This document provides information about biopotential electrodes used for measuring bioelectric signals from the body. It discusses the electrode-skin interface and equivalent circuit, sources of noise and offset voltages, and classifications of electrodes including microelectrodes for single-cell measurements, skin surface electrodes like limb electrodes and suction cups for ECG, and needle electrodes for acute internal measurements. It also covers topics like the stable silver-silver chloride electrode, effects of polarization, and ensuring high amplifier input impedance.
MEASUREMENT OF BIO POTENTIAL USING TWO ELECTRODES AND RECORDING PROBLEMSBharathasreejaG
YOU CAN LEARN ABOUT MEASUREMENT USING TWO ELECTRODES & RECORDING PROBLEMS# NEED OF MEDICAL RECORDING # ELECTRODE TO SKIN INTERFACE # NERNST EQUATION # NOISE DURING RECORDING# MOTION ARTIFACT# ELECTRODE TO ELECTROLYTE NOISE # ELECTROLYTE TO SKIN NOISE# THERMAL NOISE# AMPLIFICATION NOISE# CABLE MOVEMENT# OTHER NOISES # CODING FOR GENERATING NOISE
The working of diffrent transducers and its priciples are discussed. The various types of sensors, transducers for the biopotential detections are also discussed with necessary diagrams.
A Bioamplifier is an electrophysiological device, a variation of the instrumentation amplifier, used to gather and increase the signal integrity of physiologic electrical activity for output to various sources. It may be an independent unit, or integrated into the electrodes.
The document discusses an electromagnetic blood flow meter. It operates based on electromagnetic induction principles, inducing an EMF in blood flowing through a vessel perpendicular to a magnetic field. Electrodes placed across the vessel measure this induced EMF, which is proportional to blood velocity. The small EMF signal is amplified for measurement and low pass filtered to determine average blood flow rate. Advantages include a linear dynamic range and no mechanical limitations for measuring high and low blood flows.
Biotelemetry is the measurement and transmission of biological parameters such as heart rate, blood pressure, and body temperature from a distance. It allows for monitoring of things like astronauts in space, patients during exercise or in ambulances, and collecting medical data from homes or offices. It also enables research on unrestrained animals in their natural habitats. Biotelemetry systems consist of components like amplifiers, oscillators, power supplies, analog-to-digital converters, digital-to-analog converters, transducers, and processors to adapt existing measurement methods to transmit the resulting data.
Bioelectrodes function as an interface between biological structures and electronic systems. They convert ionic potentials in the body to electronic potentials that can be measured. At rest, neurons maintain a potential of -70 mV due to ion concentration differences. An action potential occurs when the membrane reaches -55 mV, causing sodium and potassium ion channels to open and reverse the polarization. Action potentials propagate along axons to transmit signals. Synaptic transmission involves neurotransmitters being released at the synapse in response to an action potential. Bioelectrodes must have low impedance, be non-polarizing, and avoid motion artifacts when measuring biological signals like ECG, EEG, EMG.
The document discusses biopotential electrodes and microelectrodes. Biopotential electrodes measure bioelectric potentials through the metal-electrolyte interface between the electrode and body tissues. Microelectrodes are very small electrodes that can penetrate individual cells to obtain intracellular readings. There are two main types of microelectrodes: metal microelectrodes made of thin wires coated with insulation, and micropipette electrodes made of glass pipettes filled with electrolytes compatible with cell fluids. Both types allow precise measurement of electric potentials within cells.
This document discusses various medical devices and technologies that use sensors. It describes sensors that measure bioelectric signals, technologies like X-rays and ultrasounds, and how computers helped make complex medical sensors feasible. It also discusses different types of biomedical sensors and provides examples like pacemakers, ECGs, and blood glucose meters. Overall, the document outlines the important role sensors play in various medical applications and technologies that have helped improve human health and care.
MEASUREMENT OF BIO POTENTIAL USING TWO ELECTRODES AND RECORDING PROBLEMSBharathasreejaG
YOU CAN LEARN ABOUT MEASUREMENT USING TWO ELECTRODES & RECORDING PROBLEMS# NEED OF MEDICAL RECORDING # ELECTRODE TO SKIN INTERFACE # NERNST EQUATION # NOISE DURING RECORDING# MOTION ARTIFACT# ELECTRODE TO ELECTROLYTE NOISE # ELECTROLYTE TO SKIN NOISE# THERMAL NOISE# AMPLIFICATION NOISE# CABLE MOVEMENT# OTHER NOISES # CODING FOR GENERATING NOISE
The working of diffrent transducers and its priciples are discussed. The various types of sensors, transducers for the biopotential detections are also discussed with necessary diagrams.
A Bioamplifier is an electrophysiological device, a variation of the instrumentation amplifier, used to gather and increase the signal integrity of physiologic electrical activity for output to various sources. It may be an independent unit, or integrated into the electrodes.
The document discusses an electromagnetic blood flow meter. It operates based on electromagnetic induction principles, inducing an EMF in blood flowing through a vessel perpendicular to a magnetic field. Electrodes placed across the vessel measure this induced EMF, which is proportional to blood velocity. The small EMF signal is amplified for measurement and low pass filtered to determine average blood flow rate. Advantages include a linear dynamic range and no mechanical limitations for measuring high and low blood flows.
Biotelemetry is the measurement and transmission of biological parameters such as heart rate, blood pressure, and body temperature from a distance. It allows for monitoring of things like astronauts in space, patients during exercise or in ambulances, and collecting medical data from homes or offices. It also enables research on unrestrained animals in their natural habitats. Biotelemetry systems consist of components like amplifiers, oscillators, power supplies, analog-to-digital converters, digital-to-analog converters, transducers, and processors to adapt existing measurement methods to transmit the resulting data.
