Catalogue Search | MBRL
Are you sure you want to remove the book from the shelf?
{{itemTitle}}
13,194
result(s) for
"Circulatory system."
Sort by:
The circulatory system
Describes the components of the circulatory system, how the heart functions to pump blood through the human body, and cardiovascular diseases and disorders.
Book
Circulatory System Based Optimization (CSBO): an expert multilevel biologically inspired meta-heuristic algorithm
The optimization problems are becoming more complicated, requiring new and efficient optimization techniques to solve them. Many bio-inspired meta-heuristic algorithms have emerged in the last decade to solve these complex problems as most of these algorithms may be trapped into local optima and could not effectively solve all types of optimization problems. Hence, researchers are still trying to develop new and better optimization algorithms. This paper introduces a novel biologically-based optimization algorithm called circulatory system-based optimization (CSBO). CSBO is modeled based on the function of the body's blood vessels with two distinctive circuits, i.e. pulmonary and systemic circuits. The proposed CSBO algorithm is tested on a wide variety of complex functions of the real world and validated with the standard meta-heuristic algorithms. The results indicate that the CSBO algorithm successfully achieves the optimal solutions and avoids local optima. Note that the source code of the CSBO algorithm is publicly available at
http://www.optim-app.com/projects/csbo
.
Journal Article
The circulatory story
Your hardworking heart started beating eight months before you were born and continues to beat about one hundred thousand times a day. \"By the time you're seventy years old, it will have beaten about 2.5 billion times.\" Find out the story behind each beat on a journey through the body's circulatory system.
Book
Applying the Rasch model to measure students’ critical thinking skills on the science topic of the human circulatory system
Critical thinking (CT) is essential in science education to enable students to deeply understand scientific concepts and apply their knowledge to solve complex real-world problems. Despite its importance, a notable gap remains in the availability of instruments designed to measure CT in specific science topics. This study addresses this gap by testing the accuracy of an instrument for assessing secondary students’ CT related to the human circulatory system, focusing on six APA-defined indicators: interpretation, analysis, inference, evaluation, explanation, and self-regulation. The study was conducted in Bantul Regency, Yogyakarta, Indonesia, and involved 445 8th-grade students from urban, middle, and rural schools. Data were collected through an online test administered in collaboration with teachers after students had completed the topic. Using the Rasch model for data analysis improved the accuracy and consistency of the instrument. Results showed that self-regulation was CT subskill with the lowest mean score, highlighting it as a priority for development. At the same time, interpretation had the highest mean score, particularly in the level 4 rating category, making it the most mastered skill. These findings underscore the need for educators to develop targeted learning strategies that enhance CT skills and adapt them to other science topics with similar complexity to the human circulatory system.
Journal Article
The science of the heart and circulatory system
Introduces the workings of the heart and circulatory system in the human body.
Book
Risk of mortality from diseases of the circulatory system due to occupational chronic radiation exposure, considering the radiation dose rate
In this paper, we present findings of the analysis of mortality from diseases of the circulatory system in a cohort of Russian nuclear workers who were chronically exposed to ionizing radiation at radiation dose rate of 0.005–0.050 Gy/year. Excess relative risks of mortality from diseases of the circulatory system, cerebrovascular diseases, and ischemic stroke per unit total gamma-ray dose from external exposure accumulated at higher dose rates were found to be higher than the corresponding risks per unit total dose accumulated due to exposure at lower dose rates. Continuous radiation exposure at higher rates over a duration of 5 years was found to increase considerably the risk of mortality from diseases of the circulatory system, cerebrovascular diseases, and ischemic stroke.
Journal Article
Why do I bleed?
\"Want to know how arteries carry oxygen-rich blood throughout our bodies and what blood type means? Fun illustrations and entertaining text help give kids a clear understanding of the blood and circulatory system\"-- Provided by publisher.
Book
A patient-specific modelling method of blood circulatory system for the numerical simulation of enhanced external counterpulsation
Lumped parameter model (LPM) is a common numerical model for hemodynamic simulation of human’s blood circulatory system. The numerical simulation of enhanced external counterpulsation (EECP) is a typical biomechanical simulation process based on the LPM of blood circulatory system. In order to simulate patient-specific hemodynamic effects of EECP and develop best treatment strategy for each individual, this study developed an optimization algorithm to individualize LPM elements. Physiological data from 30 volunteers including approximate aortic pressure, cardiac output, ankle pressure and carotid artery flow were clinically collected as optimization objectives. A closed-loop LPM was established for the simulation of blood circulatory system. Aiming at clinical data, a sensitivity analysis for each element was conducted to identify the significant ones. We improved the traditional simulated annealing algorithm to iteratively optimize the sensitive elements. To verify the accuracy of the patient-specific model, 30 samples of simulated data were compared with clinical measurements. In addition, an EECP experiment was conducted on a volunteer to verify the applicability of the optimized model for the simulation of EECP. For these 30 samples, the optimization results show a slight difference between clinical data and simulated data. The average relative root mean square error is lower than 5%. For the subject of EECP experiment, the relative error of hemodynamic responses during EECP is lower than 10%. This slight error demonstrated a good state of optimization. The optimized modeling algorithm can effectively individualize the LPM for blood circulatory system, which is significant to the numerical simulation of patient-specific hemodynamics.
Journal Article
Effect of lower extremity amputation on cardiovascular hemodynamic environment: An in vitro study
Lower extremity amputation (LEA) was associated with a greater risk of cardiovascular disease, but its hemodynamic mechanisms have not been fully studied. Therefore, to clarify the interrelationship between them, and figure out the potential pathogenesis, the exploration of the hemodynamic environment change of patients after LEA was premeditatedly executed. A near-physiological mock circulatory system (MCS) was employed in the present work to replicate the cardiovascular circulation after LEA in a short time and the unsteady-state numerical simulation was utilized as an auxiliary method to observe the changes of the hemodynamic environment inside the blood vessel. Higher severity of LEA leads to higher peripheral vascular impedance, higher blood pressure, and more obvious redistribution of blood perfusion volume. In addition, higher severity of LEA leads to lower wall shear stress (WSS), higher oscillatory shear index (OSI), and higher relative residence time (RRT) appeared in the infrarenal abdominal aorta and the iliac artery, while these changes are closely related to the higher probability of cardiovascular diseases. Results showed that different degrees of LEA (varying heights, unilateral/bilateral) have diverse effects on the patient's hemodynamic environment. This study explained the potential pathogenesis of cardiovascular diseases after LEA from a hemodynamic perspective and provided a certain reference value for the improvement of the cardiovascular hemodynamic environment and the prevention of cardiovascular diseases in lower extremity amputees.
Journal Article