Introduction
Physiologists and cardiologists are keenly aware of heart rate (HR) dependence of physiological indexes used to assess cardiac function. Selected pump-function indexes rely on stroke volume, typically based on systolic ejection, and significant work has been done to analyze the HR dependence of the duration of systole
Physiological versus cardiological systole and diastole
Physiological systole
Cardiological systole
Isovolumic contraction
From M1 to A2, including:
Maximal ejection
Major part of isovolumic contraction*
Maximal ejection
Reduced ejection
Physiological diastole
Cardiological diastole
Reduced ejection
A2 - M1 interval (filling phases included)
Isovolumic relaxation
Filling phases
* Note that M1 occurs with a definite albeit short delay after the start of the LV contraction. Modified from Opie LH. Mechanisms of cardiac contraction and relaxation. In: Braunwald E, Zipes DP, Libby P, Bonow RO, eds. Heart Disease. 7th ed. WB Saunders Company 2005, Chap.19:457–489, page 474.
The mechanical events in the cardiac cycle, first assembled by Lewis in 1920 but first conceived by Wiggers in 1915
The mechanical events in the cardiac cycle, first assembled by Lewis in 1920 but first conceived by Wiggers in 1915. Cycle length of 800 milliseconds for 75 beats/min.
Aims of this study were:
1- To assess the feasibility of demarcate cardiological systole and cardiological diastole through an operator independent cutaneous heart sounds sensor.
2- To assess diastolic time at rest and at every 5 heart beats increase during exercise, dipyridamole or pacing stress in patients scheduled for stress echocardiography.
3- To assess systolic/diastolic time ratio at rest and at every 5 heart beats increase during stress.
4- To assess diastolic flow rate, at rest and at peak stress.
Methods
Patient selection
We enrolled 161 consecutive patients (106 males, 62 ± 13 years) referred for stress echocardiography (115 for exercise, 40 for dipyridamole, 6 for pacing stress). The type of stress was clinically driven for exercise vs. dipyridamole, and by the presence of a permanent pace maker for pacing stress. The characteristics of the study patients are reported in Table
Characteristics of the study patients
EXERCISE
DIP
PACING
Pt n°
115
40
6
Age (years)
57 ± 14
66 ± 11
68 ± 10
Males
78
24
4
Controls
17
-
-
Previous PTCA/By pass
22
14
1
Previous myocardial infarction
24
10
2
Arterial hypertension
49
19
3
COPD
16
1
-
DC
17
1
1
Valvular disease
13
-
-
Atipical chest pain
7
9
3
BB on
39
21
4
ACEi on
32
9
3
Ca CB on
24
11
-
COPD = Chronic Obstructive Pulmonary Disease, DC = Dilated Cardiomyopathy, BB = Beta Blockers, ACEi = Angiotensin Converting Enzyme inhibitors, Ca CB = Calcium Channel Blockers
All patients met the following inclusion criteria: 1) referred to stress echo for clinically driven testing; 2) acoustic window of acceptable quality; 3) willingness to enter the study. Exclusion criteria were: 1) unstable angina or recent myocardial infarction; 2) moderate-to severe aortic stenosis; 3) hemodynamic instability, documentation of life-threatening ventricular arrhythmias (sustained ventricular tachycardia or ventricular fibrillation), atrial fibrillation.
From the initially considered population of 170 patients, 4 were excluded for poor acoustic window, 3 for low quality of the force sensor signal, or refusal to give written informed consent (n = 2).
Stress echocardiography
Semi-supine bicycle exercise
Graded bicycle semi-supine exercise echo was performed in 115 patients starting at an initial workload of 25 watts lasting for 2 minutes; thereafter the workload was increased stepwise by 25 watts at 2 minutes interval. A 12-lead electrocardiogram and blood pressure determination were performed at baseline and every minute thereafter
Dipyridamole stress echo
Dipyridamole stress echo was performed following the protocol of the American Society of Echocardiography
Pacing stress echo
The study population consisted of 6 patients with a permanent Pace Maker. The pacing protocol was accelerated (with a 10-beat increment every 60 s). Stimulation was performed, wherever possible, in atrial stimulation mode, or dual-chamber (DDD) pacing to have normal contraction sequence. In the VVI-implanted patients, ventricular stimulation mode was used
Diagnostic end points and interruption criteria
The diagnostic end-points for all types of stress were: the development of obvious positive echocardiography, obvious alterations of ECG (ST segment shift > 3 mm). The exam was also stopped in case of limiting subjective side effects or hypertension (systolic pressure > 220 mmHg, diastolic pressure > 120 mmHg), hypotension (relative or absolute) with decrease of the blood pressure > 30 mmHg, supraventricular arrhythmias (supraventricular tachycardia, atrial fibrillation), ventricular arrhythmias (ventricular tachycardia, frequent and polymorphous ventricular beats); limiting dyspnoea, or maximal predicted heart rate in the absence of ischemia
Regional wall motion analysis
The Wall Motion Score Index (WMSI) was calculated in each patient at baseline and peak stress, according to the recommendations of the American Society of Echocardiography from 1 = normal-hyperkinetic to 4 = dyskinetic in a 17 segment model of the left ventricle
Blood pressure analysis
One nurse recorded blood pressures both at rest and during each individual study. Blood pressure recording was made using a sphygmomanometer and the diaphragm of a standard stethoscope. Systolic and diastolic blood pressure was obtained on the right arm.
