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The suprachiasmatic nucleus generated rhythm in blood glucose a role for the autonomic nervous system /La Fleur, Susanne Eva, January 2001 (has links)
Proefschrift Universiteit van Amsterdam. / Met bibliogr., lit. opg. - Met samenvatting in het Nederlands.
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New concepts for managing diabetes mellitus / Fred KeetKeet, Fred January 2003 (has links)
Preface -
Biotechnology is generally considered to be the wave of the future. To facilitate
accurate and rapid development of medication and treatments, it is critical that we are
able to simulate the human body. One section of this complex model would be the
human energy system.
Pharmaceutical companies are currently pouring vast amounts of capital into research
regarding general simulation of cellular structures, protein structures and bodily
processes. Their aim is to develop treatments and medication for major diseases.
Some of these diseases are epidemics like cancer, cardiovascular diseases, stress,
obesity, etc. One of the most important causes of these diseases is poor blood glucose
control.
Current management methods for insulin dependent diabetes are limited to trial and
error systems: clearly ineffective and prone to errors. It is critical that better
management systems be developed, to ease the diabetic epidemic.
The blood glucose control system is one of the major systems in the body, as we are
in constant need of energy to facilitate the optimum functioning of the human body.
This study makes use of a developed simulation model for the human energy system
to ease the management of Diabetes mellitus, which is a malfunction of the human
energy system.
This dissertation is presented in two parts: The first part discusses the human energy
simulation model, and the verification thereof, while the second presents possible
applications of this model to ease the management of Diabetes.
The human energy system simulation model -
This section discusses the development and verification of the model. It also touches
on the causes, and current methods, of managing diabetes, as well as the functioning
of the human energy system.
The human energy model is approached with the conservation of energy in mind. A
top down model is developed, using data from independent studies to verify the
model.
Application of human energy simulation model -
The human energy simulation model is of little use if the intended audience cannot
use it: people suffering from malfunctioning energy systems. These include people
having trouble with obesity, diabetes, cardiovascular disease, etc. To facilitate this, we
need to provide a variety of products useable by this group of people.
We propose a variety of ways in which the model can be used: Cellular phone
applications, Personal digital assistants (PDAs) applications, as well as computer
software.
By making use of current technology, we generate a basic proof-of-concept
application to demonstrate the intended functionality. / MIng (Mechanical Engineering) North-West University, Potchefstroom Campus, 2004
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New concepts for managing diabetes mellitus / Fred KeetKeet, Fred January 2003 (has links)
Preface -
Biotechnology is generally considered to be the wave of the future. To facilitate
accurate and rapid development of medication and treatments, it is critical that we are
able to simulate the human body. One section of this complex model would be the
human energy system.
Pharmaceutical companies are currently pouring vast amounts of capital into research
regarding general simulation of cellular structures, protein structures and bodily
processes. Their aim is to develop treatments and medication for major diseases.
Some of these diseases are epidemics like cancer, cardiovascular diseases, stress,
obesity, etc. One of the most important causes of these diseases is poor blood glucose
control.
Current management methods for insulin dependent diabetes are limited to trial and
error systems: clearly ineffective and prone to errors. It is critical that better
management systems be developed, to ease the diabetic epidemic.
The blood glucose control system is one of the major systems in the body, as we are
in constant need of energy to facilitate the optimum functioning of the human body.
This study makes use of a developed simulation model for the human energy system
to ease the management of Diabetes mellitus, which is a malfunction of the human
energy system.
This dissertation is presented in two parts: The first part discusses the human energy
simulation model, and the verification thereof, while the second presents possible
applications of this model to ease the management of Diabetes.
The human energy system simulation model -
This section discusses the development and verification of the model. It also touches
on the causes, and current methods, of managing diabetes, as well as the functioning
of the human energy system.
The human energy model is approached with the conservation of energy in mind. A
top down model is developed, using data from independent studies to verify the
model.
Application of human energy simulation model -
The human energy simulation model is of little use if the intended audience cannot
use it: people suffering from malfunctioning energy systems. These include people
having trouble with obesity, diabetes, cardiovascular disease, etc. To facilitate this, we
need to provide a variety of products useable by this group of people.
