RU2220653C2 - Method and device for detecting medical states in non-invasive way by applying current peripheral arterial tonus control - Google Patents

Abstract

FIELD: medical engineering; medicine. SUBSTANCE: method involves creating static pressure around distal portion of patient finger. Peripheral arterial tonus changes and the volume of changes in distal portion of the finger are detected for determining physiological status or medical state or carrying out their monitoring. The device has finger-fixed transducer like a tube for inserting patient finger usable for applying pressure and adjacent pressure cuff for widening pressure field boundaries. The finger transducer either has signal/converter. EFFECT: simplified noninvasive means for detecting cardiac ischemia as a consequence of coronary artery. 57 cl, 39 dwg

Description

 Description text in facsimile form (see graphic part) and

Claims (60)

1. A method for non-invasive detection of changes in the physiological state of a patient, which consists in monitoring the peripheral arterial tone and judging by a specific change in the physiological state of the patient, the peripheral arterial tone being monitored by measuring changes in at least one of the hemodynamic parameters. 2. The method according to claim 1, characterized in that the physiological state is either myocardial ischemia, or the beginning of the sleep stage with rapid eye movement (REM) or an apnea attack in sleep. 3. The method according to claim 1, characterized in that it further includes the operation of applying pressure to the measurement site from about 30 mm RT. Art. to a value greater than about 10% of the patient’s diastolic pressure, and the indicated pressure is sufficient to prevent the accumulation of venous blood at the indicated measurement location and uncontrolled venous return blood flow at this place, as well as to partially relieve tension in the artery wall, but without blocking them, measurement site when it is at or below the heart level. 4. The method according to claim 1, characterized in that the operation of the current control of changes in peripheral arterial tone provides for the current control of changes in blood flow of the arteries of the skin. 5. The method according to claim 1, characterized in that the operation of monitoring the changes in peripheral arterial tone involves monitoring the changes in blood flow of the arteries of the finger or toe. 6. The method according to claim 1, characterized in that the current control is carried out continuously and / or in real time. 7. A device for detecting changes in the physiological state of a patient, characterized in that it includes a finger sensor for applying to a patient’s finger or foot, designed to measure changes in at least one of the hemodynamic parameters determining peripheral arterial tone, and a processor made with the ability to receive signals from the specified sensor and generate an output signal that reflects changes in peripheral arterial tone in the specified finger to determine the physi logical status or medical condition of the patient. 8. The device according to claim 7, characterized in that the finger sensor includes a membrane for applying pressure sufficient to prevent the accumulation of venous blood in the specified finger and partial unloading of voltage in the wall of the arteries in the specified finger, but without overlapping them. 9. The device according to claim 8, characterized in that said sensor is a sensor for monitoring current changes in blood volume in said finger. 10. The device according to claim 9, characterized in that said finger sensor further comprises a cuff for expanding the field of application of pressure to the finger. 11. The device according to claim 8, characterized in that the finger sensor is configured to monitor peripheral arterial tone continuously and / or in real time. 12. A device for applying pressure to a finger of a patient’s finger or toe during non-invasive detection of changes in the physiological state of a patient, characterized in that it includes a rigid cylindrical shell having an open end and a closed end, a tubular membrane closed at one end and placed inside said shell, and the open end of the membrane is hermetically connected to the open end of the shell, and located so that the chamber formed between the closed end of the shell and the membrane is connected to a pressure source exerting pressure on the membrane and through it onto the finger, and means for preventing the tubular membrane from being pushed out of the cylindrical shell when pressure is applied from the pressure source. 13. A method for non-invasively detecting physiological dysfunction of a patient, characterized in that it involves applying a static pressure field around the distal end of the patient’s finger or foot, including around the distal tip of the finger, the static pressure field being sufficient to prevent mainly venous blood accumulation in the specified distal end, preventing the mainly uncontrolled venous return blood flow in the specified distal end, and partial unloading of tension in the st arteries in the specified distal end, but without overlapping, when the specified distal end is at or below the heart level, and measuring changes in blood volume or other hemodynamic parameter in the specified distal end, accompanying arterial pulse waves. 