Operator-independent cardiologic systole and diastole quantification
The transcutaneous force sensor is based on a linear accelerometer from STMicroelectronics (LIS3). The device includes in one single package a MEMS sensor that measures a capacitance variation in response to movement or inclination and a factory trimmed interface chip that converts the capacitance variations into analog signal proportional to the motion. The device has a full scale of ± 2·g (g = 9.8 m/s2) with a resolution of 0.0005·g. We housed the device in a small case (Figure
Operator-independent cardiologic systole and diastole quantification
Operator-independent cardiologic systole and diastole quantification. The transcutaneous force sensor is based on a linear accelerometer from STMicroelectronics (LIS3). The device includes in one single package a MEMS sensor that measures a capacitance variation in response to movement or inclination and a factory trimmed interface chip that converts the capacitance variations into analog signal proportional to the motion. The device has a full scale of ± 2·g (g = 9.8 m/s2) with a resolution of 0.0005·g. We housed the device in a small case which was positioned in the mid-sternal precordial region and was fastened by a solid gel ECG electrode. The acceleration signal was converted to digital and recorded by a laptop PC, together with an ECG signal. The system is also provided with a user interface that shows both the acceleration and the ECG signals while the acquisition is in progress. The data were analyzed by using software developed in Matlab (The MathWorks, Inc). An analog peak-to-peak detector synchronized with the standards ECG scans the first 150 ms following the R wave to record first heart sound force vibrations and the 100 ms following the T wave to record second heart sound force vibrations. A stable, reproducible, and consistent first heart sound and second heart sound signal was obtained in all patients and utilized as time markers to continuously assess cardiologic systole and diastole during exercise, dipyridamole and pacing stress echo.
Systolic and diastolic times were acquired continuously at baseline and during stress. The primary outcome was the proportion of the cardiac cycle occupied by systole and diastole (absolute values, msec). Secondary outcomes included the systolic/diastolic ratio. The systolic/diastolic ratio was expressed as a dimensionless ratio (systolic/diastolic). The systolic and diastolic intervals were displayed by plotting time (y axis, msec) vs. heart rate increase during stress (x axis, heart rate, bpm) (Figure
Controls
Controls. The curve of the systolic (pink line) and diastolic (black lines) time variation as a function of heart rate in 3 controls (upper and middle panels males, lower panel female). The parameters are acquired as instantaneous values at baseline and during stress. In normal healthy volunteer subjects performing bicycle exercise, the observed duration of diastole was greater than systole up to 160 beats per minute. The data can be also remotely read by a telemetric connection.
Volume measurements and diastolic mitral filling rate quantification
Because stroke volume varies directly with body size, it was indexed for body surface area (SVi) to better reflect differences with age and between the genders adjusted for differences in body size.
Cardiac index calculation
Cardiac index (SVi × heart rate) was calculated at baseline and peak stress.
Diastolic filling rate
Diastolic filling rate was calculated at rest and at peak stress as mitral filling volume (considered equivalent to the SVi estimated with biplane Simpson method) divided by diastolic time (automatically sensor estimated) × 1,000
Intra- and inter-observer reproducibility
The intra- and inter-observer reproducibility was tested in 20 randomly selected patients at rest and during stress.
