Autonomous Cardiac Diagnostic based on Synchronized ECG and
PCG Signal
Z. Bouguila
1
, A. Moukadem
1
, A. Dieterlen
1
, A. Ahmed Benyahia
2,3
, A. Hajjam
2
, S. Talha
4
and E. Andres
4
1
MIPS Laboratory, University of Haute Alsace, 61 rue Albert Camus, 68093 Mulhouse, France
2
Irtes, Université de Technologie Belfort Montbéliard, 90010 Belfort, France
3
Newel, 36 rue Paul Cezanne, 68200 Mulhouse, France
4
Hôpital Civil, 1 Place de L’hôpital, 67000 Strasbourg, France
1 STAGE OF THE RESEARCH
The MIPS Laboratory (Modelling, Intelligence,
Process and Systems) is an interdisciplinary research
laboratory hosted by the Haute Alsace University. It
is involved in several research projects that deal with
signal processing, software engineering, microscopy
imaging and modeling and identification in
automatic and mechanic.
Since March 2012, the MIPS laboratory is
involved in the telemedicine project E-care
(www.projet-e-care.fr) piloted by the NEWEL
society. This project rallied economics and scientific
community to keep patients in the comfort of their
own home with a higher level of care and all this
with reduction cost.
The E-care project aims to develop best practices
and a platform for awareness raising, knowledge
exchange and policy making in this field. The
project is closely linked to the thesis contribution of
Ali Moukadem (Moukadem, 2011). Indeed, this
thesis fulfilled in MIPS laboratory and HUS
“Hôpitaux Universitaires de Strasbourg” co-financed
by “region Alsace” and ANR ASAP TLOG 06
project, became interested in development of robust
methods for heart sound analysis which can be used
for auto-diagnosis and telemedicine applications.
Diagnosis based PhonoCardioGram (PCG)
signals alone cannot detect all cases of heart
symptoms (Ahlstrom et al., 2008). In this work, we
are recommended for using an EleCtrocardioGram
(ECG) signal besides a PCG signal for heart disease
investigation. The advantage of the proposed system
is that a heart’s diagnosis system based on the ECG
and PCG signals can lead to high performance heart
diagnostics (Ping and Zhigang, 1998).
This thesis project, brings economic and
scientific partners together, is financially supported
by “Caisse des Dépots” and “region Alsace” and
seeks to improve the use of telemedicine for life
saving. The activities planned focus on providing
good practices and improving the quality of services
offered to patients.
2 OUTLINE OF THE E-CARE
PROJECT
Despite considerable advances in medical therapy,
heart failure remains a substantial burden of
mortality and economic cost
(EUROPEAN.COMMISSION, 2012). These trends
underline the growing fiscal and medical imperative
to develop better strategies to improve care delivery
to heart failure patients and reduce rehospitalization
rates.
The healthcare reform in many countries
generates new approaches to care delivery and to
provide high quality. The main reflect is the need for
improving the access of a growing aging population
in order to contain the costs (Zannad et al., 2009).
At the present, the societal and economic
benefits from wider use of telemedicine are far from
being achieved (Weinstein et al.). Then politicians
and healthcare leaders are realizing that telemedicine
is clearly a buttress of the solution. This is tangibly
seen by the soaring number of healthcare systems
that are adopting telemedicine, by the development
of industry investments in telemedicine products and
involvement of government in project delivery.
There common goals is to initiate the citizens on
keeping them healthy, partly by encouraging them to
become more active participants in their own health
management.
Telemedicine provides healthcare services
through use secure transmission of medical data and
36
Bouguila Z., Moukadem A., Dieterlen A., Ahmed Benyahia A., Hajjam A., Talha S. and Andres E..
Autonomous Cardiac Diagnostic based on Synchronized ECG and PCG Signal.
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
information for the diagnosis, prevention, treatment
and following up patients focusing in benefits of
advanced current technologies and the advance in
signal processing field.
Heart failure (HF) is among the major causes of
hospitalization for elderly citizens (Zannad et al.,
2009). The New York Heart Association (NYHA)
(www.heart.org) functional classification of HF is
widely used classification system relating HF
symptoms. The NYHA classification consists of four
categories that range from no symptoms (class I) to
severe at rest (class IV).
The E-care project’s, through telemedicine, main
objective is to greatly contribute to the enhancement
of the remote patient monitoring, expanding the
possibilities for lifesaving care. In this project, a
smart platform is adopted for home monitoring using
noninvasive sensors to HF patients with NYHA
(class III) severity. This platform is open and
extensible to integrate data sources, to complete the
patient knowledge which will help in diagnostic and
report the risk at an early stage.
Our contribution in this project, with our
partners, is to enhance the signal processing part for
accurate diagnostic. Although ECG and PCG signals
play important roles in heart abnormality detection,
diagnosis based alone on ECG signal or PCG signal
cannot detect most cases of heart symptoms. Hence,
some research has focused on diagnosing heart
defects based on the intercourse between ECG and
PCG signals (Jabloun et al., 2013); (Phanphaisarn et
al., 2011); (Ahlstrom et al., 2008) which can bring
high performance heart diagnostics.