We propose a variety of ways in which the model can be used: Cellular phone
applications, Personal digital assistants (PDAs) applications, as well as computer
software.
By making use of current technology, we generate a basic proof-of-concept
application to demonstrate the intended functionality. / MIng (Mechanical Engineering) North-West University, Potchefstroom Campus, 2004
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Metabolic energy management and cancer / Suretha PotgieterPotgieter, Suretha January 2007 (has links)
This study examined the energy dependence of cancer cells. Glucose was found to be their main energy source. It seems possible to use this dependence to advantage in the fight against cancer. A novel experiment to reduce the blood glucose supply and utilisation was proposed. It entailed caloric restriction, suppression of glucose secretion by the liver as well as suppression of stress hormones (which elevates glucose levels). This minimises the blood glucose value. As a last step, anti-insulin is provided to inhibit cancer cells to utilise the glucose. The cancer cells are thus deprived of their main energy source. This should lead to a reduction or elimination of tumours and will aid in preventing their development. Although feasible, this method turned out to be too expensive to perform the necessary clinical trials to prove the hypothesis.
Next, the focus shifted to cancer prevention. The human energy system was analysed with the goal to reduce the circulating glucose level. The main focus here was metabolised CHO energy consumption. A previously proposed unit – the Equivalent Teaspoon Sugar, or ets , was used to quantify energy with. It was shown that cancer risk increases significantly when the recommended ets consumption per day is exceeded.
Furthermore, it was shown that including fibre in a meal reduces the ets value of the meal. One gram of fibre leads to a reduction of around 0.6 ets . The link between exercise, stress, fibre, their resulting blood glucose levels and cancer were quantified in terms of ets . Exercise expends ets , while stress causes the liver to secrete more ets . Experimental data was analysed to confirm the relationships.
In conclusion an equation was formulated to describe the combined effect of all these elements on the energy system. One’s total daily ets consumption can be obtained from the equation, and it was linked to one’s cancer risk. Adapting a lifestyle that ensures the correct daily ets intake will lead to a significant reduction in cancer risk.
This study proved that cancer cells are very dependent on sugar and a restriction of this energy source forces them into regression. Using this knowledge to advantage may help in the combat one of the biggest killers of our time – cancer. / Thesis (Ph.D. (Electrical and Electronic Engineering))--North-West University, Potchefstroom Campus, 2012
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Metabolic energy management and cancer / Suretha PotgieterPotgieter, Suretha January 2007 (has links)
This study examined the energy dependence of cancer cells. Glucose was found to be their main energy source. It seems possible to use this dependence to advantage in the fight against cancer. A novel experiment to reduce the blood glucose supply and utilisation was proposed. It entailed caloric restriction, suppression of glucose secretion by the liver as well as suppression of stress hormones (which elevates glucose levels). This minimises the blood glucose value. As a last step, anti-insulin is provided to inhibit cancer cells to utilise the glucose. The cancer cells are thus deprived of their main energy source. This should lead to a reduction or elimination of tumours and will aid in preventing their development. Although feasible, this method turned out to be too expensive to perform the necessary clinical trials to prove the hypothesis.
Next, the focus shifted to cancer prevention. The human energy system was analysed with the goal to reduce the circulating glucose level. The main focus here was metabolised CHO energy consumption. A previously proposed unit – the Equivalent Teaspoon Sugar, or ets , was used to quantify energy with. It was shown that cancer risk increases significantly when the recommended ets consumption per day is exceeded.
Furthermore, it was shown that including fibre in a meal reduces the ets value of the meal. One gram of fibre leads to a reduction of around 0.6 ets . The link between exercise, stress, fibre, their resulting blood glucose levels and cancer were quantified in terms of ets . Exercise expends ets , while stress causes the liver to secrete more ets . Experimental data was analysed to confirm the relationships.