Statistical analysis
SPSS 11 for Windows was utilized for statistical analysis. The statistical analyses included descriptive statistics (frequency and percentage of categorical variables and mean and standard deviation of continuous variables). The primary outcome was the proportion of the cardiac cycle occupied by systole and diastole (absolute value, msec). Secondary outcomes included the systolic/diastolic ratio. Repeated-measures analysis of variance (ANOVA) was used to compare data groups. The Scheffé test was used for post hoc comparisons. The correlation between the heart rate and the systolic, diastolic times, and the systolic/diastolic ratio was assessed by error bar charts plotting the standard deviations of individual variables at each 5 beats heart rate increase during stress (exercise, dip or pacing stress). Multiple linear regression analysis was used to analyze the data to allow for multiple parameters, including dependence on HR, subject-to-subject variability, and gender differences. The correlations between the diastolic duration time, the diastolic filling rate and the cardiac index were assessed by regression analysis and scatter plots, both at rest and at peak stress. A two-tailed
Results
Resting and stress echocardiographic findings
Technically adequate images were obtained in all patients at baseline (by selection) and during stress.
At Peak Exercise
Heart rate was lower in the dipyridamole than in the exercise and pacing groups. Regional wall motion abnormalities occurred in 2 patients of the exercise, 1 patient of Dip and 2 patients of the pacing groups. (Table
Rest and stress data
EXERCISE
DIP
PACING
Pt n°
115
40
6
Age (years)
57 ± 14
Δ
66 ± 11
68 ± 10
Gender (M/F)
78/37
24/16
4/2
Standard measurements
HR rest (bpm)
71 ± 14
66 ± 12
71 ± 10
HR peak (bpm)
128 ± 22
Δ
84 ± 14
*
132 ± 13
LV EF % rest
59 ± 12
61 ± 10
51 ± 11
WMSI rest
1.15 ± 0.33
1.10 ± 0.22
1.28 ± 0.46
WMSI peak
1.15 ± 0.34
1.11 ± 0.22
1.42 ± 0.46
SBP rest (mmHg)
132 ± 20
136 ± 22
133 ± 20
SBP peak (mmHg)
188 ± 24
§
130 ± 28
137 ± 37
DBP rest (mmHg)
73 ± 10
71 ± 13
74 ± 11
DBP peak (mmHg)
93 ± 12
§
68 ± 14
75 ± 15
Sensor recorded times
Systolic time rest (msec)
315 ± 45
Δ
348 ± 36
315 ± 53
Systolic time peak (mesc)
236 ± 40
Δ
338 ± 43
*
249 ± 38
Diastolic time rest (msec)
541 ± 143
Δ
651 ± 146
600 ± 108
Diastolic time peak (msec)
250 ± 59
Δ
387 ± 98
*
211 ± 48
Systolic/diastolic time rest (ratio)
0.61 ± 0.14
0.56 ± 0.11
0.53 ± 0.08
Systolic/diastolic time peak (ratio)
0.98 ± 0.21
Δ
0.92 ± 0.20
*
1.25 ± 0.39
§= significant differences between exercise and both dipyridamole and pacing stress pts; * = significant differences between dipyridamole and pacing stress pts; Δ = significant differences between exercise and dipyridamole stress pts.
Despite similar baseline values, diastolic blood pressure increased in the exercise, decreased in the dipyridamole, while unchanged in the pacing group; although the response was heterogeneous at the individual level. (Table
Sensor diastolic and systolic times monitoring at increasing heart rates
A consistent first heart sound and second heart sound signal was obtained in 161 out of 164 patients at rest and during stress. In 3 patients (2% of the examinations) data were discarded because of a low signal to noise ratio which was related to both small amplitude of the signal and the presence of several artefacts due to heavy movements and/or speaking of the patient. A typical systolic and diastolic times trend during exercise, dipyridamole and pacing stress is shown in Figure
Exercise stress echo
Exercise stress echo. Systolic (pink lines) and diastolic (black lines) times as a function of HR. Upper panel, a normal subject: systolic duration plotted as a function of HR demonstrates a slight linear decrease; duration of diastole demonstrates the most significant change. Middle panel, a patient with severe mitral regurgitation and stress induced severe pulmonary hypertension; the test was stopped at low stress load due to limiting dyspnoea without stress induced ischemia: prolonged systolic time with systolic/diastolic time reversal occurred during stress. Lower panel, a patient with stress induced ischemia at low stress load: at ischemia systole lengthens with systolic/diastolic time reversal.