14. The method according to item 13, wherein the measurement of blood volume or other hemodynamic parameter is carried out by measuring changes in the volume of the specified distal end of the finger. 15. The method according to item 13, wherein the measurement of changes in blood volume or other hemodynamic parameter is carried out by measuring changes in optical density of the specified distal end of the finger. 16. The method according to one of paragraphs.13-15, characterized in that the current control of these changes is performed to detect the existence of myocardial ischemia in a patient. 17. The method according to one of paragraphs.13-15, characterized in that the current control of these changes is performed to detect at least either the onset and duration of the sleep stage with rapid eye movement (REM), or an apnea attack in sleep. 18. The method according to one of paragraphs.13-15, characterized in that the specified field of static pressure lies in the range from 30 mm RT. Art. up to a pressure of approximately 10% higher than the patient’s diastolic pressure. 19. The method according to one of paragraphs.13-15, characterized in that the static pressure field is 70 mm RT. Art. 20. The method according to one of paragraphs.13-15, characterized in that the said field of static pressure is applied around the area proximal to the most extreme fingertip, including the specified tip. 21. The method according to claim 20, characterized in that the specified field of static pressure is applied using the device according to item 12. 22. A device for applying pressure to a finger of a patient’s finger or foot during non-invasive detection of the physiological state of a patient, characterized in that it includes a rigid cylindrical shell having an open end and a closed end, one or more membranes located inside the shell, the open end the membrane is hermetically connected to the open end of the shell, and a chamber is formed between the closed end of the shell and the membrane, which is connected to a pressure source that exerts pressure on the membrane and through mbranu - on the finger, while the specified membrane and the specified membrane form a cap that is worn on the patient’s finger, and the specified cap has a shape that provides pressure on the opposite sides of the distal part of the specified finger, to prevent the accumulation of venous blood in the specified finger, to prevent the expulsion of the specified a tubular membrane from the specified cap when applying pressure from the pressure source and to prevent displacement of the specified shell relative to the finger adjacent to the decree constant envelope in the form of an annular collar with a cylindrical sleeve secured to the elastic membrane, wherein said membrane and the inner wall of said sleeve to form a cavity associated with the pressure source for pressing the membrane to a finger to expand the application of pressure to the finger field. 23. The device according to p. 22, characterized in that it further comprises a heating mechanism. 24. The device according to item 23, wherein the device further comprises a vertical displacement sensor of the device relative to the heart. 25. The device according to item 22, wherein the specified membrane is divided into two sections at two diametrically opposite sides of the finger. 26. The device according to item 22, wherein said cap is divided into many sections, each of which has a membrane section combined with it, and the specified many shell sections are connected together to form the specified cap. 27. The device according to p. 26, characterized in that the means of preventing the ejection of the specified membrane is a restrictive rib attached to the shell and having a middle section inserted inside the tubular membrane, so as to limit the internal axial displacement of the membrane. 28. A device for applying pressure to a finger of a patient’s finger or foot during non-invasive detection of changes in the physiological state of a patient, characterized in that it includes a rigid shell having an open end and a closed end, an elastic membrane located inside the shell and hermetically connected to the open end said shell, an annular pressure applying tape provided inside said shell and arranged to clamp said membrane to the inner wall of said bolochki, U-shaped restrictive rib provided inside said casing, with pressing to said membrane so as to prevent axial displacement of the membrane to prevent ejection finger placed therein. 29. The device according to p. 28, characterized in that said pressure application tape divides the membrane into two sealed pressure application chambers. 30. A device for detecting changes in the physiological state of the patient, including a means of applying pressure, which includes a tubular socket for input into it at a predetermined length of the distal end of the patient’s finger or foot, including the distal tip of the finger, a pressure source for applying a static pressure field around the distal end of the finger, including the most distal tip of the patient’s finger or foot, when it is inserted into the specified tubular socket, and a measuring device for measuring ia changes in blood volume or other hemodynamic parameter in the specified distal end of the finger. 