неинвазивное измерение артериального давления что это такое

Неинвазивные методы исследования динамики артериального давления

Полный текст:

Аннотация

В работе рассматриваются основные методы автоматического неинвазивного измерения артериального давления (АД), применяемые для длительного мониторирования. Обсуждаются преимущества и недостатки дискретного измерения АД по тонам Короткова (ТК) и по осцилляциям в плечевой манжете. В настоящее время АД принято измерять во время дефляции манжеты. При этом давление в ней должно быть поднято на величину порядка 20–30 мм рт. ст. выше систолического. Поскольку величина АД до измерения может быть неизвестна, увеличивается риск поднятия давления в манжете выше оптимального. Поэтому в последнее время предлагаются методы определения АД во время инфляции манжеты. При этом величина АД, определенная как по ТК, так и по осциллометрии, отличается от таковой во время дефляции манжеты. Разница меняется с возрастом и уровнем АД и в ряде случаев оказывается клинически значимой. Обсуждаются причины и следствия таких различий. В отделениях интенсивной терапии и в операционных требуется непрерывное измерение АД. По сравнению с дискретным измерением оно позволяет своевременно выявлять гипотензию, оценивать ее длительность, что способствует улучшению ведения больных. Инвазивный метод определения имеет известные ограничения и осложнения, что стимулировало разработку приборов для неинвазивного контроля. Несмотря на проводимые сравнения их точности с другими методами измерения, этот вопрос продолжает дискутироваться. Рассмотренным в настоящем обзоре методам неинвазивного контроля уровня АД свойственны как достоинства, так и ограничения, что определяет необходимость дальнейших исследований в этой области.

Ключевые слова

Об авторах

Иванов Сергей Юрьевич — кандидат медицинских наук, старший научный сотрудник научно-исследовательской лаборатории профилактической кардиологии.

ул. Аккуратова, д. 2, Санкт-Петербург, 197341.

Список литературы

1. Nitzan M, Adar Y, Hoffman E, Shalom E, Engelberg S, Ben-Dov IZ et al. Comparison of systolic blood pressure values obtained by photoplethysmography and by Korotkoff sounds. Sensors. 2013;13(11):14797–14812.

2. Ogedegbe G, Pickering T. Principles and techniques of blood pressure measurement. Cardiology Clinics. 2010;28(4):571–586.

3. Geddes LA, Voelz M, Combs C, Reiner D, Babbs CF. Characterization of the oscillometric method for measuring indirect blood pressure. Ann Biomed Eng. 1982;10(6):271–280.

4. Amoore JN, Vacher E, Murray IC, Mieke S, King ST, Smith FE et al. Effect of the shapes of the oscillometric pulse amplitude envelopes and their characteristic ratios on the differences between auscultatory and oscillometric blood pressure measurements. Blood Press Monit. 2007;12(5):297–305.

5. Yang F, Chen F, Zhu M, Chen A, Zheng D. Significantly reduced blood pressure measurement variability for both normotensive and hypertensive subjects: effect of polynomial curve fitting of oscillometric pulses. BioMed Res Intern. 2017;2017: 5201069, https://doi.org/10.1155/2017/5201069.

6. Рогоза А. Н, Гориева Ш. Б. Возможности автоматических осциллометрических приборов при измерении артериального давления у пациентов с фибрилляцией предсердий. Системные гипертензии. 2012;4:40–43 [Rogoza AN, Goriyeva ShB. The capacities of automated oscillometric blood pressure measuring devices in patients with atrial fibrillation. Systemic Hypertension. 2012;4:40–43. In Russian].

7. Тихоненко В. М. Достоинства метода Короткова при мониторировании артериального давления. Вестник аритмологии. 2005;40:36–38 [Tikhonenko VM. Advantages the Korotkoff method in monitoring of arterial pressure. Vestnik Arhythmologii = Arrhythmology Bulletin. 2005;40:36–38. In Russian].

