1 / 20

Autonomic Nervous System Control Model

Master Degree in Biomedical Engineering. Instituto Superior Técnico. Autonomic Nervous System Control Model. José Manuel Monteiro Grilo Lema Santos. Lisbon, October 21 st 2008. ANS Control Model.

Télécharger la présentation

Autonomic Nervous System Control Model

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Master Degree in Biomedical Engineering Instituto Superior Técnico AutonomicNervousSystemControlModel José Manuel Monteiro Grilo Lema Santos Lisbon, October 21st 2008

  2. ANS ControlModel • The blood pressure (BP) and heart rate are not static variables in the human body. However, the dynamic of their variation and control is not yet fully understood. • What is the baroreflex? • Description of the model used for the control of mean arterial pressure (MAP) and the heart rate (HR)

  3. ANS Control Model Baroreflex and Physiological Background

  4. ANS ControlModel • The baroreflex is a control system for the BP values with a negative feedback loop. The autonomic nervous system (ANS) is the controlling system. • Baroreceptors and chemoreceptors discovery (Heymans & Neil, 1958) in monkeys opened new doors to gain insight in the control of blood pressure (BP) by the baroreflex.

  5. ANS ControlModel Neural arch of the baroreflex. Baroreceptors triggers an ANS response.

  6. ANS ControlModel Peripheral arch of the baroreflex. Innervation from ANS triggers changes in the heart rate, systolic volume and blood vessels’ radius.

  7. ANS ControlModel Cross-section of a blood vessel. In general each vessels is divided in three layers called tunicas. BP is also affected in this efferent pathways of the ANS. The sympathetic system innervates the smooth muscle tissue, providing different lumen diameters according to the stimuli received by the baroreceptors.

  8. ANS ControlModel Schematics of the baroreflex functioning. BP rise triggers baroreceptors “spikes” that cause the ANS to respond and reduce the blood pressure. This is achieved by activation of parasympathetic fibers and inhibition of sympathetic fibers.

  9. ANS ControlModel Head-upTiltTableTest

  10. ANS ControlModel Head-upTilttabletestis a commontestofthebaroreflex. ECG and BP are monitoredcontinuoslywhilethebedistiltedfromthesupine to thestandingposition. Thebaroreflex response istypical.

  11. ANS ControlModel ControlModel

  12. ANS ControlModel • The searching for mathematical models to resemble the baroreflex is an active field of research • In the last years, several models using control theory have been created to further advance in our physiological knowledge. The impossibility in carrying tests in human subjects is a strong motivation. • The inexistence of a mathematical model that provides a valid explanation and a reasonable behaviour when compared to the baroreflex is a major gap.

  13. ANS ControlModel Model for the MAP from Kawada et al. (2002). HN – Transferfunctionfromthe neural arc. HP – Transferfunctionfromtheperipheral arc.

  14. ANS ControlModel ProposedModel S – SympatheticSystem V – Parasympathetic (Vagal) System

  15. ANS ControlModel • The multiplication of the vascular resistance by the cardiac output gives rise to the MAP, the major output of this model. • Baroreceptors will sense MAP. They regulate the values and maintain the homeostasis. • HUT disturbance is introduced directly in the MAP signal.

  16. ANS ControlModel Resultsfromthemodel

  17. ANS ControlModel Results from the model showing MAP, HR and CO. Experimental data resultsshowing HR andsystolicbloodpressure (SBP) duringHUT.

  18. ANS ControlModel • The incremental model proposed has a similar behaviour to the baroreflex mechanism and to the raw data used as the basis for the results. • The model introduced new concepts like the division of the peripheral arc into two distinct blocks: the heart block and the cardiovascular block. The neural block division is also new. • Systems of higher order can be applied to all blocks to better approximate the results. • Different parameters can be adjusted for different situations and results.

  19. ANS ControlModel Mythanks to… • Mytutorsfrom Instituto Superior Técnico and Faculdade de Medicina da Universidade de Lisboa; • To the Instituto de Sistemas e Robótica; • To thejury; • To myfamilyandmyotherhalf; • To theaudience.

  20. ANS ControlModel END Hopeyouhaveenjoyed!

More Related