In conclusion an equation was formulated to describe the combined effect of all these elements on the energy system. One’s total daily ets consumption can be obtained from the equation, and it was linked to one’s cancer risk. Adapting a lifestyle that ensures the correct daily ets intake will lead to a significant reduction in cancer risk.
This study proved that cancer cells are very dependent on sugar and a restriction of this energy source forces them into regression. Using this knowledge to advantage may help in the combat one of the biggest killers of our time – cancer. / Thesis (Ph.D. (Electrical and Electronic Engineering))--North-West University, Potchefstroom Campus, 2012
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Simulation of the human energy system / Cornelis Petrus BothaBotha, Cornelis Petrus January 2002 (has links)
Preface -
Biotechnology is generally accepted to be the next economical wave of the future. In order to attain
the many benefits associated with this growing industry simulation modelling techniques have to be
implemented successfully. One of the simulations that ne' ed to be performed is that of the human
energy system.
Pharmaceutical companies are currently pouring vast amounts of capital into research regarding
simulation of bodily processes. Their aim is to develop cures, treatments, medication, etc. for major
diseases. These diseases include epidemics like diabetes, cancer, cardiovascular diseases, obesity,
stress, hypertension, etc. One of the most important driving forces behind these diseases is poor
blood sugar control.
The blood glucose system is one of the major subsystems of the complete human energy system. In
this study a simulation model and procedure for simulating blood glucose response due to various
external influences on the human body is presented.
The study is presented in two parts. The first is the development of a novel concept for quantifying
glucose energy flow into, within and out of the human energy system. The new quantification unit
is called ets (equivalent teaspoons sugar). The second part of the study is the implementation of the
ets concept in order to develop the simulation model.
Development of the ets concept -
In the first part of the study the ets concept, used for predicting glycaemic response, is developed
and presented.
The two current methods for predicting glycaemic response due to ingestion of food are discussed,
namely carbohydrate counting and the glycaemic index. Furthermore, it is shown that it is currently
incorrectly assumed that 100% of the chemical energy contained in food is available to the human
energy system after consumption. The ets concept is derived to provide a better measure of
available energy from food.
In order to verify the ets concept, two links with ets are investigated. These are the links with
insulin response prediction as well as with endurance energy expenditure. It is shown that with both
these links linear relationships provide a good approximation of empirical data. It is also shown that
individualised characterisation of different people is only dependent on a single measurable variable
for each link.
Lastly, two novel applications of the ets concept are considered. The first is a new method to use the
ets values associated with food and energy expenditure in order to calculate both short-acting and
long-acting insulin dosages for Type 1 diabetics. The second application entails a new
quantification method for describing the effects of stress and illness in terms of ets.
Development of the blood glucose simulation model -
The second part of the study presents a literature study regarding human physiology, the
development for the blood glucose simulation model as well as a verification study of the
simulation model.
Firstly, a brief overview is given for the need and motivation behind simulation is given. A
discussion on the implementation of the techniques for construction of the model is also shown. The
procedure for solving the model is then outlined.
During the literature study regarding human physiology two detailed schematic layouts are
presented and discussed. The first layout involves the complex flow pathways of energy through the
human energy system. The second layout presents a detailed discussion on the control system
involved with the glucose energy pathway.
Following the literature review the model for predicting glycaemic response is proposed. The
design of the component models used for the simulations of the internal processes are developed in
detail as well as the control strategies implemented for the control system of the simulation model.
Lastly, the simulation model is applied for glycaemic response prediction of actual test subjects and
the quality of the predictions are evaluated. The verification of the model and the procedure is
performed by comparing simulated results to measured data. Two evaluations were considered,
namely long-term and short-term trials. The quality of both are determined according to certain
evaluation criteria and it is found that the model is more than 70% accurate for long-term
simulations and more than 80% accurate for short-term simulations.
Conclusion -
In conclusion, it is shown that simplified simulation of the human energy system is not only
possible but also relatively accurate. However, in order to accomplish the simulations a simple
quantification method is required and this is provided by the ets concept developed in the first part
of this study. Some recommendations are also made for future research regarding both the ets
concept and the simulation model.
