Английская Википедия:History of continuous noninvasive arterial pressure

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Шаблон:Main The article reviews the evolution of continuous noninvasive arterial pressure measurement (CNAP). The historical gap between ease of use, but intermittent upper arm instruments and bulky, but continuous “pulse writers” (sphygmographs) is discussed starting with the first efforts to measure pulse, published by Jules Harrison in 1835. Such sphygmographs led a shadowy existence in the past, while Riva Rocci's upper arm blood pressure measurement started its triumphant success over 100 years ago. In recent times, CNAP measurement introduced by Jan Penáz in 1973 enabled the first recording of noninvasive beat-to-beat blood pressure resulting in marketed products such as the Finapres™ device and its successors. Recently, a novel method for CNAP monitoring has been designed for patient monitoring in perioperative, critical and emergency care, where blood pressure needs to be measured repeatedly or even continuously to facilitate the best care for patients.

Early sphygmographs

Prior to quantitative measurement, which was applied in medicine in the 19th century, diagnostic possibilities of hemodynamic activities had been limited to qualitative sensing of pulse through palpation. In some cultures, sensitive palpation is still a main part of medicine like pulse diagnosis in Traditional Chinese medicine (TCM) or the identification of the ayurvedic doshas. The introduction of the stethoscope and the methods of auscultation by René-Théophile-Hyacinthe Laennec in 1816 changed the medical behavior consistently and forced the need of quantitative hemodynamic measurements.[1]

The first instrument which could measure the force of pulse with a mercury filled glass tube was developed by Jules Harrison in 1835.[2] Jean Léonard Marie Poiseuille invented the first mercury “Hemodynameter”, a forerunner of the sphygmomanometer in 1821.[3]

The first sphygmograph (pulse writer) for the continuous graphical registration of pulse dates back to Karl von Vierordt in 1854.[4] More popular, however, was the improved sphygmograph from the French physiologist and pioneer in cinematography Étienne-Jules Marey (1863).[5] In his famous book “La méthode graphique“ (1878) and his studies with the photographic gun, Marey's work was related to cardiovascular movements of heart and vessels.[6]

Файл:Marey Sphygmograph.jpg
Marey's sphygmograph – note the registration unit at the top right, where one can see the blood pressure waveforms obtained from the set of levers at the wrist

Besides Marey's sphygmograph, a device developed by the Austrian Samuel von Basch attracted attention and was introduced in Europe in 1880 . A fluid filled bladder placed on the wrist was able to detect pulse; the pressure, which was necessary for the disappearance of the pulses, was measured with a mercury manometer. This allowed the first measurement of systolic blood pressure.[7] Several other sphygmographs were developed in the late 19th century, especially in Great Britain, France and Germany.[8][9][10] These instruments were portable, reasonably accurate and widely available, so physicians even used them at the bedside.

Simple and accurate sphygmomanometers displace sphygmographs

In 1896, the Italian Scipione Riva-Rocci introduced the first mercury-sphygmomanometer placed on the upper arm.[11] It enabled the measurement of absolute systolic blood pressure. Since the finding of the characteristic sounds by the Russian Nikolai Sergejev Korotkoff in 1905, the upper arm method also allows the registration of absolute diastolic blood pressure.[12]

One year after Riva-Rocci's findings, Leonard Erskine Hill and Harold Barnard reported blood pressure monitoring during anesthesia for the first time.[13] Their almost concurrently invented devices consisted of a narrow armlet to occlude the brachial artery, a small bicycle-type metal pump and a metal manometer graduated in mmHg.[14] It seems surprising that the first report of blood pressure monitoring during anesthesia did not mention the use of sphygmographs, which had already been in common use at this time . One reason might be that the former practice totally relied on the observation of breathing as the sole method of monitoring; even the palpation of pulse during ether or chloroform administration was not recognized as a good practice. Another reason may be found directly in the title of the report: “A simple and accurate form of sphygmometer or arterial pressure gauge contrived for clinical use” – implying that for clinical use the device must be simple and accurate.Шаблон:Citation needed