Bioelectrodes function as an interface between biological structures and electronic systems. They convert ionic potentials in the body to electronic potentials that can be measured. At rest, neurons maintain a potential of -70 mV due to ion concentration differences. An action potential occurs when the membrane reaches -55 mV, causing sodium and potassium ion channels to open and reverse the polarization. Action potentials propagate along axons to transmit signals. Synaptic transmission involves neurotransmitters being released at the synapse in response to an action potential. Bioelectrodes must have low impedance, be non-polarizing, and avoid motion artifacts when measuring biological signals like ECG, EEG, EMG.
The document discusses biopotential electrodes and microelectrodes. Biopotential electrodes measure bioelectric potentials through the metal-electrolyte interface between the electrode and body tissues. Microelectrodes are very small electrodes that can penetrate individual cells to obtain intracellular readings. There are two main types of microelectrodes: metal microelectrodes made of thin wires coated with insulation, and micropipette electrodes made of glass pipettes filled with electrolytes compatible with cell fluids. Both types allow precise measurement of electric potentials within cells.
This document discusses various medical devices and technologies that use sensors. It describes sensors that measure bioelectric signals, technologies like X-rays and ultrasounds, and how computers helped make complex medical sensors feasible. It also discusses different types of biomedical sensors and provides examples like pacemakers, ECGs, and blood glucose meters. Overall, the document outlines the important role sensors play in various medical applications and technologies that have helped improve human health and care.
Biopotentials are ionic voltages produced by electrochemical activity in cells. Certain cells like nerve and muscle cells are encased in a semi-permeable membrane that allows some substances to pass through while keeping others out. These membranes maintain a resting potential of -60 to -100 mV by allowing potassium and chloride ions into the cell while blocking sodium ions. When the membrane allows sodium ions to pass through, the cell's potential becomes slightly positive in what is called an action potential, changing the cell from its resting state. Transducers are used to convert these ionic potentials into electrical signals that can be measured and analyzed.
This document discusses various biomedical recorders used to measure electrical signals from the body. It focuses on electrocardiography (ECG) which measures the heart's electrical activity, and phonocardiography (PCG) which records heart sounds. For ECG, it describes the typical waveform, applications in diagnosis, and 12-lead measurement setup. For PCG, it explains the different heart sounds recorded, microphones used, writing methods, medical applications in detecting murmurs and valvular lesions, and special applications including fetal and esophageal PCG.
The Action and resting potential of the body are discussed. The working of body cell, tissue and how the electrical activity of body cell done? are discussed.
This document provides an overview of transducers for biomedical applications. It defines transducers as devices that convert one form of energy into another for measurement purposes. It classifies transducers as active or passive, analog or digital, and primary or secondary. It also discusses various transducer principles including capacitive, inductive, resistive, and piezoelectric. The document then focuses on specific biomedical applications, describing transducers used to measure electrical activity, blood pressure, blood flow, temperature, respiration, and pulse. Common transducer types for these applications include electrodes, strain gauges, inductive sensors, capacitive sensors, thermistors, and fiber optic sensors.
This document discusses different types of electrodes used to measure electrical activity in the body. It describes various classifications of transducers including passive vs active, absolute vs relative, direct vs complex, analog vs digital, and primary vs secondary. It also explains different electrode principles such as capacitive, inductive, and resistive. The document outlines types of electrodes like surface electrodes, needle electrodes, and microelectrodes and provides examples of each. It discusses factors to consider when selecting a transducer and electrodes used to measure specific physiological variables.
1.Bioelectric signals and their characteristics
2.Structure of heart
3.ECG Lead System Configuration
4.ECG Waveform
5.ECG Recording system – Block diagram
6.Analysis of ECG waveform
This document provides an overview of biomedical instrumentation. It discusses how instrumentation is used to monitor and control process variables for measurement and control. Biomedical instrumentation specifically creates instruments to measure, record, and transmit data to and from the body. Some key types of biomedical instrumentation systems are direct/indirect, invasive/noninvasive, contact/remote for sensing and actuating in real-time or statically. Several important instruments are discussed in detail, including X-rays, electrocardiography, magnetic resonance imaging, ultrasound, and computed tomography. The document outlines the basic workings, advantages, and disadvantages of these key biomedical instruments.
Graphic record heart sound - Phonogram.
Recording the sounds connected with the pumping action of heart.
Sound from heart – phonocardiogram
Instrument to measure this – phonocardiograph
Basic function – to pick up the different heart sound,filter the required and display.
This document discusses biopotentials and methods for measuring them. It begins with an introduction to biopotentials and what they are. It then discusses the mechanisms behind biopotentials, focusing on ion concentrations and how they generate electrical potentials. The rest of the document discusses specific measurement methods like ECG, EEG, EMG, EOG, and considerations for biopotential measurement like electronics, electrodes, and practices.
The document provides an overview of commonly used biomedical signals for monitoring physiological processes and detecting pathological conditions. It discusses several key signals including the electrocardiogram (ECG), electroencephalogram (EEG), electromyogram (EMG), electroretinogram (ERG), electrooculogram (EOG) and event-related potentials (ERPs). For each signal, it describes what physiological process is being measured, how the signal is recorded, its typical amplitude and bandwidth, main sources of interference and common applications. The document emphasizes that biomedical signals reflect the electrical, chemical and mechanical activities of cells, tissues and organs, and can provide important diagnostic information when analyzed.
The document outlines various topics related to biomedical instrumentation including biometrics, physiological systems of the human body like cardiovascular and respiratory systems, the kidney, bioelectric potentials, biopotential electrodes, and transducers for ECG, EEG, and EMG. It also provides details on the characteristics of biomedical instrumentation systems and describes concepts like bioelectric potential, action potential, and the recording setup for ECG, EEG, and EMG.