31. The device according to p. 30, characterized in that the said measuring device is configured to measure changes in the volume of the specified distal end of the finger associated with waves of blood pressure. 32. The device according to p. 30, characterized in that the said measuring device is configured to measure changes in optical density at the specified distal end of the finger associated with waves of blood pressure. 33. The device according to one of paragraphs.30-32, characterized in that the said means of applying pressure is configured to apply static pressure around the distal end of the finger, and this field is elongated in the proximal direction towards the patient’s heart at a certain distance from the place, in which carry out the measurement of these changes. 34. The device according to one of paragraphs.30-32, characterized in that said means of applying pressure includes a shell with a deformable tubular membrane installed therein defining the tubular chamber in said shell, and a pressure source for applying it to said tubular chamber for creating deformations of the tubular membrane in accordance with changes in the volume of blood flow through the patient’s finger inserted into it, said deformable tubular membrane being divided into several sections. 35. The device according to clause 34, wherein said deformable tubular membrane is divided into two sections at diametrically opposite sides of the patient’s finger inserted into it. 36. The device according to clause 34, wherein said shell is divided into many sections, one for each of the sections of the membrane, combined together to form the specified external tubular chamber together with these sections of the membrane. 37. The device according to clause 34, wherein the specified tubular membrane is divided into many sections using a restrictive rib attached to the shell and having a middle section inserted inside the tubular membrane, so as to limit the displacement inward of the outer periphery of each section of the membrane during application pressure to the specified tubular chamber. 38. The device according to p. 30, characterized in that the pressure applied by the specified pressure source is in the range from 30 mm RT. Art. up to approximately 70 mm RT. Art. 39. The device according to p. 30, characterized in that the pressure applied by the specified means of applying pressure is 70 mm RT. Art. 40. The device according to p. 30, characterized in that it further includes a Converter for converting these measured changes in the specified end of the finger into the arterial blood pressure of the patient. 41. The device according to p, characterized in that the transducer includes a measuring device for measuring hydrostatic pressure added to the blood pressure of the patient by vertical movement of the patient’s finger in each of the many vertical positions relative to the patient’s heart level, and a computing device using the specified static pressure field and the measured hydrostatic pressure to calibrate the measured changes at the end of the patient’s finger in arterial blood values patient pressure and for converting said measured changes to arterial blood pressure. 42. The device according to p, characterized in that it further includes a heater for preheating the patient’s finger to a predetermined temperature to maximize the expansion of arterial blood vessels in the finger. 43. The device according to p. 30, characterized in that the pressure source is integrated into at least one finger of the glove worn by the patient and designed to measure changes in the distal end of the patient’s finger inserted into the glove finger. 44. A device for monitoring the hemodynamic state of a patient, characterized in that it includes a tubular socket for inputting the distal end of the patient’s finger, a heater in said socket for heating the distal end of the patient’s finger to a predetermined temperature to maximize the arterial blood vessels in the specified finger and a measuring device for measuring changes in blood volume or other hemodynamic parameter at the distal end of the finger, accompanying the waves of blood pressure. 45. The device according to item 44, wherein the specified socket further includes a means of applying static pressure around the distal end of the finger, sufficient to prevent the accumulation of venous blood and to partially unload the voltage in the wall of the arteries of the finger, but without overlapping them when the finger is at heart level. 46. The device according to one of p. 44 or 45, characterized in that the said measuring device is configured to measure changes in the volume of the specified distal part of the finger accompanying the waves of blood pressure. 47. The device according to one of p. 44 or 45, characterized in that the said measuring device is configured to measure changes in optical density in the specified distal part of the finger. 