Early vascular unloading technique

While the sphygmomanometer had started its triumphant advance, only a few pulse registration devices were invented in the 20th century. Plain plethysmographic devices like pulse oximeters are, of course, the exception, but they cannot be used for blood pressure measurement. If at all, they can measure blood volume changes. These volume changes cannot easily be transformed into pressure, because the elastic components of the arterial wall are not linear and the smooth muscles also consist of non-elastic parts.. Шаблон:Citation needed

The goal is to unload the arterial wall in order to linearize this phenomenon with a counter pressure as high as the pressure inside the artery. Blood volume is kept constant by applying this corresponding pressure from the outside. The continuously changing outside pressure that is needed to keep the arterial blood volume constant directly corresponds to the arterial pressure. It is an instantaneous, continuous measure for arterial blood pressure, which is the basic principle of the so-called “vascular unloading technique”.Шаблон:Citation needed

In 1942, the German physiologist Richard Wagner introduced a mechanical system for the identification of blood pressure at the arteria radialis using a mechanical version of the vascular unloading technique, where a counter pressure unloads the arterial wall.[15]

Electro-pneumatic vascular unloading technique

The Czech physiologist Jan Peňáz introduced the vascular unloading technique on the finger in 1973 by means of an electro-pneumatic control loop. The control loop is shown in the block diagram: a cuff is placed over the finger, as it is the most suitable and an easily accessible region. Inside the cuff, the blood volume in the finger arteries is measured using an infrared light source (L) and a light detecting photocell (PC). The plethysmographic signal (PG) – the light signal compared to constant C1 – is an electronic measure for finger blood volume. PG is fed into a control unit having proportional-integral-differential characteristics (PID). The PID-signal is added to a constant set point (C2), amplified and fed to an electro-pneumatic transducer (EPT). EPT produces a pressure in the cuff, which, again, alters finger blood volume.[16]

Файл:Penaz principle.jpg
Block diagram of Peňáz’ system with single control loop: F – finger, L – lamp, PC – photo cell, S – segments of transparent pressure cuff, C1 – average of PC-signal, DA – difference amplifier, V(PG) – plethysmographic signal, PID – correcting network, C2 – set point SP, SW – switch between open and closed loop, PA – power amplifier, EPT – electro-pneumatic transducer, M(CP) Pressure measured with Manometer. (Constructed with respect to Peňáz’ original drawing).[16]

The condition of the control loop can be described as follows: The light-signal PG shall become zero by controlling the alterable pressure in the cuff. During systole, when blood volume increases in the finger, the PID-controller increases the control point. Thus, cuff pressure is increased until the excess blood volume is squeezed out. On the other hand, during diastole, the blood volume in the finger is decreased; as a result the PID-controller decreases the control point. Hence, cuff pressure is lowered and the overall blood volume remains constant. As blood volume and thus PG is held constant over time, the pressure difference between cuff pressure and intra-arterial pressure is zero. Intra-arterial pressure is equal to cuff pressure, which can easily be measured by means of the manometer M. Шаблон:Citation needed

Peňáz used a single electronic control loop, which was responsible for the fast tracking of blood pressure changes as well as for the stability of the system. However, the changes in arterial diameter and in wall tension due to vasoconstriction and vasodilatation make a long-term measurement with this single control loop almost impossible, since the true unloading of the arterial wall is easily lost [17] Therefore, groups in the Netherlands,[18][19][20][21][22] Japan,[23][24][25][26][27][28][29] Australia[30] and Austria[31][32][33] have improved the Peňáz principle of vascular unloading.

Finapres and its successors

An innovative evolution of Peňáz’ principle was the Finapres™, which was developed by the Dutch group around K.H. Wesseling and introduced to the market in 1986.[34] Successors of the Finapres systems on the medical market are the Finometer, the Portapres as well as the Nexfin.Шаблон:Citation needed

Digital CNAP-technology

Starting in 1996, an Austrian research group has developed a completely digital approach of the method. As a result, this technology can be found in the Task Force Monitor and CNAP Monitor 500 (CNSystems) as well as in the CNAP Smart Pod (Dräger Medical) and in the LiDCOrapid (LiDCO Ltd.).[33]

Whereas other technologies still use one single control loop, the digital CNAP-technology is based on concentrically interlocking control loops. These loops enable beat-to-beat correction of changes in vasomotor tone using the VERIFI-algorithm.[33]