8. Иванов С. Ю., Бондаренко Б. Б. Сравнительная точность измерения артериального давления аускультативным и осциллометрическим методом. Бюллетень ФЦСКЭ. 2011;3:12–20 [Ivanov SY, Bondarenko BB. Comparative accuracy of the blood pressure measurement with auscultatory and oscillographic methods. Bulleten Almazov FHBEC = Bulletin of the Almazov Centre (Translational Medicine). 2011;3:12–20. In Russian].

9. Watanabe N, Bando YK, Kawachi T, Yamakita H, Futatsuyama K, Honda Y et al. Development and validation of a novel cuff-less blood pressure monitoring device. JACC Basic Transl Sci. 2017;2(6):631–642.

10. Sheshadri V, Tiwari AK, Nagappa M, Venkatraghavan L. Accuracy in blood pressure monitoring: The effect of noninvasive blood pressure cuff inflation on intra-arterial blood pressure values. Anesth Essays Res. 2017;11(1):169–173.

11. Sasaki J, Kikuchi Y, Usuda T, Hori S. Validation of inflationary noninvasive blood pressure monitoring in the emergency room. Blood Press Monit. 2015;20(6):325–9.

12. Alpert BS. Validation of the Welch Allyn SureBP (inflation) and StepBP (deflation) algorithms by AAMI standard testing and BHS data analysis. Blood Press Monit. 2011;16(2):96–98.

13. Yamashita A, Irikoma S. Comparison of inflationary non-invasive blood pressure (iNIBP) monitoring technology and conventional deflationary non-invasive blood pressure (dNIBP) measurement in detecting hypotension during cesarean section. JA Clin Rep. 2018;4(1):5. doi:10.1186/s40981-017-0145-y

14. Liu C, Zheng D, Griffiths C, Murray A. Oscillometric waveform difference between cuff inflation and deflation during blood pressure measurement. Computing Cardiol. 2014;41:849– 852.

15. Zheng D, Pan F, Murray A. Effect of mechanical behaviour of the brachial artery on blood pressure measurement during both cuff inflation and cuff deflation. Blood Press Monit. 2013;18 (5):265–271.

16. Fabian V, Havlik J, Dvorak J, Kremen V, Sajgalik P, Bellamy V et al. Differences in mean arterial pressure of young and elderly people measured by oscillometry during inflation and deflation of the arm cuff. Biomed Tech (Berl). 2016;61(6):611–621. doi:10.1515/bmt-2015-0098

17. Vychytil J, Moravec F, Kochova P, Kuncova J, Svıglerova J. Modelling of the mechanical behaviour of porcine carotid artery undergoing inflation-deflation test. Appl Comput Mech. 2010;4: 251–262.

18. Drzewiecki G, Pilla JJ. Noninvasive measurement of the human brachial artery pressure-area relation in collapse and hypertension. Ann Biomed Eng. 1998;26(6):965–974.

19. Bank AJ, Kaiser DR, Rajala S, Cheng A. In vivo human brachial artery elastic mechanics: effects of smooth muscle relaxation. Circulation. 1999;100(1):41–47.

20. Foran TG, Sheahan NF. Compression of the brachial artery in vivo. Physiol Meas. 2004;25(2):553–564.

21. Bassez S, Flaud P, Chauveau M. Modeling of the deformation of flexible tubes using a single law: application to veins of the lower limb in man. J Biomech Eng. 2001;123(1):58–65.

22. Cecelja M, Chowienczyk P. Role of arterial stiffness in cardiovascular disease. JRSM Cardiovasc Dis. 2012;1(4): cvd.2012. 012016. doi:10.1258/cvd.2012.012016

23. Skaug EA, Aspenes ST, Oldervoll L, Mørkedal B, Vatten L, Wisløff U et al. Age and gender differences of endothelial function in 4739 healthy adults: the HUNT3 fitness study. Eur J Prev Cardiol. 2013;20(4):531–540.

