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Modelling the characteristics of the baroreceptorSmith, Kirsten Taneall January 2017 (has links)
A dissertation submitted to the Faculty of Engineering and the Built Environment,
University of Witwatersrand in fulfilment of the requirements for the degree of Master of Science in Engineering. 2017 / The baroreceptor is a stretch receptor which detects changes in pressure in arterial blood vessels.
Baroreceptor nerves inform the brainstem of changes in blood pressure, which then influences
sympathetic and parasympathetic nervous activity to counteract that change. Due to the relationship
between essential hypertension, sympathetic nervous activity and the baroreflex, there is some debate
in the literature about whether the baroreflex can act as a long-term controller of blood pressure. This
debate has increased in recent years, due to the high prevalence of essential hypertension in all
societies and the introduction of new technologies to counteract drug-resistance hypertension. The
baroreflex has become a source of debate due to the complex physiological feedback control that
regulates blood pressure and due to new stimulating electrical devices, which have shown promising
results in reducing drug-resistant essential hypertension.
system. This is done through a literature survey extending through experimental and modelling
research, where selected mathematical models of the baroreceptor are then analysed and simulated to
find the best performing model, so that they may be simulated for an extended frequency response
than what would be experimentally possible. The purpose of this investigation is to determine, through
simulation, what the sensor static and dynamic characteristics are. Through this characterisation of
the sensor behaviour of the baroreceptor in the baroreflex control loop, it is then possible to infer
whether the baroreflex can act as a long-term controller of blood pressure.
An overview of experimental and analytical investigations on the baroreceptor over the last 70 years is
summarised. This overview includes mathematical models, which predict experimental results. A
subset of four models from Srinivasen et al., Bugenhagen et al., Beard et al. and Mahdi et al. are
selected. These models are implemented in MATLAB and Simulink. The parameters and experimental
conditions are integrated into the Simulink models, and the simulated results are compared to the
reported experimental data. In this way, each mathematical model is evaluated using secondary data
for its ability to simulate the expected behaviour. Thereafter, all simulated models are compared under
the same input conditions (a 0-230 mmHg step input over 12 s). These results are used to select the
best performing models, based on how well they were parameterised and validated for experimental
tests. The best performing models are those of Beard et al. and Bugenhagen et al. They are tested for a
wide range of artificial inputs at different frequencies, with sinusoidal inputs which have periods that
range from 0.1 s to 10 days and have a 100 mmHg operating point with a 1 mmHg peak amplitude.
All modelling techniques studied show that the baroreceptor firing response resets due to the rate of
change in strain in the visco-elastic arterial wall. Both tested model frequency responses, although
parameterised for different species and for different major vessels, show high sensitivity to inputs in range from 1 s to 1 min 36 s (0.01 Hz 1Hz), and very low sensitivity for changes that are longer
than 16 min 36s (0.001 Hz). This extrapolated simulation suggests a zero gain near DC.
The simulated frequency response of the best performing baroreceptor models, which were validated
against short-term experimental data, indicate that the baroreceptor is only able to sense changes that
happen in less than 1 min 16s. The critical analysis of all the simulated baroreceptor models show that
this characteristic of the baroreceptor is caused by the visco-elastic layers of the arterial wall, and is
likely in all baroreceptors regardless of type or species. It also indicates that under electrical
stimulation of the baroreceptor, the input signal from the electrical device bypasses the baroreceptor
nerve ending (which is embedded in the arterial wall) and that the electrical signal of the baroreceptor
is bypassed by the new stimulated electrical signal of the device. Furthermore, if the sensor can only
detect short-term changes, then it is unlikely that the baroreceptor can inform the brainstem on longterm
changes to mean arterial blood pressure. Therefore, based on the models examined in this study,
this suggests that the baroreceptor is unlikely to be involved in long-term blood pressure control. This
analysis of the best performing model is presented to show the limitations of the baroreflex in long
term control of blood pressure. It serves as a simulated experiment to rationalise the contentious debate
around the role of the baroreflex in long term blood pressure control, and to allow for future
improvements that can be made on the baroreceptor model to allow for more extended modelling on
sor characteristics. An improvement that could be applied to the best performing
baroreceptor models, implemented in this study, is to examine the effects of ageing and inter-species
variability on carotid sinus dimensions and visco-elastic wall properties. / CK2018
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