Dipyridamole stress echo (0.84 mg/kg in 6', accelerated protocol)
Dipyridamole stress echo (0.84 mg/kg in 6', accelerated protocol). Systolic (pink lines) and diastolic (black lines) times as a function of HR. Dipyridamole results in adenosine receptor-mediated systemic as well coronary vasodilatation, often accompanied by a reflex increase in heart rate. With moderate stress induced HR increase (up to 110–100 bpm, upper and middle panel) diastolic time critically shortens, equalling systolic time. With mild induced HR increase (up to 70 bpm, lower panel) diastole has longer duration.
Patients with a permanent Pace Maker
Patients with a permanent Pace Maker. Upper and middle panels, pacing stress echo: external programming of permanent PM induces a controlled change in heart rate which is independent of the patient capability to exercise; heart rate increase is achieved with sequential atrial-(right) ventricular stimulation with pacing induced left bundle branch block; a dramatic shortening of diastolic time occurs at pacing (from 60 bpm, spontaneous rhythmus to 100 bpm paced rhythmus) with a reversal of the systolic/diastolic ratio at 120 bpm heart rate). Lower panel, exercise stress in a patient with dilated cardiomyopathy (LVEF = 30%) and (sensed atrial rate) BIV pacing: the physiological induced increase in heart rate is accompanied by no reversal of the systolic/diastolic time ratio.
Diastolic time decreased from 541 ± 143 to 250 ± 59 msec during exercise, from 651 ± 146 to 387 ± 98 msec in the dipyridamole group, and from 600 ± 108 to 211 ± 48 msec in the pacing group (Figure
Summary data
Summary data. Left panels: plot of systolic (pink symbols) and diastolic (black symbols) mean ± SD time values at increasing heart rates during exercise, dipyridamole and pacing stresses. Right panels: plot of systolic/diastolic time ratio as mean ± SD time values at increasing heart rates in the same patients groups; despite lower peak stress heart rates, dipyridamole patients show systolic/diastole time reversal at around 100 bpm heart rate.
The systolic/diastolic time ratio increased from 0.64 ± 0.15 to 1 ± 0.23 in the exercise, from 0.57 ± 0.11 to 0.92 ± 0.19 in the dipyridamole group, and from 0.53 ± 0.08 to 1.25 ± 0.39 in the pacing group (Table
In the exercise group as a whole, diastolic times were blunted in females vs. males at peak stress (Figure
Exercise stress, males vs. females
Exercise stress, males vs. females. Plot of systolic (pink symbols) and diastolic (black symbols) mean ± SD time values at increasing heart rates during exercise stress in males (upper panels) and females (lower panels). Despite similar prevalence of controls vs. heart diseases patients in both subgroups, females show lower diastole duration at peak stress.
In the exercise group diastolic time was greater and systolic/diastolic time ratio lower in the 17 control subjects than in the 98 patients. At higher heart rates, diastole duration was blunted in patients with systemic hypertension, coronary, valvular or dilated heart disease. The relation between systole duration, diastole duration and the systolic/diastolic ratio to heart rate is demonstrated in Figure
Exercise stress, controls vs. patients
Exercise stress, controls vs. patients. Correlation between the heart rate and the systolic (pink symbols) and diastolic (black symbols) times is displayed by error bar charts plotting the standard deviations of individual variables at each 5 beats heart rate increase during stress. Repeated-measures analysis of variance (ANOVA) was used to compare data groups. At each stage of stress inter-group comparison was performed and significant differences (p < 0.05) are displayed with symbols: * = significant differences between controls (NL, left upper panel) and patients groups.
Exercise stress, controls vs. patients
Exercise stress, controls vs. patients. Systolic/diastolic ratio plotted against heart rate in 17 controls (NL, left upper panel) and in patients groups during exercise stress. At each stage of exercise inter-group comparison was performed and significant differences (p < 0.05) are displayed with symbols: * = significant differences between controls and patients groups.
