultrasound sensors capable of assessing tissue elasticity and stiffness also confirm the feasibility of this technical result. The reliability of the results obtained using the above technologies, confirmed in numerous clinical and experimental studies, suggests the industrial applicability of the proposed device. The proposed non-invasive ultrasound imaging system is compact, convenient, and reliable.

Literature

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Claims (1)

An ultrasonic sensor for an ultrasonic imaging device for assessing the lipid content in a vessel wall, consisting of a housing with a built-in signal generator of various wavelengths, connected by a cable containing a current conductor and optical fibers with a protective coating of Teflon, a damper, a grid of piezoelectric elements, matching layers and an acoustic lens, a generating photodiode located in the side wall of the ultrasonic sensor, and sensor photodiodes located along the longitudinal axis of the ultrasonic sensor at a distance of 2, 4, 6 and 8 cm from the generating photodiode and connected by means of sealed optical fibers.