Finally, as an initial endeavour the simulation model and the ets concept proposed in this study may
provide the necessary edge for groundbreaking biotechnological discoveries. / PhD (Mechanical Engineering) North-West University, Potchefstroom Campus, 2003
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Simulation of the human energy system / Cornelis Petrus BothaBotha, Cornelis Petrus January 2002 (has links)
Preface -
Biotechnology is generally accepted to be the next economical wave of the future. In order to attain
the many benefits associated with this growing industry simulation modelling techniques have to be
implemented successfully. One of the simulations that ne' ed to be performed is that of the human
energy system.
Pharmaceutical companies are currently pouring vast amounts of capital into research regarding
simulation of bodily processes. Their aim is to develop cures, treatments, medication, etc. for major
diseases. These diseases include epidemics like diabetes, cancer, cardiovascular diseases, obesity,
stress, hypertension, etc. One of the most important driving forces behind these diseases is poor
blood sugar control.
The blood glucose system is one of the major subsystems of the complete human energy system. In
this study a simulation model and procedure for simulating blood glucose response due to various
external influences on the human body is presented.
The study is presented in two parts. The first is the development of a novel concept for quantifying
glucose energy flow into, within and out of the human energy system. The new quantification unit
is called ets (equivalent teaspoons sugar). The second part of the study is the implementation of the
ets concept in order to develop the simulation model.
Development of the ets concept -
In the first part of the study the ets concept, used for predicting glycaemic response, is developed
and presented.
The two current methods for predicting glycaemic response due to ingestion of food are discussed,
namely carbohydrate counting and the glycaemic index. Furthermore, it is shown that it is currently
incorrectly assumed that 100% of the chemical energy contained in food is available to the human
energy system after consumption. The ets concept is derived to provide a better measure of
available energy from food.
In order to verify the ets concept, two links with ets are investigated. These are the links with
insulin response prediction as well as with endurance energy expenditure. It is shown that with both
these links linear relationships provide a good approximation of empirical data. It is also shown that
individualised characterisation of different people is only dependent on a single measurable variable
for each link.
Lastly, two novel applications of the ets concept are considered. The first is a new method to use the
ets values associated with food and energy expenditure in order to calculate both short-acting and
long-acting insulin dosages for Type 1 diabetics. The second application entails a new
quantification method for describing the effects of stress and illness in terms of ets.
Development of the blood glucose simulation model -
The second part of the study presents a literature study regarding human physiology, the
development for the blood glucose simulation model as well as a verification study of the
simulation model.
Firstly, a brief overview is given for the need and motivation behind simulation is given. A
discussion on the implementation of the techniques for construction of the model is also shown. The
procedure for solving the model is then outlined.
During the literature study regarding human physiology two detailed schematic layouts are
presented and discussed. The first layout involves the complex flow pathways of energy through the
human energy system. The second layout presents a detailed discussion on the control system
involved with the glucose energy pathway.
Following the literature review the model for predicting glycaemic response is proposed. The
design of the component models used for the simulations of the internal processes are developed in
detail as well as the control strategies implemented for the control system of the simulation model.
Lastly, the simulation model is applied for glycaemic response prediction of actual test subjects and
the quality of the predictions are evaluated. The verification of the model and the procedure is
performed by comparing simulated results to measured data. Two evaluations were considered,
namely long-term and short-term trials. The quality of both are determined according to certain
evaluation criteria and it is found that the model is more than 70% accurate for long-term
simulations and more than 80% accurate for short-term simulations.
Conclusion -
In conclusion, it is shown that simplified simulation of the human energy system is not only
possible but also relatively accurate. However, in order to accomplish the simulations a simple
quantification method is required and this is provided by the ets concept developed in the first part
of this study. Some recommendations are also made for future research regarding both the ets
concept and the simulation model.
Finally, as an initial endeavour the simulation model and the ets concept proposed in this study may
provide the necessary edge for groundbreaking biotechnological discoveries. / PhD (Mechanical Engineering) North-West University, Potchefstroom Campus, 2003
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