In the dipyridamole group (no controls), mean systolic and diastolic time occupied 35 ± 5% and 65 ± 5 % of the total cycle period, at rest. At drug infusion, the mild rise in heart rate shortened both portions of the cardiac cycle, but the decrease was greater with diastole. At peak stress, systolic time period was 47 ± 6 % of the cycle, while the estimated diastolic time was 53 ± 6 (Figure
Individual's trends of 2 out of the 6 pacing stress are shown in Figure
Diastolic filling rate and cardiac index
By selection, mitral filling volume (= stroke volume index) was calculated in 102 out of the 161 patients. The diastolic filling rate was 101 ± 36 ml/m2* s-1 at rest and increased significantly (
Values for diastolic filling variables at rest and during exercise, dip and pacing stress are outlined in Table
Mitral filling volume and diastolic filling rate
EXERCISE
DIP
PACING
Pt n°
64
32
6
Age (years)
57 ± 13
Δ
66 ± 11
68 ± 10
Gender (M/F)
44/20
20/12
4/2
HR rest (bpm)
70 ± 14
67 ± 12
71 ± 10
HR peak (bpm)
129 ± 22
Δ
85 ± 13
*
132 ± 13
Diastolic time rest (msec)
531 ± 148
Δ
623 ± 135
600 ± 108
Diastolic time peak (msec)
245 ± 58
Δ
377 ± 87
*
211 ± 48
Mitral filling volume rest (= stroke volume index rest), ml/m2
28 ± 7
30 ± 7
35 ± 9
Mitral filling volume peak (= stroke volume index peak), ml/m2
30 ± 8
‡
33 ± 9
*
21 ± 6
diastolic filling rate rest (= mitral filling volume/diastolic time * 1,000), ml/m2 * s -1
105 ± 36
90 ± 26
117 ± 57
diastolic filling rate peak (= mitral filling volume/diastolic time*1,000), ml/m2 * s -1
248 ± 95
Δ
164 ± 60
191 ± 58
Cardiac index rest (ml/m2 * min)
1915 ± 605
1987 ± 4922
2473 ± 709
Cardiac index peak (ml/m2 * min)
3883 ± 1176
§
2783 ± 913
2745 ± 767
§= significant differences between exercise and both dipyridamole and pacing stress pts; ‡ = significant differences between exercise and pacing stress pts; * = significant differences between dipyridamole and pacing stress pts; Δ = significant differences between exercise and dipyridamole stress pts.
Diastolic time and diastolic filling rate vs. cardiac index: summary data
Diastolic time and diastolic filling rate vs. cardiac index: summary data. Left panels: scatter plots demonstrating relationships between the diastolic duration time and the cardiac index, both at rest and at peak stress. Right panels: scatter plots demonstrating relationships between the diastolic filling rate and the cardiac index, both at rest and at peak stress. Green symbols: dipyridamole stress; blue symbols: pacing stress; red symbols: exercise stress. The substantial increase in the LV diastolic filling rate measured as volume per time suggests a large filling capacity during exercise (red symbols).
Discussion
Recently, a cutaneous operator independent force-frequency relation recording system as been validated in the stress echo lab based on first heart sound vibrations amplitude variations at increasing heart rates
In the whole group of patients, mean systolic and diastolic time occupied 37 ± 5% and 63 ± 5% of the cardiac cycle at rest.
The total cardiac cycle duration is algebraically dependent on the heart rate [= 60,000 msec/heart rate] with fixed values totally independent from the increasing heart rate stress type. (Table
Heart rate and total cardiac cycle duration
HR b.p.m
50
60
70
80
90
100
110
120
130
140
150
160
170
180
Cardiac cycle length (msec)
1200
1000
857
750
666
600
545
500
463
429
400
375
353
333
The total cardiac cycle duration is algebraically dependent on the heart rate [= 60,000 msec/heart rate] with fixed values totally independent from the increasing heart rate stress type.
However at each heart rate the fixed total cardiac cycle time can be differently divided between systole and diastole. At fixed heart rates the diastolic time fraction is determined by factors that modulates systolic duration through modulation of myocyte contraction
In the exercise group of this study the systolic time declined as stress intensity increased, with a significant decrease at each level of exercise. From rest to peak exercise, the mean systolic time was shortened by 25 ± 11%. The diastolic time decreased markedly during early exercise and, at a heart rate of 100 bpm, the mean filling time had shortened by 35 ± 16% (by 52 ± 13% at peak stress). Others
At 100 bpm, systolic/diastolic time ratio was lower in the 17 controls (0.74 ± 0.12) than in patients with hypertensive (0.94 ± 0.12), coronary (0.88 ± 0.11), valvular (0.93 ± 0.14) or cardiomyopathy heart (0.86 ± 0.10) disease (all p < 0.05 vs. controls) (Figure
Reversal of the normal systolic/diastolic ratio may compromise cardiac filling and function. Stress-induced "systolic-diastolic mismatch" can be easily quantified by a disproportionate decrease of diastolic time fraction, and is associated to several cardiac diseases, possibly expanding the spectrum of information obtainable during stress.