Telemetry involves measuring values at a remote location and transmitting the data to another location. It involves three steps - measuring a value, converting it to a signal, transmitting the signal, and reconverting it back to the original data. Factors like accuracy, whether the data is analog or digital, error detection/correction, and bandwidth influence telemetry system design. There are two main types - landline systems which use wires/cables over short distances, and radio frequency systems which use radio links from 1km to beyond 50km. Landline systems transmit current or voltage and have simple circuitry but limited range. Radio frequency systems transmit via radio links and are used for long range applications like spacecraft. Modulation schemes include amplitude modulation for
This document provides information about electroencephalography (EEG), electromyography (EMG), and patient monitoring. It discusses how EEG is used to measure brain activity through electrodes on the scalp. It describes the different frequency bands seen on EEG and how they relate to mental states. The document outlines the components of an EEG recording system and various EEG artifacts. It also discusses EMG and how it is used to measure muscle electrical activity. Finally, it covers patient monitoring systems, including bedside monitors, central monitoring stations, and the parameters that are measured like heart rate, blood pressure, respiration rate.
Topic 1 introduction of biomedical instrumentationGhansyam Rathod
Basic Description of the Biomedical Instrumentation subject and basics of the physiological system of human body discussed as per the syllabus of 2EC42 subject offered at Birla Vishvakarma Mahavidyalaya, Engineering Autonomous Institution.
Blood flow measurement involves quantifying the factors influencing blood pressure and flow. It aids in diagnosing and managing critically ill patients. There are invasive and non-invasive methods to measure blood flow in single vessels or tissue. Common techniques include electromagnetic flow meters, ultrasonic Doppler and transit-time flow meters, which use principles like electromagnetic induction or ultrasound to determine flow rate. Precise blood flow measurement is important for understanding cardiovascular conditions.
1. The document discusses isolation transformers and optical isolation. Isolation transformers transfer electrical power from one circuit to another while isolating the circuits to prevent faults or shocks, whereas optical isolators use light to isolate circuits and prevent unwanted feedback or interference.
2. Key aspects of isolation transformers are that they allow separate grounds, block interference from ground loops, and provide isolation for sensitive equipment or medical devices. Optical isolators contain an LED to convert electrical signals to light and a photosensor to convert light back to electrical signals with no direct connection between the two.
3. Both isolation transformers and optical isolators are used to isolate circuits for safety and prevent transmission of unwanted signals between circuits, but optical isolators
Biomedical Signal Processing / Biomedical Signals/ Bio-signals/ Bio-signals C...Mehak Azeem
These amazing and highly informative slides presented to the IEEE Signal Processing Society of IEEE MESCE Student Branch. These slides aim to provide basic knowledge about biosignals, their classification, examples and their working.
For more information, please contact:
[mehakazeem@ieee.org]
The document discusses different types of bioelectric signals and the electrodes used to record them. It describes the electrocardiogram (ECG), which records the electrical activity of the heart using skin surface electrodes. It also describes the electroencephalogram (EEG) for brain activity and electromyogram (EMG) for muscle activity. Other types discussed include the electroretinogram (ERG) for eye, electrogastrogram (EGG) for stomach, and electrooculogram (EOG) for eye movements. The document outlines the main electrode types used - skin surface electrodes, needle electrodes, and microelectrodes.
The document discusses different types of electrodes used to record bioelectric signals from the body and brain. It describes 5 main types used in EEG: scalp electrodes, sphenoidal electrodes placed near the temples, nasopharyngeal electrodes inserted in the nose, electrocorticographic electrodes placed directly on the brain, and intracerebral electrodes inserted into brain tissue. Reusable scalp disks, EEG caps with disks, adhesive gel electrodes, and subdermal needles are discussed as options for scalp electrodes. Microelectrodes and their uses are also summarized.
Biopotentials are ionic voltages produced by electrochemical activity in cells. Certain cells like nerve and muscle cells are encased in a semi-permeable membrane that allows some substances to pass through while keeping others out. These membranes maintain a resting potential of -60 to -100 mV by allowing potassium and chloride ions into the cell while blocking sodium ions. When the membrane allows sodium ions to pass through, the cell's potential becomes slightly positive in what is called an action potential, changing the cell from its resting state. Transducers are used to convert these ionic potentials into electrical signals that can be measured and analyzed.
This document discusses various biomedical recorders used to measure electrical signals from the body. It focuses on electrocardiography (ECG) which measures the heart's electrical activity, and phonocardiography (PCG) which records heart sounds. For ECG, it describes the typical waveform, applications in diagnosis, and 12-lead measurement setup. For PCG, it explains the different heart sounds recorded, microphones used, writing methods, medical applications in detecting murmurs and valvular lesions, and special applications including fetal and esophageal PCG.
The Action and resting potential of the body are discussed. The working of body cell, tissue and how the electrical activity of body cell done? are discussed.
This document provides an overview of transducers for biomedical applications. It defines transducers as devices that convert one form of energy into another for measurement purposes. It classifies transducers as active or passive, analog or digital, and primary or secondary. It also discusses various transducer principles including capacitive, inductive, resistive, and piezoelectric. The document then focuses on specific biomedical applications, describing transducers used to measure electrical activity, blood pressure, blood flow, temperature, respiration, and pulse. Common transducer types for these applications include electrodes, strain gauges, inductive sensors, capacitive sensors, thermistors, and fiber optic sensors.
This document discusses different types of electrodes used to measure electrical activity in the body. It describes various classifications of transducers including passive vs active, absolute vs relative, direct vs complex, analog vs digital, and primary vs secondary. It also explains different electrode principles such as capacitive, inductive, and resistive. The document outlines types of electrodes like surface electrodes, needle electrodes, and microelectrodes and provides examples of each. It discusses factors to consider when selecting a transducer and electrodes used to measure specific physiological variables.
1.Bioelectric signals and their characteristics
2.Structure of heart
3.ECG Lead System Configuration
4.ECG Waveform
5.ECG Recording system – Block diagram
6.Analysis of ECG waveform
This document provides an overview of biomedical instrumentation. It discusses how instrumentation is used to monitor and control process variables for measurement and control. Biomedical instrumentation specifically creates instruments to measure, record, and transmit data to and from the body. Some key types of biomedical instrumentation systems are direct/indirect, invasive/noninvasive, contact/remote for sensing and actuating in real-time or statically. Several important instruments are discussed in detail, including X-rays, electrocardiography, magnetic resonance imaging, ultrasound, and computed tomography. The document outlines the basic workings, advantages, and disadvantages of these key biomedical instruments.