Tonometry

Tonometry is the resurrection of the old sphygmograph technology as it again describes a mechanism for the automatic noninvasive palpation on the arteria radialis. In order to obtain a stable blood pressure signal, the tonometric sensor must be protected against movement and other mechanical artifacts.[35][36][37]

Pulse transit time

When the heart ejects stroke volume to the arteries, it takes a certain transit time until the blood volume reaches the periphery. This pulse transit time (PTT) indirectly depends on blood pressure. This circumstance can be used for the noninvasive detection of blood pressure changes.[38]

Pulse Decomposition Analysis

The arterial pressure pulse in the upper body is composed of five constituent pulses: the left ventricular ejection pulse, a reflection of this pulse that is known as the second systolic pulse and that arises from the diameter mismatch between thoracic/abdominal aortas, another reflection of it in the iliac arteries that forms the diastolic pulse, and two more re-reflections that arise between these reflection sites and that can typically only be observed in subjects with low arterial stiffness and long cardiac cycles. Using PDA, the pressure profile of each heart pulse is analyzed for changes in systolic, diastolic, and mean arterial pressure as well as other hemodynamic parameters.[39] PDA systems offer very low coupling pressures to a finger and track blood pressures for long periods. Like tonometers and PTT methods, the measurement can be optionally calibrated with an absolute blood pressure from a reference method. One commercially available PDA method has shown acceptable accuracy compared to an invasive arterial line.[40]