In the dipyridamole group at rest, mean systolic and diastolic time occupied 36 ± 5% and 64 ± 5% of the total cycle period, respectively. It is not likely that dipyridamole by itself had an influence on diastolic time fraction. At six minutes drug infusion, the mild rise in heart rate shortened both portions of the cardiac cycle, but the decrease was greater with diastole. At peak exercise, systolic ejection period was 47 ± 6% of the cycle, while the estimated diastolic time was 53 ± 6%. Since shortening of diastole duration occurs greatly in the frequency ranges of dipyridamole infusion, with possible inversion of the normal systolic/diastolic time ratio, its knowledge could be useful in the evaluation of the coronary flow reserve
Clinical implications and different scenarios for the routine use of the sensor
Cardiovascular drugs and ischemia
Previous studies
Diastolic function and diastolic filling rate
The filling rate, i.e. volume per time, was calculated by dividing the stroke volume index, by the filling time. The filling rate was 101 ± 36 ml/m2 * s-1 at rest and increased significantly (
Despite their potential importance, the components and characteristics of the peripheral pump are poorly understood, reflecting the technical difficulty in assessing variables that influence cardiac diastolic filling during exercise. Stress echocardiography is useful for the evaluation of patients with dyspnoea of possible cardiac origin and diastolic heart failure currently accounts for more than 50% of all heart failure patients. The diagnosis of heart failure with normal ejection fraction requires evidence of diastolic left ventricular dysfunction, obtained non-invasively by tissue Doppler (E/E' > 15). However, interpretable E/E' are not always obtained, since the most common source of uninterpretable tracings is fusion of E and A velocities due to tachycardia. A better (more feasible and sensitive) way to assess diastolic function during stress echo is needed. The combination of a cutaneous operator-independent force sensor and 3D stress echo allows a highly feasible, fast and informative assessment of mitral inflow rate, which could be impaired in presence of diastolic dysfunction and provide insight on a novel form – feasible at last! – of diastolic stress echocardiography.
Limitations of the study
A potential limitation of this study is the lack of information regarding Doppler indexes or diastolic function or dysfunction during stress. Doppler echocardiography is the preferred method for non-invasive diastolic function assessment. Doppler-derived indexes have been used to characterize diastolic function in numerous cardiac disorders, including heart failure, myocardial infarction, hypertrophic cardiomyopathy, and hypertension. In current practice, most diastolic function indexes are derived by visual inspection of transmitral E- and A-waves. These shape-derived indexes include peak velocity of the E-wave (Epeak), duration of the E-wave, acceleration (AT) and deceleration (DT) times of the E-wave, and area under the E-wave [velocity-time integral (VTI)]. Additional indexes include the peak velocity of the A wave (Apeak) and the ratio of the Epeak and Apeak velocities (E/A)
During exercise E- and A-waves become difficult to separate and discern when the A-wave merges with the E-wave and covers more than two-thirds of the E-wave deceleration, which typically occurs at heart rate > 100 beats/min
It has been noted that E' is load independent in patients with chronic ischemic syndrome
Another potential limitation is the fact that cardiologic diastole includes filling phases, but also isovolumic relaxation
Five (3 %) of the 161 patients had stress induced ischemia. The low rate of test positivity depends on many factors. The test indication class was not always I or IIa: low appropriateness in a high volume laboratory setting mainly depends on too often repeated tests in the absence clinical changes
Conclusion
An operator independent cutaneous force sensor based on first heart and second heart sound vibrations amplitude recording may be utilized to automatically quantify cardiological systolic and diastolic duration.
A stable, reproducible, and consistent first heart sound and second heart sound signal has been obtained in all patients and utilized as a time markers to continuously assess cardiologic systole and diastole during exercise, dipyridamole and pacing stress echo. Diastolic time was greater and systolic/diastolic time lower in the 17 control subjects than in the patients. At higher heart rates, the increased systolic/diastolic ratio was accentuated in patients with systemic hypertension, or coronary, dilated or valvular heart disease, reflecting the relatively prolonged systole and shortened diastole in these patients.
Simultaneous calculation of stroke volume with echocardiography allowed quantifying diastolic filling rate and its increase with stress.
Portability of the sensor and simple remote transmission of the signal could allow telemonitoring in chronic heart failure patients.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
TB conceived this study, performed the data analysis, and drafted the manuscript; LV, CP, EPa, LP, DAR and MP were responsible for data collection and revised the manuscript; VG, EB, FF and MG were responsible for technology development and digital signal processing; GA gave a contribution to data discussion; EPi gave a contribution to the preparation of study design, data discussion, and critical revision of the manuscript. All authors read and approved the final manuscript.