Graphic record heart sound - Phonogram.
Recording the sounds connected with the pumping action of heart.
Sound from heart – phonocardiogram
Instrument to measure this – phonocardiograph
Basic function – to pick up the different heart sound,filter the required and display.
This document discusses biopotentials and methods for measuring them. It begins with an introduction to biopotentials and what they are. It then discusses the mechanisms behind biopotentials, focusing on ion concentrations and how they generate electrical potentials. The rest of the document discusses specific measurement methods like ECG, EEG, EMG, EOG, and considerations for biopotential measurement like electronics, electrodes, and practices.
The document provides an overview of commonly used biomedical signals for monitoring physiological processes and detecting pathological conditions. It discusses several key signals including the electrocardiogram (ECG), electroencephalogram (EEG), electromyogram (EMG), electroretinogram (ERG), electrooculogram (EOG) and event-related potentials (ERPs). For each signal, it describes what physiological process is being measured, how the signal is recorded, its typical amplitude and bandwidth, main sources of interference and common applications. The document emphasizes that biomedical signals reflect the electrical, chemical and mechanical activities of cells, tissues and organs, and can provide important diagnostic information when analyzed.
The document outlines various topics related to biomedical instrumentation including biometrics, physiological systems of the human body like cardiovascular and respiratory systems, the kidney, bioelectric potentials, biopotential electrodes, and transducers for ECG, EEG, and EMG. It also provides details on the characteristics of biomedical instrumentation systems and describes concepts like bioelectric potential, action potential, and the recording setup for ECG, EEG, and EMG.
Telemetry involves measuring values at a remote location and transmitting the data to another location. It involves three steps - measuring a value, converting it to a signal, transmitting the signal, and reconverting it back to the original data. Factors like accuracy, whether the data is analog or digital, error detection/correction, and bandwidth influence telemetry system design. There are two main types - landline systems which use wires/cables over short distances, and radio frequency systems which use radio links from 1km to beyond 50km. Landline systems transmit current or voltage and have simple circuitry but limited range. Radio frequency systems transmit via radio links and are used for long range applications like spacecraft. Modulation schemes include amplitude modulation for
This document provides information about electroencephalography (EEG), electromyography (EMG), and patient monitoring. It discusses how EEG is used to measure brain activity through electrodes on the scalp. It describes the different frequency bands seen on EEG and how they relate to mental states. The document outlines the components of an EEG recording system and various EEG artifacts. It also discusses EMG and how it is used to measure muscle electrical activity. Finally, it covers patient monitoring systems, including bedside monitors, central monitoring stations, and the parameters that are measured like heart rate, blood pressure, respiration rate.
Topic 1 introduction of biomedical instrumentationGhansyam Rathod
Basic Description of the Biomedical Instrumentation subject and basics of the physiological system of human body discussed as per the syllabus of 2EC42 subject offered at Birla Vishvakarma Mahavidyalaya, Engineering Autonomous Institution.
Blood flow measurement involves quantifying the factors influencing blood pressure and flow. It aids in diagnosing and managing critically ill patients. There are invasive and non-invasive methods to measure blood flow in single vessels or tissue. Common techniques include electromagnetic flow meters, ultrasonic Doppler and transit-time flow meters, which use principles like electromagnetic induction or ultrasound to determine flow rate. Precise blood flow measurement is important for understanding cardiovascular conditions.
1. The document discusses isolation transformers and optical isolation. Isolation transformers transfer electrical power from one circuit to another while isolating the circuits to prevent faults or shocks, whereas optical isolators use light to isolate circuits and prevent unwanted feedback or interference.
2. Key aspects of isolation transformers are that they allow separate grounds, block interference from ground loops, and provide isolation for sensitive equipment or medical devices. Optical isolators contain an LED to convert electrical signals to light and a photosensor to convert light back to electrical signals with no direct connection between the two.
3. Both isolation transformers and optical isolators are used to isolate circuits for safety and prevent transmission of unwanted signals between circuits, but optical isolators
Biomedical Signal Processing / Biomedical Signals/ Bio-signals/ Bio-signals C...Mehak Azeem
These amazing and highly informative slides presented to the IEEE Signal Processing Society of IEEE MESCE Student Branch. These slides aim to provide basic knowledge about biosignals, their classification, examples and their working.
For more information, please contact:
[mehakazeem@ieee.org]
The document discusses different types of bioelectric signals and the electrodes used to record them. It describes the electrocardiogram (ECG), which records the electrical activity of the heart using skin surface electrodes. It also describes the electroencephalogram (EEG) for brain activity and electromyogram (EMG) for muscle activity. Other types discussed include the electroretinogram (ERG) for eye, electrogastrogram (EGG) for stomach, and electrooculogram (EOG) for eye movements. The document outlines the main electrode types used - skin surface electrodes, needle electrodes, and microelectrodes.
The document discusses different types of electrodes used to record bioelectric signals from the body and brain. It describes 5 main types used in EEG: scalp electrodes, sphenoidal electrodes placed near the temples, nasopharyngeal electrodes inserted in the nose, electrocorticographic electrodes placed directly on the brain, and intracerebral electrodes inserted into brain tissue. Reusable scalp disks, EEG caps with disks, adhesive gel electrodes, and subdermal needles are discussed as options for scalp electrodes. Microelectrodes and their uses are also summarized.
The document discusses different types of bioelectrodes used to measure bioelectric signals. It describes microelectrodes which can measure potentials within a single cell, body surface electrodes like skin electrodes and needle electrodes, and disposable electrodes. It explains how electrodes work and factors like half-cell potential. Electrodes can be polarizable or non-polarizable. The document also discusses materials used for electrodes and their properties.
