Abstract:
The living organisms possess several types of rhythms interacting with each other
and the outside dynamic environment, under the control of incalculable feedback systems
performing orderly function to enable life. The alternations in the rhythms of
physiological system help us to obtain information about the current state of living
systems having substantial diagnostic value in context of human health and disease. The
human body emits rhythmic alterations in form of recordable signals called biological
signals which reflects the, characteristics, state, properties and the information about the
physiological parameter such as heart, brain, muscles and genes etc. The large body
published literature suggested that heart rate signals are most widely explored biological
signals during last four decades. The electrocardiography (ECG) is used to detect
abnormalities in the cardiac rhythms during the onset of cardiovascular problems. The
rhythms of heart started to change long before the onset of disease, for which long term
ambulatory ECG (AECG) recording is required. Therefore, 24 h or 48 h AECG
monitoring is becoming vitally important for early detection of abnormal events to
prevent onset cardiovascular disease and in various clinical settings.
The variations in the beat-to-beat intervals called heart rate variability (HRV)
reflects the cardiac autonomic control of the autonomic nervous system (ANS), via its
sympathetic and parasympathetic branches. Reduced heart rate variability has been
associated with the onset of pathological disturbances, aging and early warning signs of
impending disease. During the last three decades, many linear and non-linear HRV
analysis techniques have been proposed for the extraction of information from cardiac
inter-beat interval time series data.
In the recent past, few studies have been conducted to find the relation between
heart rate (HR) and HRV. These studies either did not investigate the relationship between HR and HRV quantitatively or only considered linear HRV measures to find
quantitative relationship between HR and linear HRV parameters. Under usual
physiologic conditions, heart is not periodic oscillator, the linear HRV measures may fail
to provide account for transient fluctuations in the RR-interval data. The nonlinear HRV
measures have been used in numerous studies to account for transient fluctuations in the
heart. The one direction of the study was to investigate the relationship of both linear and
nonlinear HRV measures with HR. The result revealed inverse relationship between HRV
metrics and HR for human and animal heart rate time series data.
Recently, researchers proposed the idea of multiscaling for extracting information
from biological signals and validated that biological signals provide dynamically
incorrect information at single time scale. The second direction of the study was to assess,
how multiscaling procedures affect the relationship between HRV parameters and heart
rate. The results revealed inverse correlation between HR and HRV parameter at
threshold values 1 to 5.
Furthermore, the study focused on improving the classification ability of sign
series descriptor acceleration change index (ACI) and proposed novel sign series
measures for charactering the dynamics of healthy and pathological subjects. The
dynamical information encoded in the interbeat interval time series was examined using
scale based ACI measures (MACI and CMACI). The proposed scale base ACI measures
were compared with ACI for assessing the computational performance. The ANOVA,
Bonferroni post-hoc test, AUC, sensitivity, specificity, PPV, NPV, FDR, FOR and total
accuracy were used for assessing the performance of ACI and scale based ACI for
classifying healthy and pathological subjects. The results reported in the study depicted
that scale based acceleration change index measures showed better classification between
pathological and healthy groups at wide range of temporal scales.