(V.) Signal detection by PowerLab system - instruction
(VII.) Examination of pulse by palpation
Physiology I - practicals
Dep. of Physiology, Fac. of Med., MU, 2015 © Michal Hendrych, Tibor Stračina

Pulse (pulsus)
•Mechanical manifestation of heart activity •Mechanical wave (pulse wave) arises after each
contraction of LV and propagates along the arterial wall
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Ejection phase of systole
(open aortal valve)
Diastole (closed aortal valve)
Aortal valve contracts behind the pressure wave
Aortal wall stretches in forward direction
Pressure (pulse) wave

STK
DTK

https://s-media-cache-ak0.pinimg.com/736x/d7/60/75/d760758ecd74f778e5ab7124646da026.jpg
Palpation of pulse
•Where:
•A. radialis
•A. carotis
•A. femoralis
•A. brachialis
•A. poplitea How:
•A. tibialis posterior
•A. dorsalis pedis
•
http://www.angiologist.com/wp-content/uploads/2011/08/Pulse-palpation.jpg

Palpation of pulse
•Where:
•A. radialis
•A. carotis
•A. femoralis
•A. brachialis
•A. poplitea
•A. tibialis posterior
•A. dorsalis pedis
•
http://docplayer.cz/docs-images/40/13777908/images/page_5.jpg
a. carotis
a. radialis
a. femotalis
a. poplitea
a. tibialis posterior
a. dorsalis pedis
aorta abdominalis
a. brachialis
a. axillaris
a. subclavis
http://www.angiologist.com/wp-content/uploads/2011/08/Pulse-palpation.jpg
How:

Examination of pulse
•Frequency: number of pulses per one minute = pulse rate
•Qualities: regularity, compressibility
•According qualities, we can describe:
•Pulsus regularis
•Pulsus irregularis
•Pulsus celer (Corrigan´s pulse: P. celer, altus, frequens)
•Pulsus tardus
•Pulsus durus – hardly compressible pulse – hypertension
•Pulsus mollis – easily compressible pulse – hypotension
•Pulsus magnus – high amplitude of pulse
•Pulsus parvus – small amplitude of pulse
•Pulsus filiformis – threadlike pulse – circulatory failure
•

Heart rate
•Physiological values: 60 – 100 beats per minute (BPM) at rest
•Tachycardia: increased heart rate (> 100 at rest)
•Bradycardia: decreased heart rate (< 60 at rest)
•Arrhythmia: an abnormality in the heart's rhythm, or heartbeat pattern.
The heartbeat can be too slow, too fast, have extra beats, skip a beat, or otherwise beat
irregularly
•

Heart rate vs. pulse frequency
•Heart rate (HR) is a number of cardiac cycles per minute
•computed from ECG
•Pulse frequency is a number of pulse cycles per minute
•Computed from sphygmography, blood pressure or by palpation of artery
•Usually: heart rate = pulse frequency

Modulation of HR by autonomic nervous system (ANS)
•ANS modulates heart automaticity by modulation of SA node activity
•
•Parasympathetic system – vagus nerve – „nervi retardantes“
•Via M2 receptors
•Negative chronotropic effect
•Decreased tonus of vagus nerve = increased HR
•
•Sympathetic system – sympathetic cardiac nerves – „nervi accelerantes“
•via β1 receptors
•Positive chronotropic effect
•Increased sympathetic activity = increased HR
•Sympathetic and parasympathetic systems are active simultaneously, but in different intensity…
•

Baroreflex
•Short-time control of arterial pressure
•Mean arterial pressure (MAP) is detected by baroreceptors in aortic arch and carotic sinus
•stretch-receptors (mechanoreceptors)
•Afferent fibres: vagus nerve (n. X.) and n. glosopharingeus
•Centre: rostral part of nucleus solitarius in medulla oblongata
•Efferent pathways:
•Cardiac branch: n. vagus (+ SS) – heart rate changes
•Peripheral (vascular) branch: sympathetic vascular innervation – changes of total peripheral
resistance (TPR)
•

File:Baroreflex.jpg
•Mechanism:
↓MAP
↓afferentation from baroreceptors processing
•↓vagus activity and  ↑sympathetic activity
•↑HR and ↑TPR
(MAP = HR * SV * TPR)
•↑MAP
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… and conversely in case of MAP increase
Baroreflex

Respiratory sinus arrhythmia (RSA)
•Changes of heart rate in accordance with breathing: increase of HR during inspirium, decrease of
HR during expirium •The most evident in young people, associated with vagal activity
•RSA disappears with HR increase (stress, exercise, high age)
ECG
BP
respiration
time [s]
Mechanisms of RSA formation:
•Baroreflex: during inspiration – ↓ intrathoracic pressure → ↑venous return (due to ↑ pressure
gradient) → ↑systolic volume → ↑MAP → baroreflex (2 s lag) → ↓HR → ↑ (balance of) MAP
•Central origin: irradiation of respiratory centre to kardiomotoric centre in the medulla oblongata
•Bainbridge reflex: ↑venous return during inspirium – stretch of atria – activation of
stretch-receptors – stimulation of n. vagus – stimulation of SA node
•Local source: mechanical stretch of SA node accelerates its depolarization (weak RSA is presented
in transplanted heart)
•Another reflexes influencing vagal activity, chemoreflex (oscillation of pCO2, pO2, pH)

•↑venous return from lower part of body → ↑heart filling (preload) → ↑SV → ↑BP → baroreflex causes
↓HR and ↓ TPR
•Orthostatic reaction – change of position from lying to standing (sitting):
↓ venous return from lower part of body → ↓ heart filling (preload) → ↓SV → ↓BP → baroreflex causes
↑HR and ↑TPR
•Cardiac branch of baroreflex is faster but less effective in BP maintenance  - HR increases within
1 s after BP decrease, this prevents to brain perfusion decrease
•Peripheral branch of baroreflex is slower but more effective: TPR increases cca 6 s after BP
decrease and stabilize BP → HR decreases during long lasting standing to resting value
http://www.cardiachealth.org/sites/default/files/2011/TiltTable.png
Body posture changes in gravity field cause blood pressure (BP) changes. These changes are
minimized by short-term BP regulation (baroreflex).
•Clinostatic reaction – change of position from standing (sitting) to lying:
Heart rate during body posture changes

Heart rate changes and physical exercise
•Working muscle has higher metabolic demands – perfusion is increased (autoregulation of blood
flow, metabolic vasodilatation)
•Exercise increases tonus of sympaticus („ergotropic system“)
•Anticipation of exercise
•There is compensatory vasoconstriction in those tissues which are not metabolically active (GIT,
reproduction system, excretory system, skin) – s.c. redistribution of blood.
•It affects heart function:
•Vasodilatation in muscles → ↓TPR → ↓BP → baroreflex → ↑HR
•Sympaticus: ↑HR
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•Athletes' heart

Zdroje obrázků
•Slide 6 - https://www.pinterest.com/pin/144537469264742090/ [cited 31.8.2015] •Slide 6 -
http://www.angiologist.com/general-medicine/pulse-palpation-and-pulse-location/ [cited 31.8.2015]
•Slide 12 - http://corposcindosis.wikia.com/wiki/File:Baroreflex.jpg [cited 31.8.2015] •Slide 14 -
http://www.cardiachealth.org/postural-orthostatic-tachycardia-syndrome-pots [cited 31.8.2015]
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