This document discusses different types of electrodes used in biomedical instrumentation. Electrodes are used to pick up electric signals from the body by converting ionic current into electronic current. Common types of electrodes include surface electrodes like metal plate electrodes and suction cup electrodes, needle electrodes, microelectrodes, depth electrodes, and chemical electrodes. The interface between the electrode and electrolyte allows measurement and recording of body potentials by providing a connection between the body and electronic measuring devices. Key characteristics of this interface include the transfer of electrons and ions across the barrier.
This document discusses biomedical systems and various types of biopotentials and electrodes. It covers resting potential, action potential, propagation of action potential, biological signals like ECG, EEG, EMG. It describes different types of electrodes - bio-potential electrodes, microelectrodes including etched metal, micropipette, and metal-film coated micropipette electrodes. It also discusses skin surface electrodes and their uses in ECG, EMG, EEG along with desirable electrode features.
The document introduces the basic electronic components including breadboards, resistors, capacitors, diodes, triodes, transistors, LEDs, coils, transformers, switches, relays, and integrated circuits. It provides brief descriptions of each component, including their symbols and functions. Resistors limit current, capacitors store energy, diodes allow current to pass in one direction, and transistors amplify signals. Together, these components form the building blocks of modern electronic circuits and devices.
The document introduces the basic electronic components including breadboards, resistors, capacitors, diodes, triodes, transistors, LEDs, coils, transformers, switches, relays, and integrated circuits. It provides brief descriptions of each component, their symbols and functions. Resistors limit current, capacitors store energy, diodes allow current to pass in one direction, transistors amplify signals, and integrated circuits combine multiple electronic components into a single chip. The document serves to familiarize readers with fundamental building blocks of electronics.
Bio potential electrodes are transducers that convert ionic currents in the body into electronic currents that can be measured by electronic equipment. They provide an interface between the body and measuring devices. At the electrode-electrolyte interface, ions carry current in the body while electrons carry current in the electrode. Electrodes change ionic current into electronic current to allow for measurement. Motion artifacts can occur when electrodes are disturbed, but can be reduced by using non-polarizable electrodes like silver-silver chloride electrodes.
Bio potential electrodes are transducers that convert ionic currents in the body into electronic currents that can be measured by electronic equipment. They provide an interface between the body and measuring devices. At the electrode-electrolyte interface, ions carry current in the body while electrons carry current in the electrode. Electrodes change ionic current into electronic current to allow for measurement. Motion artifacts can occur when electrodes are disturbed, but can be reduced by using non-polarizable electrodes like silver-silver chloride electrodes.
This document provides an overview of the Basic Electronics course EEE-231. The key details are:
- The course is 3 credit hours with lectures, quizzes, assignments, and exams throughout the semester. Minimum 80% attendance is required to sit for the final exam.
- The course will cover fundamentals of semiconductor physics, diodes, transistors, amplifiers, and digital circuits.
- Two textbooks are required for the course. Prerequisites include knowledge of DC circuit analysis.
This will cover chapter one and two of medical physics.Slides to help students in electrotherapy medical physics part.will cover part from the book and internet source includes
Thermal effect of current
Chemical effects
Cell/batteries
Electronic tube
Diodes
Triodes
Electrolysis
Electrical burns
This document provides information about the course EEE111 Analog Electronics offered in the spring 2023 semester. It includes details like the course code, title, semester, instructor's name and contact information. The document outlines the topics that will be covered, such as semiconductor devices, diodes, transistors, and electronic circuits. It lists the course objectives, outcomes, assessment methods including exams, quizzes, assignments and laboratory work. Recommended textbooks and references are also provided.
this presentation is based on magnetic effect of electric current, a which many of us have studies or will be studying in higher classes.this presentation is a better way of understanding the topic and in a visual way
This document provides an overview of microelectrodes and their use. It discusses:
1. Microelectrodes are used for potential recording, current injection, and introducing ion-selective resins into cells. They underlie techniques like voltage clamping and patch clamping.
2. Microelectrodes are usually glass micropipettes pulled to a fine tip, filled with electrolyte solution. Their tips can range from 1-500 megohms in resistance.
3. Junction potentials occur at interfaces between solutions of different ionic compositions and concentrations. They must be accounted for in accurate potential measurements.
Electronics is the branch of physics concerned with the design of circuits using transistors and microchips to control the behavior and movement of electrons. Key components include resistors, capacitors, inductors, diodes, and transistors. Together, these components can be used to build logic gates which are the basic building blocks of digital circuits and computers. Sensors are also important electronic components that detect changes in the environment and convert them to electrical signals.
This document provides an overview of current electricity topics including definitions of cells and batteries, types of cells like simple voltage cells, wet Leclanche cells, and dry cells. It discusses how cells work and how cells can be combined in series and parallel. It also summarizes thermal effects of current, electrolysis, electrolytic burns, ionization of gases, thermionic emission, diodes, triodes, and electronic tubes.
The document provides information about the ESL 130 Electrical and Electronics Workshop course. It outlines the continuous internal evaluation pattern which includes attendance, classwork assessment, and end semester exams. It then lists the various exercises and experiments covered in the course, including familiarization of electronic components, circuit diagram drawing, use of testing instruments, component testing, soldering practices, printed circuit boards, and assembling electronic circuits. Key components discussed include resistors, capacitors, inductors, diodes, transistors, integrated circuits, and various connectors.
This document summarizes basic electronic circuit elements and semiconductor components. It discusses the four main basic circuit elements - resistors, capacitors, inductors, and diodes - and what they are used for. It also explains that semiconductors like silicon and germanium can have their conductivity altered and are used to create transistors and integrated circuits. Transistors can amplify or switch currents, while integrated circuits incorporate multiple semiconductor devices onto a single chip and revolutionized electronics. In summary, basic circuit elements control electrical signals and semiconductors have unique properties used to build transistors and integrated circuits.