24. Frangos JA, Eskin SG, McIntire LV, Ives CL. Flow effects on prostacyclin production by cultured human endothelial cells. Science. 1985;227(4693):1477–1479.

25. Grabowski EF, Jaffe EA, Weksler BB. Prostacyclin production by cultured endothelial cell monolayers exposed to step increases in shear stress. J Lab Clin Med. 1985;105(1):36–43.

26. Yoshizumi M, Kurihara H, Sugiyama T, Takaku F, Yanagisawa M, Masaki T et al. Hemodynamic shear stress stimulates endothelin production by cultured endothelial cells. Biochem Biophys Res Commun. 1989;161(2):859–864.

27. Sun Z. Aging, arterial stiffness, and hypertension. Hypertension. 2015;65(2):252–256.

28. Van Popele NM, Grobbee DE, Bots ML, Asmar R, Topouchian J, Reneman RS et al. Association between arterial stiffness and atherosclerosis: the Rotterdam Study. Stroke. 2001;32 (2):454–460.

29. Scheer B, Perel A, Pfeiffer UJ. Clinical review: complications and risk factors of peripheral arterial catheters used for haemodynamic monitoring in anaesthesia and intensive care medicine. Crit Care. 2002;6(3):199–204. doi:10.1186/cc1489

30. Cannesson M, Pestel G, Ricks C, Hoeft A, Perel A. Hemodynamic monitoring and management in patients undergoing high risk surgery: a survey among North American and European anesthesiologists. Crit Care. 2011;15(4): R197. doi:10.1186/cc10364

31. Peňáz J. Photoelectric measurement of blood pressure, volume and flow in the finger. Digest of the 10th International Conference on Medical and Biological Engineering. Dresden. 1973. 104 p.

32. Lakhal K, Martin M, Faiz S, Ehrmann S, Blanloeil Y, Asehnoune K et al. The CNAP finger cuff for noninvasive beat-tobeat monitoring of arterial blood pressure: an evaluation in intensive care unit patients and a comparison with 2 intermittent devices. Anesth Analg. 2016;123(5):1126–1135.

33. Kemmotsu O, Ueda M, Otsuka H, Yamamura T, Winter DC, Eckerle JS. Arterial tonometry for noninvasive, continuous blood pressure monitoring during anesthesia. Anesthesiology. 1991;75 (2):333–340.

34. Hansen S, Staber M. Oscillometric blood pressure measurement used for calibration of the arterial tonometry method contributes significantly to error. Eur J Anaesthesiol. 2006;23 (9):781–787.

35. Walsh M, Kurz A, Turan A, Rodseth RN, Cywinski J, Thabane L et al. Relationship between intraoperative mean arterial pressure and clinical outcomes after noncardiac surgery. Anesthesiology. 2013;119(3):507–515.

36. Salmasi V, Maheshwari K, Yang D, Mascha EJ, Singh A, Sessler DI et al. Relationship between intraoperative hypotension, defined by either reduction from baseline or absolute thresholds, and acute kidney and myocardial injury after noncardiac surgery. Anesthesiology. 2017;126(1):47–65.

37. Sun LY, Wijeysundera DN, Tait GA, Beattie WS. Association of intraoperative hypotension with acute kidney injury after elective noncardiac surgery. Anesthesiology. 2015;123(3):515–523.

38. Bijker JB, Persoon S, Peelen LM, Moons KG, Kalkman CJ, Kappelle LJ et al. Intraoperative hypotension and perioperative ischemic stroke after general surgery: a nested casecontrol study. Anesthesiology. 2012;116(3):658–664.

39. Monk TG, Saini V, Weldon BC, Sigl JC. Anesthetic management and one-year mortality after noncardiac surgery. Anesth Analg. 2005;100(1):4–10.

40. Tassoudis V, Vretzakis G, Petsiti A, Stamatiou G, Bouzia K, Melekos M et al. Impact of intraoperative hypotension on hospital stay in major abdominal surgery. J Anesth. 2011;25(4):492–499.