48. A device for detecting cardiopulmonary distress of a patient, characterized in that it includes a means for applying pressure, which includes a tubular socket for insertion into it at a predetermined length of the distal end of the patient’s finger or foot, including the distal tip of the finger , a pressure source for applying a static pressure field around the distal ring of the finger when it is inserted into the specified tubular socket, and the specified static pressure field is sufficient to prevent the accumulation of veins heat in the distal end of the finger and to partially relieve tension in the wall of the arteries, but without overlapping them, in the specified finger, when it is at the level of the heart, a measuring device for measuring changes in blood volume or other hemodynamic parameter in the distal end of the finger accompanying blood waves pressure, and an indicator to provide an indication of the existence of cardiopulmonary distress when the indicated measured changes in hemodynamic parameters exceed a predetermined percentage in comparison with the known rmalnoy condition of the patient without the presence of cardiopulmonary distress. 49. A device for monitoring the patient’s sleep state, characterized in that it includes a means of applying pressure, which includes a tubular socket for insertion into it at a predetermined length of the distal end of the patient’s finger or foot, including the distal tip itself finger, a pressure source for applying a static pressure field around the distal end of the finger when it is inserted into the specified tubular socket, and the specified static pressure field is sufficient to prevent, mainly, congestion venous blood in the distal end of the finger and to partially relieve tension in the wall of the arteries, but without overlapping them, in the specified finger, when it is at the level of the heart, a measuring device for measuring changes in blood volume or other hemodynamic parameter in the distal end of the finger associated with waves blood pressure, and an indicator to provide an indication of the patient’s sleep state based on the indicated measured changes in hemodynamic parameters. 50. The device according to one of p. 48 or 49, characterized in that the said measuring device is configured to measure changes in the volume of the specified end of the finger. 51. The device according to one of p. 48 or 49, characterized in that the said measuring device is configured to measure changes in optical density of the indicated end of the finger. 52. The device according to one of p. 48 or 49, characterized in that the pressure applied by the specified means of applying pressure is in the range from 30 mm RT. Art. up to 70 mmHg Art. 53. The device according to one of p. 48 or 49, characterized in that the said means of applying pressure is configured to apply static pressure around the distal end of the finger, and the field of static pressure is expanded towards the patient’s heart by a certain distance from the place at which measuring these changes. 54. The device according to one of p. 48 or 49, characterized in that said pressure application means comprises a shell with a deformable tubular membrane installed therein, defining together with said shell an outer tubular chamber, and an inner tubular socket for introducing a distal end of the finger into it the patient, and the specified pressure source is configured to apply a static pressure field to the specified external tubular chamber to create deformations of the tubular membrane in accordance with changes in volume the volume of the patient’s finger inserted into it, associated with blood pressure waves, wherein the deformable tubular membrane is divided into several sections distributed around the patient’s finger introduced into it, each section having a central region and an outer periphery, with the outer periphery of each section being limited relative to the inward displacement, so that the pressure inside the outer tubular chamber displaces inward the central region of each section of the membrane to a greater extent than its outer periphery for tight pressing the patient’s finger in the device and eliminating the axial and rotational movement of the device relative to the limb of the body when moving inward the central regions of many sections of the membrane. 55. The device according to item 54, wherein the specified deformable tubular membrane is divided into two sections at two diametrically opposite sides of the finger inserted into it. 56. The device according to item 54, wherein the specified shell is divided into many sections, one for each of the sections of the membrane, combined together to form the specified external tubular chamber together with the indicated sections of the membrane, each of the sections of the membrane being a four-sided membrane attached at its peripheral edges to the peripheral edges of its corresponding shell section. 57. The device according to item 54, wherein the specified tubular membrane is divided into many sections using a restrictive rib attached to the shell and having a middle section inserted inside the tubular membrane, so as to limit the displacement inward of the outer periphery of each section of the membrane during application the specified pressure to the specified tubular chamber. Priority on points: 01/30/1997 according to claims 1, 4-6, 11, 16 and 48; 07/30/1996 according to claims 7-10, 12-15, 20-27, 30-36, 40-42, 44-47, 49-51 and 53-57; 05/21/1997 according to claims 2-3, 17-19, 28-29, 37-39, 43, 52.

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