Clinical laboratories are important for disease diagnosis and monitoring patient health. They examine samples like blood, urine, and CSF to perform tests that help determine disease severity and treatment effectiveness. The main sections of a clinical lab are clinical pathology, hematology, clinical biochemistry, microbiology, serology, and blood bank. Biochemical tests analyze things like lipids, diabetes markers, electrolytes, and bone/liver function. Precise sample collection and handling are crucial to ensure accurate test results.
- The document discusses biomedical instrumentation and focuses on cardiac pacemakers and defibrillators.
- It describes how pacemakers use electrical impulses to regulate abnormal heart rhythms by contracting heart muscles. Pacemakers can be temporary or permanent depending on the cardiac condition.
- Defibrillators deliver electric shocks to the heart in ventricular fibrillation which can be fatal if not corrected. The document discusses different types of defibrillators and how they function to reestablish normal heart rhythm.
Measurement of blood pressure is one of the oldest physiological measurements. It originates from the heart and depends on three factors: cardiac output, artery diameter, and blood quantity. Normal values are below 120/80 mmHg. Indirect non-invasive methods like auscultation and oscillometry use an occlusive cuff on the brachial artery. Direct invasive methods involve catheter insertion but are needed for continuous accurate readings in dynamic situations. Both methods rely on measuring pressures as a cuff is inflated and deflated over the artery.
This document provides an overview of biomedical instrumentation. It discusses key topics such as:
- The development of biomedical instrumentation from early devices like the electrocardiograph to modern advances enabled by surplus electronics after WWII.
- Key considerations for designing medical instrumentation systems, including range, sensitivity, linearity, and frequency response.
- Components of the man-instrument system including the subject, stimuli, transducers, signal conditioning equipment, and displays.
- Objectives of instrumentation systems like information gathering, diagnosis, evaluation, monitoring and control.
- Biometrics as the measurement of physiological variables and parameters that biomedical instrumentation provides tools to measure.
Power system planning involves studies ranging from 1-10 years to determine generation, transmission, and distribution infrastructure needs. Key aspects of transmission planning include load forecasting, generation expansion planning to meet load, substation expansion planning, network expansion planning to transmit power from generators to loads, and reactive power planning. Both static planning looking at single time periods and dynamic planning considering multiple time periods simultaneously are used. Transmission planning is interconnected with generation planning, as transmission systems deliver power from generators to loads.
Power system planning involves arranging a scheme beforehand to adequately satisfy future load requirements. It determines new and upgraded generation, transmission, and distribution elements. Load forecasting is an important part of planning to estimate future loads. Short term forecasting is used for operations while long term forecasting informs infrastructure development decisions. Various statistical, artificial intelligence, and hybrid methods are used for load forecasting at different timescales, each with their own advantages and limitations regarding accuracy. Accurate load forecasting is essential for utility planning and operations.
This document discusses various problems facing the electricity industry and methods for long term load forecasting. It outlines common electrical problems like intermittent power, power surges, sags and outages. It then describes methods for long term load forecasting including trend analysis, econometric modeling and end-use analysis. Trend analysis uses past load data to predict future load. Econometric modeling establishes relationships between load and driving parameters statistically and forecasts load based on projected parameters.
Load forecasting is essential for power system planning to estimate future demand and energy requirements. Accurate load forecasts are needed to determine generation capacity additions, transmission and distribution infrastructure requirements, fuel procurement, and other planning decisions. Load forecasts can predict short-term (1 hour to 1 week) loads with about 1-3% accuracy but long-term (over 1 year) forecasts are less accurate due to uncertainties in weather predictions. Load forecasting helps utilities make important decisions around power purchasing, generation, and infrastructure development.
Understanding Inductive Bias in Machine LearningSUTEJAS
This presentation explores the concept of inductive bias in machine learning. It explains how algorithms come with built-in assumptions and preferences that guide the learning process. You'll learn about the different types of inductive bias and how they can impact the performance and generalizability of machine learning models.
The presentation also covers the positive and negative aspects of inductive bias, along with strategies for mitigating potential drawbacks. We'll explore examples of how bias manifests in algorithms like neural networks and decision trees.
By understanding inductive bias, you can gain valuable insights into how machine learning models work and make informed decisions when building and deploying them.
Advanced control scheme of doubly fed induction generator for wind turbine us...IJECEIAES
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3. Biopotential Electrodes
Bioelectric signals are picked up from the body
using electrodes.
Provide interface between the body and the
electronic instrumentation system.electronic instrumentation system.
3
4. • An electrode potential is developed across the
interface, proportional to the exchange of ions
between the metal and the electrolytes of the body.
• The double layer of charge at the interface acts as a
capacitor. Thus, the equivalent circuit of biopotential
electrode in contact with the body consists of a voltage
in series with a resistance-capacitance network of thein series with a resistance-capacitance network of the
type shown in Figure.
4
5. • Since measurement of bioelectric potentials requires
two electrodes, the voltage measured is really the
difference between the instantaneous potentials of
the two electrodes, as shown in Figure .
5
6. Two Silver plates used as biopotential
electrodes on the surface of the skin
6
8. 8
• To reduce that error by choice of materials, or by special
treatment, such as coating the electrodes by some
electrolytic method to improve stability.
9. • The dc voltage due to the difference in electrode
potentials is called the electrode offset voltage.
• The resulting current is often mistaken for a true
physiological event.
• Even two electrodes of the same material may produce
a small electrode offset voltage.
• In addition to the electrode offset voltage, experiments
have shown that the chemical activity that takes place
within an electrode can cause voltage fluctuations to
have shown that the chemical activity that takes place
within an electrode can cause voltage fluctuations to
appear without any physiological input.
• Such variations may appear as noise on a bioelectric
signal.
9
10. • This noise can be reduced by proper choice of materials
or, in most cases, by special treatment, such as coating
the electrodes by some electrolytic method to improve
stability.
• It has been found that, electrochemically, the silver-
silver chloride electrode is very stable.