Unlike the time or frequency methods, the time-
frequency analysis has the advantage of being robust
in heart sounds segmentation (Moukadem et al.,
2013). Thanks to this advantage, we want during this
thesis to expand the scope applications to ECG
signals and see also to find common features
between the two signals.
3 HARDWARE AND DATA
ACQUISITION
Chosen sensor are from the market and validated
“Continua” to ensure the compatibility with E-care
platform. A lot of new system will come on the
marquet on the feature, but we focus our attention
only on commercialized product so we work with
aquared signal from system that could be used by
cardiologist.
A laptop will be used as data acquisition for the
proposed analysis. A measurement campaign will be
carried out in the cardiology department of the HUS
of Strasbourg. Heart sound will be captured using
the electronic stethoscope (Littmann Electronic
Stethoscope Model 3200), figure 1. An ECG (éolys),
figure 2, amplifier circuit will be used to capture and
amplify the ECG of patients. Both are wirelessly
connected to the laptop.
3.1 Phonocardiogram Signals
Phonocardiogram (PCG) is the acoustic recording of
mechanical activity of the heart. It facilitates the
measurement of the instantaneous heart rate, beat-to-
beat differences and duration of systolic and
diastolic phases. These measures provide
information about the cardiac function.
Figure 1: 3M™ Littmann® Electronic stethoscope model
3200.
The Littmann electronic stethoscope, figure 1, is
intended for medical diagnostic purposes. It is used
for the detection and amplification of internal sounds
in human body such as from the heart, arteries,
veins, and other internal organs using selective
frequency ranges. It is designed to be used by
anyone who wishes to listen to a sound which is
known, in medical terms, as auscultation.
Using its Bluetooth wireless link, the stethoscope
exchange audio data with an external device in real
time, permitting their visual presentation, recording,
and analysis by applications software.
3.2 Electrocardiogram Signals
The heart produces tiny electrical impulses which
spread through the heart muscle to make the heart
contract.
Figure 2: Electrogradiogram éolys®.
AutonomousCardiacDiagnosticbasedonSynchronizedECGandPCGSignal
37
The éolys® electrocardiogram (ECG), figure 2,
record the electrical activity of the heart from
electrodes on the body surface. To measure the rate
and regularity of heartbeats, the ECG includes 12
self-adhesive electrodes attached to selected
locations of the skin on the arms, legs and chest.
There is for wirelessly transmitting a 3-/6- or 12-
channel ECG to a monitor, e.g. a PC or a regular
patient monitor.
4 SIGNAL PROCESSING
METHODS
In this experiment, the two physiological signals
(ECG and PCG) will be collected simultaneously but
without electronically controlled synchronization of
the measures.
Advanced methods and techniques of signal
processing and artificial intelligence will be applied
to extract relevant features, after the acquisition,
from the two physiological signals. These signals are
non-stationary by nature. The classical Fourier
transform analyzes the frequency content of signal
without any time information. Therefore, the
importance of time-frequency transforms to detect
the frequency changes of signal over time and to
extract pertinent features form the two physiological
signals.
4.1 S-Transform Challenges
In recent years, joint time and frequency
representation provide a better description of signals
in time-frequency planes. Therefore, the time-
frequency analysis for non-stationary signals is of
great interest and importance in evaluation of signal
characteristics. Mathematical tools of time-
frequency analysis include short-time Fourier
transform (STFT), Wigner-Ville distribution
(WVD), wavelet transform (WT) (Daubechies,
1990) and recently Stockwell Transform (S-
Transform) (Stockwell et al., 1996). S-Transform
leads to multiresolution signal processing, which is
considered as a variable sliding window STFT or as
phase corrected WT.
Stockwell et al., introduced in 1996 the S-
Transform. It combines the potential of the Short
Time Fourier Transform (STFT) and continuous
wavelet transform (CWT) and provides an
alternative approach to process the non-stationary
signals. It employs a moving and scalable localizing
window length. The frequency dependent window
function produces sharper time localization at higher
frequencies and higher frequency resolution at lower
frequencies. Furthermore, the S-Transform has an
advantage, even at the presence of high level of
noise (Stockwell et al., 1996,); (Mansinha et al.,
1997), in that it provides multi-resolution analysis
while it is capable of obtaining reasonably accurate
amplitude and phase spectrum of the analyzed
signals.
The S-Transform of a time series
ht is defined
as
2
2
,expexp2
2
2
f
tf
Sf ht iftdt
(1)
where
2
2
exp
2
2
f
t
f
is the Gaussian
modulation function and
1
f
f
is the standard
deviation.
where f is the frequency, t and
are both time.