41. Schramm C, Baat L, Plaschke K. Continuous noninvasive arterial pressure: assessment in older and high-risk patients under analgesic sedation. Blood Press Monit. 2011;16(6):270–276.

42. Ilies C, Bauer M, Berg P, Rosenberg J, Hedderich J, Bein B et al. Investigation of the agreement of a continuous noninvasive arterial pressure device in comparison with invasive radial artery measurement. Br J Anaesth. 2012;108(2):202–210.

43. Akkermans J, Diepeveen M, Ganzevoort W, van Montfrans GA, Westerhof BE, Wolf H. Continuous non-invasive blood pressure monitoring, a validation study of Nexfin in a pregnant population. Hypertens Pregnancy. 2009;28(2):230–242.

44. Eeftinck Schattenkerk DW, van Lieshout JJ, van den Meiracker AH, Wesseling KR, Blanc S, Wieling W et al. Nexfin noninvasive continuous blood pressure validated against RivaRocci/Korotkoff. Am J Hypertens. 2009;22(4):378–383.

45. Chen G, Chung E, Meng L, Alexander B, Vu T, Rinehart J et al. Impact of non invasive and beat-to-beat arterial pressure monitoring on intraoperative hemodynamic management. J Clin Monit Comput. 2012;26(2):133–140.

46. Benes J, Simanova A, Tovarnicka T, Sevcikova S, Kletecka J, Zatloukal J et al. Continuous non-invasive monitoring improves blood pressure stability in upright position: randomized controlled trial. J Clin Monit Comput. 2015;29(1):11–17.

47. Hahn R, Rinösl H, Neuner M, Kettner SC. Clinical validation of a continuous non-invasive haemodynamic monitor (CNAP™; 500) during general anaesthesia. Br J Anaesth. 2012;108(4):581–585.

48. Biais M, Vidil L, Roullet S, Masson F, Quinart A, Revel P et al. Continuous non-invasive arterial pressure measurement: evaluation of CNAP device during vascular surgery. Ann Fr Anesth Reanim. 2010;29(7–8):530–535.

49. McCarthy T, Telec N, Dennis A, Griffiths J, Buettner A. Ability of non-invasive intermittent blood pressure monitoring and a continuous non-invasive arterial pressure monitor (CNAP™) to provide new readings in each 1-min interval during elective caesarean section under spinal anaesthesia. Anaesthesia. 2012;67 (3):274–279.

50. Eckert S, Horstkotte D. Comparison of Portapres noninvasive blood pressure measurement in the finger with intra-aortic pressure measurement during incremental bicycle exercise. Blood Press Monit. 2002;7(3):179–183.

51. Kim SH, Lilot M, Sidhu KS, Rinehart J, Yu Z, Canales C et al. Accuracy and precision of continuous noninvasive arterial pressure monitoring compared with invasive arterial pressure: a systematic review and meta-analysis. Anesthesiology. 2014;120 (5):1080–1097.

52. Fortin J, Lerche K, Flot-zinger D, O’Brien T. Is the standard supplied by the Association for the Advancement of Medical Instrumentation the measure of all things for noninvasive continuous hemodynamic devices? Anesthesiology. 2015;122 (1):208–209.

Для цитирования:

Иванов С.Ю., Бондаренко Б.Б. Неинвазивные методы исследования динамики артериального давления. Артериальная гипертензия. 2018;24(6):637-645. https://doi.org/10.18705/1607-419X-2018-24-6-637-645

For citation:

Ivanov S.Yu., Bondarenko B.B. Non-invasive methods for studying the dynamics of blood pressure. «Arterial’naya Gipertenziya» («Arterial Hypertension»). 2018;24(6):637-645. (In Russ.) https://doi.org/10.18705/1607-419X-2018-24-6-637-645

Источник

Неинвазивные методы исследования динамики артериального давления

Полный текст:

Аннотация

В работе рассматриваются основные методы автоматического неинвазивного измерения артериального давления (АД), применяемые для длительного мониторирования. Обсуждаются преимущества и недостатки дискретного измерения АД по тонам Короткова (ТК) и по осцилляциям в плечевой манжете. В настоящее время АД принято измерять во время дефляции манжеты. При этом давление в ней должно быть поднято на величину порядка 20–30 мм рт. ст. выше систолического. Поскольку величина АД до измерения может быть неизвестна, увеличивается риск поднятия давления в манжете выше оптимального. Поэтому в последнее время предлагаются методы определения АД во время инфляции манжеты. При этом величина АД, определенная как по ТК, так и по осциллометрии, отличается от таковой во время дефляции манжеты. Разница меняется с возрастом и уровнем АД и в ряде случаев оказывается клинически значимой. Обсуждаются причины и следствия таких различий. В отделениях интенсивной терапии и в операционных требуется непрерывное измерение АД. По сравнению с дискретным измерением оно позволяет своевременно выявлять гипотензию, оценивать ее длительность, что способствует улучшению ведения больных. Инвазивный метод определения имеет известные ограничения и осложнения, что стимулировало разработку приборов для неинвазивного контроля. Несмотря на проводимые сравнения их точности с другими методами измерения, этот вопрос продолжает дискутироваться. Рассмотренным в настоящем обзоре методам неинвазивного контроля уровня АД свойственны как достоинства, так и ограничения, что определяет необходимость дальнейших исследований в этой области.

Ключевые слова

Об авторах

Иванов Сергей Юрьевич — кандидат медицинских наук, старший научный сотрудник научно-исследовательской лаборатории профилактической кардиологии.

ул. Аккуратова, д. 2, Санкт-Петербург, 197341.

Список литературы

1. Nitzan M, Adar Y, Hoffman E, Shalom E, Engelberg S, Ben-Dov IZ et al. Comparison of systolic blood pressure values obtained by photoplethysmography and by Korotkoff sounds. Sensors. 2013;13(11):14797–14812.

2. Ogedegbe G, Pickering T. Principles and techniques of blood pressure measurement. Cardiology Clinics. 2010;28(4):571–586.

3. Geddes LA, Voelz M, Combs C, Reiner D, Babbs CF. Characterization of the oscillometric method for measuring indirect blood pressure. Ann Biomed Eng. 1982;10(6):271–280.

4. Amoore JN, Vacher E, Murray IC, Mieke S, King ST, Smith FE et al. Effect of the shapes of the oscillometric pulse amplitude envelopes and their characteristic ratios on the differences between auscultatory and oscillometric blood pressure measurements. Blood Press Monit. 2007;12(5):297–305.

5. Yang F, Chen F, Zhu M, Chen A, Zheng D. Significantly reduced blood pressure measurement variability for both normotensive and hypertensive subjects: effect of polynomial curve fitting of oscillometric pulses. BioMed Res Intern. 2017;2017: 5201069, https://doi.org/10.1155/2017/5201069.

6. Рогоза А. Н, Гориева Ш. Б. Возможности автоматических осциллометрических приборов при измерении артериального давления у пациентов с фибрилляцией предсердий. Системные гипертензии. 2012;4:40–43 [Rogoza AN, Goriyeva ShB. The capacities of automated oscillometric blood pressure measuring devices in patients with atrial fibrillation. Systemic Hypertension. 2012;4:40–43. In Russian].

7. Тихоненко В. М. Достоинства метода Короткова при мониторировании артериального давления. Вестник аритмологии. 2005;40:36–38 [Tikhonenko VM. Advantages the Korotkoff method in monitoring of arterial pressure. Vestnik Arhythmologii = Arrhythmology Bulletin. 2005;40:36–38. In Russian].