• This type of electrode is prepared by electrolytically
coating a piece of pure silver with silver chloride.coating a piece of pure silver with silver chloride.
• The coating is normally done by placing a cleaned piece
of silver into a bromide-free sodium chloride solution.
• A second piece of silver is also placed in the solution,
and the two are connected to a voltage source such that
the electrode to be chlorided is made positive with
respect to the other.
10
11. • The silver ions combine with the chloride ions
from the salt to produce neutral silver chloride
molecules that coat the silver electrode.
• Some variations in the process are used to
produce electrodes with specific characteristics.
• The resistance-capacitance networks shown in
Figures represent the impedance of the
electrodes (one of their most importantelectrodes (one of their most important
characteristics) as fixed values of resistance and
capacitance.
• Unfortunately, the impedance is not constant.
11
12. • The impedance is frequency-dependent because of
the effect of the capacitance.
• Furthermore, both the electrode potential and the
impedance are varied by an effect called polarization.
• Polarization is the result of direct current passing
through the metal electrolyte interface.
• The effect is much like that of charging a battery with• The effect is much like that of charging a battery with
the polarity of the charge opposing the flow of
current that generates the charge.
• Some electrodes are designed to avoid or reduce
polarization.
12
13. • If the amplifier to which the electrodes are connected has
an extremely high input impedance, the effect of
polarization or any other change in electrode impedance is
minimized.
• Size and type of electrode are also important in
determining the electrode impedance.
• Larger electrodes tend to have lower impedances.
• Surface electrodes generally have impedances of 2 to 10
kΩ, whereas small needle electrodes and microelectrodeskΩ, whereas small needle electrodes and microelectrodes
have much higher impedances.
• For best results in reading or recording the potentials
measured by the electrodes, the input impedance of the
amplifier must be several times that of the electrodes.
13
14. Classifications
1. Microelectrodes: Electrodes used to measure
bioelectric potentials near or within a single cell.
2. Skin surface electrodes: Electrodes used to
measure ECG, EEG, and EMG potentials from themeasure ECG, EEG, and EMG potentials from the
surface of the skin.
3. Needle electrodes: Electrodes used to penetrate
the skin to record EEG potentials from a local
region of the brain or EMG potentials from a
specific group of muscles.
14
15. 1.Microelectrodes
• to study the electrical activity of individual cells
• electrode is small enough with respect to the size of
the cell in which it is inserted so that penetration by
the electrode does not damage the cell.
• The tip sizes of microelectrodes range from 0.5 to 5• The tip sizes of microelectrodes range from 0.5 to 5
microns.
• Mainly two types
– Metal Microelectrodes
– Micropipette or Micro capillaries electrodes
15
17. • Metal microelectrodes are formed by
electrolytically etching the tip of a fine tungsten
or stainless-steel wire to the desired size.
• Then the wire is coated almost to the tip with an
insulating material.insulating material.
• Some electrolytic processing can also be
performed on the tip to lower the impedance.
• The metal-ion interface takes place where the
metal tip contacts the electrolytes either inside or
outside the cell.
17
19. • The micropipet type of microelectrode is a glass
micropipet with the tip drawn out to the desired size
[usually about 1 micron (now more commonly called
micrometer, im) in diameter].
• The micropipet is filled with an electrolyte compatible
with the cellular fluids.
• This type of microelectrode has a dual interface.
• One interface consists of a metal wire in contact with• One interface consists of a metal wire in contact with
the electrolyte solution inside the micropipet, while
the other is the interface between the electrolyte
inside the pipet and the fluids inside or immediately
outside the cell.
19
21. • Micropipette structure filled with metal.
• The glass provides mechanical support. It
also serves as an insulation.
• The metallic area exposed is the active tip.
21
23. • A commercial type of microelectrode is shown in
Figure . In this electrode a thin film of precious metal
is bonded to the outside of a drawn glass
microelectrode.
• The manufacturer claims such advantages as lower
impedance than the micropipet electrode, infinite
shelf life, repeatable and reproducible performance,
and easy cleaning and maintenance.and easy cleaning and maintenance.
• The metal electrolyte interface is between the metal
film and the electrolyte of the cell.
23
28. 28
Floating electrodes are generally attached to the
skin by means of two sided adhesive collars (or
rings), which adhere to both the plastic surface of
the electrode and the skin.
29. Limb Electrodes/ Metal Plate Electrodes
• Employed in ECG
• Consists of rectangular or circular plates of German
silver or chrome or nickel plated steel
• The electrode held in place at the skin site by a• The electrode held in place at the skin site by a
rubber strap or belt
29
30. Suction-cup Electrode
• Requires no straps or adhesives to hold it in place.
• Used to record the precordial (chest) leads of ECG.
• consists of a hollow, metallic, cylindrical electrode
that makes contact with the skin at its base and athat makes contact with the skin at its base and a
rubber suction bulb which fits over its top.
• When the bulb is released, the suction applied
against the skin holds the electrode assembly in
place.
30
32. Various types of disposable electrodes have been introduced in
recent years to eliminate the requirement for cleaning and care after
each use.
32
33. • Special types of surface electrodes have been
developed for other applications.
• For example, a special ear-clip electrode was
developed for use as a reference electrode for
EEG measurements.
• Scalp surface electrodes for EEG are usually• Scalp surface electrodes for EEG are usually
small disks about 7 mm in diameter or small
solder pellets that are placed on the cleaned
scalp, using an electrolyte paste.
33
35. 3.Needle Electrodes and Wire Electrodes
• The electrodes or the lead wire penetrates the skin
or may be implanted internally are internal
electrodes (percutaneous electrodes) measure
biopotentials from with in the body usually made
of stainless steel with a sharp point are used forof stainless steel with a sharp point are used for
acute measurements.
• Needle electrodes uncomfortable for long-term
implantations.