The continuous wavelet transform
,Wd
of a
function
ht is defined as
,,Wd htwt ddt
(1)
The S-Transform of the function
ht can also be
defined as a wavelet transform with a specific
mother wavelet multiplied by a phase factor
,,exp2SfWd if
(2)
where the mother wavelet
,wtd is defined as
22
,expexp2
2
2
ftf
wt f i ft
(3)
where the dilation d function is the inverse of f. the
inverse of S-Transform is given by
,exp2ht S f d i ftdf
(4)
and, since
,Sf
is complex, can be written as
,,exp,SfAf i f
(5)
where
,
A
f
and
,
f
are the amplitude and the
phase of the S-spectrum respectively. The phase
spectrum is an improvement on the wavelet
transform in that the average of all the local spectra
does indeed give the same result as the Fourier
transform.
BIOSTEC2014-DoctoralConsortium
38
The S-Transform is a useful time-frequency
analysis algorithm. However, it still suffers from
poor energy concentration for the most classes of
signals. An optimization to the existing S-Transform
can enhance the energy concentration in the time-
frequency domain.
In this perspective, as part of my thesis, the first
line of work can be articulated on two theoretical
approaches presented in the following two
paragraphs.
4.1.1 Windows Width Algorithms
Modification of the window width of the S-
Transform enhances the energy concentration in the
time-frequency domain. Djurović et al., (2008)
proposed an algorithm to optimize the window width
in the S-Transform based on the measure of
concentration (Stanković, 2001), which
quantitatively evaluates the energy concentration.
Sejdić et al., (2007) use the Kaiser windows for
improving the energy concentration of the S-
Transform.
4.1.2 Time-frequency Reassignment and
Synchrosqueezing
The Heisenberg uncertainty principle limits the
resolution that can be attained in the time-frequency
plane; different trade-offs can be achieved by the
choice of time-frequency family transform, but none
is ideal. Then the representation can influence the
interpretation given on the time-frequency plane in
order to deduce properties of the signal.
To overcome this difficulty, new techniques,
reassignment (Auger and Flandrin, 1995) and
synchrosqueezing (Daubechies and Maes, 1996), are
recently emerged as a powerful signal processing
tool in non-stationary signal processing. Its basic
objective is to provide a sharper representation of
signals in the time-frequency plane and extract the
individual components of a non-stationary multi-
component signal. These techniques are widely used
in several of new domains, such as audio (Fulop and
Fitz, 2006), physics (Kotte et al., 2006), ecology
(Dugnol et al., 2007), or physiology (Auger et al.,
2013).
4.2 Features Extraction by
Time-frequency Correlation
Some heart problem know as mitral stenosis,
manifested through a heart sound known as the
Opening Snap (OS), is very similar to the third heart
sound (S3). Then, it is very difficult to distinguish
these two sounds without going through proper
training (Erikson, 1997).
In the E-care project we are interested by
detecting the fourth heart sound (S4). The fourth
heart sound is a low-pitched sound and it occurs
shortly before the first heart sound that makes it
detection difficult. For the purpose to study the
fourth heart sound we explore two methods based on
correlation with optimized S-Transform. These
methods can make the detection most effective.
The first method includes a cross-spectral
analysis to study the source localization and phase
synchrony of non-stationary signals (Assous and
Boashash, 2012); (Stockwel, 2007). Since the S-
Transform localizes spectral components in time, the
cross correlation of specific events gives the phase
difference and the amplitude of the cross S-
Transform indicates coincident signals. As the local
phase information can be extracted from the S-
Transform, we can use the cross S-Transform
function to analyze the in-phase and the out-of-phase
components in time-frequency space. This is a very
useful characteristic for cross-spectral and phase
synchrony.
The second method consists on pattern
recognition. The basic idea is to correlate the signal
being analyzed with known template and make
decisions based on the magnitude of the correlation
coefficients, which is between 0 and 1. The process
of correlation is essential to determine the degree of
similarity between the signal being analyzed and the
template. A proposed scheme (Sejdic and Jin, 2007)
known as Selective Regional Correlation (SRC) has
been developed for band limited nonstationary
signals. The preprocessing is carried out by
converting a one-dimensional (1D) time-domain
signal into a two-dimensional (2D) time-frequency
domain representation. The redundant representation
of a (1D) signal in a (2D) time-frequency domain
can provide an additional degree of freedom for
signal analysis to overcome the intertwined time
domain features of the signal and allowing more
importance in the time-frequency domain, resulting
more effective pattern matching.
5 EXPECTED OUTCOME
Using time-frequency reassignment,
synchrosqueezing and correlation function could
makes detection method more effective and accurate
in complex condition with heavy background noise.
In order to perform the knowledge of the heart
activity for automated heart diagnosis and heart
AutonomousCardiacDiagnosticbasedonSynchronizedECGandPCGSignal
39
disease investigation, we think that using two
physiological signals (ECG and PCG) could be
efficient. Both ECG and PCG signals can thus be
used together for early stage detection of heart
disease into E-care platform.
In this work, an automated system for
preliminary heart defect detection is proposed. This
system is based on the concept of time-frequency
signal analysis.
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