8. Иванов С. Ю., Бондаренко Б. Б. Сравнительная точность измерения артериального давления аускультативным и осциллометрическим методом. Бюллетень ФЦСКЭ. 2011;3:12–20 [Ivanov SY, Bondarenko BB. Comparative accuracy of the blood pressure measurement with auscultatory and oscillographic methods. Bulleten Almazov FHBEC = Bulletin of the Almazov Centre (Translational Medicine). 2011;3:12–20. In Russian].

9. Watanabe N, Bando YK, Kawachi T, Yamakita H, Futatsuyama K, Honda Y et al. Development and validation of a novel cuff-less blood pressure monitoring device. JACC Basic Transl Sci. 2017;2(6):631–642.

10. Sheshadri V, Tiwari AK, Nagappa M, Venkatraghavan L. Accuracy in blood pressure monitoring: The effect of noninvasive blood pressure cuff inflation on intra-arterial blood pressure values. Anesth Essays Res. 2017;11(1):169–173.

11. Sasaki J, Kikuchi Y, Usuda T, Hori S. Validation of inflationary noninvasive blood pressure monitoring in the emergency room. Blood Press Monit. 2015;20(6):325–9.

12. Alpert BS. Validation of the Welch Allyn SureBP (inflation) and StepBP (deflation) algorithms by AAMI standard testing and BHS data analysis. Blood Press Monit. 2011;16(2):96–98.

13. Yamashita A, Irikoma S. Comparison of inflationary non-invasive blood pressure (iNIBP) monitoring technology and conventional deflationary non-invasive blood pressure (dNIBP) measurement in detecting hypotension during cesarean section. JA Clin Rep. 2018;4(1):5. doi:10.1186/s40981-017-0145-y

14. Liu C, Zheng D, Griffiths C, Murray A. Oscillometric waveform difference between cuff inflation and deflation during blood pressure measurement. Computing Cardiol. 2014;41:849– 852.

15. Zheng D, Pan F, Murray A. Effect of mechanical behaviour of the brachial artery on blood pressure measurement during both cuff inflation and cuff deflation. Blood Press Monit. 2013;18 (5):265–271.

16. Fabian V, Havlik J, Dvorak J, Kremen V, Sajgalik P, Bellamy V et al. Differences in mean arterial pressure of young and elderly people measured by oscillometry during inflation and deflation of the arm cuff. Biomed Tech (Berl). 2016;61(6):611–621. doi:10.1515/bmt-2015-0098

17. Vychytil J, Moravec F, Kochova P, Kuncova J, Svıglerova J. Modelling of the mechanical behaviour of porcine carotid artery undergoing inflation-deflation test. Appl Comput Mech. 2010;4: 251–262.

18. Drzewiecki G, Pilla JJ. Noninvasive measurement of the human brachial artery pressure-area relation in collapse and hypertension. Ann Biomed Eng. 1998;26(6):965–974.

19. Bank AJ, Kaiser DR, Rajala S, Cheng A. In vivo human brachial artery elastic mechanics: effects of smooth muscle relaxation. Circulation. 1999;100(1):41–47.

20. Foran TG, Sheahan NF. Compression of the brachial artery in vivo. Physiol Meas. 2004;25(2):553–564.

21. Bassez S, Flaud P, Chauveau M. Modeling of the deformation of flexible tubes using a single law: application to veins of the lower limb in man. J Biomech Eng. 2001;123(1):58–65.

22. Cecelja M, Chowienczyk P. Role of arterial stiffness in cardiovascular disease. JRSM Cardiovasc Dis. 2012;1(4): cvd.2012. 012016. doi:10.1258/cvd.2012.012016

23. Skaug EA, Aspenes ST, Oldervoll L, Mørkedal B, Vatten L, Wisløff U et al. Age and gender differences of endothelial function in 4739 healthy adults: the HUNT3 fitness study. Eur J Prev Cardiol. 2013;20(4):531–540.

24. Frangos JA, Eskin SG, McIntire LV, Ives CL. Flow effects on prostacyclin production by cultured human endothelial cells. Science. 1985;227(4693):1477–1479.