References

Шаблон:Reflist

  1. Eckert S. 100 Jahre Blutdruckmessung nach Riva-Rocci und Korotkoff: Rückblick und Ausblick. Journal für Hypertonie 2006; 10 (3), 7-13.
  2. Harrison J. The Sphygmomanometer, an instrument which renders the action of arteries apparent to the eye with improvement of the instrument and prefatory remarks by the translator. Longman, London, 1835.
  3. Шаблон:Cite journal
  4. Vierordt K. Die Lehre vom Arterienpuls in gesunden und kranken Zuständen gegründet auf eine neue Methode der bildlichen Darstellung des menschlichen Pulses. Vieweg und Sohn, Braunschweig, 1855.
  5. Marey EJ: Recherches sur l’état de la circulation d’après les caractères du pouls fourmis par le nouveau sphygmopraphe. J Physiol homme anim 1869; 3: 241–74.
  6. Marey EJ: La méthode graphique dans les sciences expérimentales et principalement en physiologie et en médecine, Paris (1878). p. 281
  7. Basch von S. Über die Messung des Blutdrucks am Menschen. Zeitschrift für klinische Medizin 1880; 2: 79–96.
  8. Dudgeon RE: The Sphygmograph. London: Bailliere Tindall and Cox 1882
  9. Richardson BW: Standard pulse readings. Asclepiad 1885 ii 194
  10. Potain PCE. Du sphygmomanometre et de measure de la pression arterielle de la homme a Iiètat normal et pathologique. Arch de Physiol 1889 i 556
  11. Riva Rocci S. Un sfigmomanometro nuovo. Gaz Med Torino 1896; 47: 981–96.
  12. Korotkoff NS. K voprosu o metodoach eesldovania krovyanovo davlenia. Imperatoor Vorenno JzV Med Akad 1905; 11: 365–7.
  13. Шаблон:Cite journal
  14. Hill L, Barnard H: A simple and accurate form of sphygmometer or arterial pressure gauge contrived for clinical use. BMJ 1897 ii 904
  15. Wagner R: Methodik und Ergebnisse fortlaufender Blutdruckschreibung am Menschen, Leipzig, Georg Thieme Verlag (1942).
  16. 16,0 16,1 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).
  17. Wesseling, K. H.; Settels, J. J.; van der Hoeven G. M.; Nijboer, J. A.; Butijn, M. W.; Dorlas, J. C.: Effects of peripheral vasoconstriction on the measurement of blood pressure in a finger. Cardiovasc Res. Vol. 19, Issue 3, pp. 139-145, 1985
  18. Molhoek GP, Wesseling KH, Settels JJ, van Vollenhoeven E, Weeda HWH, de Wit B, Arntzenius AC: Evaluation of the Peňáz servo-plethysmo-manometer for the continuous non-invasive measurement of finger blood pressure. Basic Res Cardiol, 79, 598-609 (1984).
  19. Smith NT, Wesseling KH, De Wit B: Evaluation of two prototype devices producing non-invasive, pulsatile, calibrated blood pressure measurement from a finger. J Clin Monit, 1, 17-27 (1985).
  20. Wesseling KH, Settels JJ, De Wit B: The measurement of continuous finger arterial noninvasively in stationary subjects. In: Schmidt TH, Dembroski TM, Blümchen G. eds. Biological and physiological factors in cardiovascular disease. Berlin: Springer Verlag, 355-75 (1986).
  21. Wesseling KH: Finapres, continuous noninvasive finger arterial pressure based on the method of Peňáz. In: W. Meyer-Sabellek, M. Anlauf, R. Gotzen, L. Steinfeld (eds.): Blood pressure measurement. Darmstadt: Steinkopff Verlag, 161-72 (1990).
  22. Wesseling KH: A century of noninvasive arterial pressure measurement: from Marey to Peñáz and Finapres. Homeostasis, 36, 2-3, 50-66 (1995).
  23. Nakagawara M, Yamakoshi K: A portable instrument for non-invasive monitoring of beat-by-beat cardiovascular haemodynamic parameters based on the volume-compensation and electrical-admittance method. Med & Biol Eng & Comput, 38 (1), 17-25 (2000).
  24. Yamakoshi K, Shimazu H, Togawa T: Indirect measurement of instantaneous arterial blood pressure in the human finger by the vascular unloading technique. IEEE Trans Biomed Eng, 27, 3M, 150-5 (1980).
  25. Yamakoshi K, Kamiya A: Noninvasive measurement of arterial blood pressure and elastic properties using photoelectric plethysmography technique. Medical Progress through Technology, 12, 123-43 (1987).
  26. Yamakoshi K: Unconstrained physiological monitoring in daily living for health care., Frontiers Med. Biol. Engng., 10, 3, 239-59 (2000).
  27. Tanaka S, Yamakoshi K: Ambulatory instrument for monitoring indirect beat-to-beat blood pressure in superficial temporal artery using volume-compensation method. Med & Biol Eng & Comput, 34, 441-7 (1996).
  28. Kawarada A, Shimazu H, Ito H, Yamakoshi K: Ambulatory monitoring of indirtect beat-to-beat arterial pressure in human fingers by a volume-compensation method. Med & Biol Eng & Comput, 29, 55-62 (1991).
  29. Shimazu H, Ito H, Kawarada A, Kobayashi H, Hiraiwa A, Yamakoshi K: Vibration technique for indirect measurement of diastolic arterial pressure in human fingers. Med & Biol Eng & Comput, 27, 130-6 (1989).
  30. Kobler H, Cejnar M, Hunyor SN: A continuous non-invasive blood pressure monitor. J Electrical and Electronics Eng Aust – IE Aust & IREE Aust, 11, 2, 102-9 (1991).
  31. Gratze, G., Fortin, J., Holler, A., Grasenick, K., Pfurtscheller, G., Wach, P., Schönegger, J., et al. (1998). A software package for non-invasive, real-time beat-to-beat monitoring of stroke volume, blood pressure, total peripheral resistance and for assessment of autonomic function. Computers in biology and medicine, 28(2), 121–42.
  32. Fortin J, Haitchi G, Bojic A, HabenbacherW, Gruellenberger R, Heller A, et al. Validation and verification of the Task Force Monitor. Results of Clinical Studies for FDA 510 (k) No.: K014063, August 2001.
  33. 33,0 33,1 33,2 Fortin, J., Marte, W., Grüllenberger, R., Hacker, A., Habenbacher, W., Heller, A., Wagner, C., et al. (2006). Continuous non-invasive blood pressure monitoring using concentrically interlocking control loops. Computers in biology and medicine, 36(9), 941–57.
  34. Imholz, B. P., Wieling, W., van Montfrans, G. A., Wesseling, K. H. (1998). Fifteen years experience with finger arterial pressure monitoring: assessment of the technology. Cardiovascular research, 38(3), 605–16.
  35. Шаблон:Cite web
  36. Шаблон:Cite web
  37. Шаблон:Cite web
  38. Шаблон:Cite book
  39. Шаблон:Cite journal
  40. Шаблон:Cite journal