25. Grabowski EF, Jaffe EA, Weksler BB. Prostacyclin production by cultured endothelial cell monolayers exposed to step increases in shear stress. J Lab Clin Med. 1985;105(1):36–43.

26. Yoshizumi M, Kurihara H, Sugiyama T, Takaku F, Yanagisawa M, Masaki T et al. Hemodynamic shear stress stimulates endothelin production by cultured endothelial cells. Biochem Biophys Res Commun. 1989;161(2):859–864.

27. Sun Z. Aging, arterial stiffness, and hypertension. Hypertension. 2015;65(2):252–256.

28. Van Popele NM, Grobbee DE, Bots ML, Asmar R, Topouchian J, Reneman RS et al. Association between arterial stiffness and atherosclerosis: the Rotterdam Study. Stroke. 2001;32 (2):454–460.

29. Scheer B, Perel A, Pfeiffer UJ. Clinical review: complications and risk factors of peripheral arterial catheters used for haemodynamic monitoring in anaesthesia and intensive care medicine. Crit Care. 2002;6(3):199–204. doi:10.1186/cc1489

30. Cannesson M, Pestel G, Ricks C, Hoeft A, Perel A. Hemodynamic monitoring and management in patients undergoing high risk surgery: a survey among North American and European anesthesiologists. Crit Care. 2011;15(4): R197. doi:10.1186/cc10364

31. Peňáz J. Photoelectric measurement of blood pressure, volume and flow in the finger. Digest of the 10th International Conference on Medical and Biological Engineering. Dresden. 1973. 104 p.

32. Lakhal K, Martin M, Faiz S, Ehrmann S, Blanloeil Y, Asehnoune K et al. The CNAP finger cuff for noninvasive beat-tobeat monitoring of arterial blood pressure: an evaluation in intensive care unit patients and a comparison with 2 intermittent devices. Anesth Analg. 2016;123(5):1126–1135.

33. Kemmotsu O, Ueda M, Otsuka H, Yamamura T, Winter DC, Eckerle JS. Arterial tonometry for noninvasive, continuous blood pressure monitoring during anesthesia. Anesthesiology. 1991;75 (2):333–340.

34. Hansen S, Staber M. Oscillometric blood pressure measurement used for calibration of the arterial tonometry method contributes significantly to error. Eur J Anaesthesiol. 2006;23 (9):781–787.

35. Walsh M, Kurz A, Turan A, Rodseth RN, Cywinski J, Thabane L et al. Relationship between intraoperative mean arterial pressure and clinical outcomes after noncardiac surgery. Anesthesiology. 2013;119(3):507–515.

36. Salmasi V, Maheshwari K, Yang D, Mascha EJ, Singh A, Sessler DI et al. Relationship between intraoperative hypotension, defined by either reduction from baseline or absolute thresholds, and acute kidney and myocardial injury after noncardiac surgery. Anesthesiology. 2017;126(1):47–65.

37. Sun LY, Wijeysundera DN, Tait GA, Beattie WS. Association of intraoperative hypotension with acute kidney injury after elective noncardiac surgery. Anesthesiology. 2015;123(3):515–523.

38. Bijker JB, Persoon S, Peelen LM, Moons KG, Kalkman CJ, Kappelle LJ et al. Intraoperative hypotension and perioperative ischemic stroke after general surgery: a nested casecontrol study. Anesthesiology. 2012;116(3):658–664.

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Для цитирования:

Иванов С.Ю., Бондаренко Б.Б. Неинвазивные методы исследования динамики артериального давления. Артериальная гипертензия. 2018;24(6):637-645. https://doi.org/10.18705/1607-419X-2018-24-6-637-645

For citation:

Ivanov S.Yu., Bondarenko B.B. Non-invasive methods for studying the dynamics of blood pressure. «Arterial’naya Gipertenziya» («Arterial Hypertension»). 2018;24(6):637-645. (In Russ.) https://doi.org/10.18705/1607-419X-2018-24-6-637-645

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