• Wire electrodes are used for long term
implantation
35
37. Biochemical TransducersBiochemical Transducers
• The usual method of measuring concentrations of ions or
gases is to use one electrode (sometimes called the
indicator or active electrode) that is sensitive to the
substance or ion being measured and to choose the
second, or reference electrode, of a type that is insensitive
37
second, or reference electrode, of a type that is insensitive
to that substance.
38. 1. Reference Electrodes
The hydrogen electrode should actually be used as the
reference in biochemical
measurements.
Hydrogen electrodes can be built and are available
commercially.
These electrodes make use of the principle that an
inert metal, such as platinum, readily absorbs hydrogen
gas.
inert metal, such as platinum, readily absorbs hydrogen
gas.
If a properly treated piece of platinum is partially
immersed in the solution containing hydrogen ions and
is also exposed to hydrogen gas, which is passed
through the electrode, an electrode potential is
formed.
38
39. The electrode lead is attached to the platinum.
Unfortunately, the hydrogen electrode is not sufficiently
stable to serve as a good reference electrode.
Furthermore, the problem of maintaining the supply of
hydrogen to pass through the electrode during a
measurement limits its usefulness to a few special
applications.applications.
39
41. However, since measurement of electrochemical
concentrations simply requires a change of potential
proportional to a change in concentration, the electrode
potential of the reference electrode can be any amount,
as long as it is stable and does not respond to any
possible changes in the composition of the solution
being measured.
Thus, the search for a good reference electrode isThus, the search for a good reference electrode is
essentially a search for the most stable electrode
available.
Two types of electrodes have interfaces sufficiently
stable to serve as reference electrodes—the silver-silver
chloride electrode and the calomel electrode.
41
42. The silver-silver chloride electrode used as a reference in
electrochemical measurements utilizes the same type of
interface for bioelectric potential electrodes.
In the chemical transducer, the ionic (silver chloride) side of
the interface is connected to the solution by an electrolyte
bridge, usually a dilute potassium chloride (KCl) filling
solution which forms a liquid junction with the sample
solution.solution.
The electrode can be successfully employed as a reference
electrode if the KCl solution is also saturated with
precipitated silver chloride.
The electrode potential for the silver-silver chloride
reference electrode depends on the concentration of the
KCl.
42
43. An equally popular reference electrode is the calomel
electrode.
Calomel is another name for mercurous chloride, a
chemical combination of mercury and chloride ions.
The interface between mercury and mercurous chloride
generates the electrode potential.
By placing the calomel side of the interface in aBy placing the calomel side of the interface in a
potassium chloride (KCl) filling solution, an electrolytic
bridge is formed to the sample solution from which the
measurement is to be made.
Like the silver-silver chloride electrode, the calomel
electrode is very stable over long periods of time and
serves well as a reference electrode in many
electrochemical measurements. 43
44. Also, like the silver-silver chloride electrode, the
electrode potential of the calomel electrode
depends on the concentration of KCl.
44
45. 2. The pH Electrode
• The most important indicator of chemical
balance in the body is the pH of the blood and
other body fluids.
• The pH is directly related to the hydrogen ion
concentration in a fluid.
Specifically, it is the logarithm of the reciprocal of• Specifically, it is the logarithm of the reciprocal of
the H+ ion concentration.
• In equation form,
45
46. • The pH is a measure of the acid-base balance of a fluid.
• A neutral solution (neither acid nor base) has a pH of 7.
• Lower pH numbers indicate acidity, whereas higher pH
values define a basic solution.
• Most human body fluids are slightly basic.
• The pH of normal arterial blood ranges between 7.38 and
7.427.42
• The pH of venous blood is 7.35, because of the extra
CO2.
46
47. • Because a thin glass membrane allows passage of only
hydrogen ions in the form of H3O+, a glass electrode
provides a * 'membrane" interface for hydrogen.
• The principle is illustrated in Figure 4.15. Inside the glass
bulb is a highly acidic buffer solution.
• Measurement of the potential across the glass interface
is achieved by placing a silver-silver chloride electrode in
the solution inside the glass bulb and a calomel or silver-the solution inside the glass bulb and a calomel or silver-
silver chloride reference electrode in the solution in
which the pH is being measured.
• In the measurement of pH and, in fact, any
electrochemical measurement, each of the two
electrodes required to obtain the measurement is called
a half-cell.
47
48. • The electrode potential for a half-cell is sometimes called
the half-cell potential.
• For pH measurement, the glass electrode with the silver-
silver chloride electrode inside the bulb is considered one
half-cell, while the calomel reference electrode constitutes
the other half-cell.
• To facilitate the measurement of the pH of a solution,
combination electrodes of the type shown in Figure 4.16
are available, with both the pH glass electrode and
combination electrodes of the type shown in Figure 4.16
are available, with both the pH glass electrode and
reference electrode in the same enclosure.
• The glass electrode is quite adequate for pH measurements
in the physiological range (around pH 7), but may produce
considerable error at the extremes of the range (near pH of
zero or 13 to 14).
48
50. • Special types of pH electrodes are available for the
extreme ranges.
• Glass electrodes are also subject to some deterioration
after prolonged use but can be restored repeatedly by
etching the glass in a 20 percent ammonium bifluoride
solution.
• The type of glass used for the membrane has much to do
with the pH response of the electrode.
• Special hydroscopic glass that readily absorbs water
provides the best pH response.
• Special hydroscopic glass that readily absorbs water
provides the best pH response.
• Modern pH electrodes have impedances ranging from 50
to 500 megohms .
• Thus, the input of the meter that measures the potential
difference between the glass electrode and the reference
electrode must have an extremely high input impedance.
• Most pH meters employ electrometer inputs.
50
51. 3. Blood Gas Electrodes
• Among the more important physiological chemical
measurements are the partial pressures of oxygen and
carbon dioxide in the blood.
• The partial pressure of a dissolved gas is the contribution of
that gas to the total pressure of all dissolved gases in the
blood.
• The partial pressure of a gas is proportional to the quantity• The partial pressure of a gas is proportional to the quantity
of that gas in the blood.
• The effectiveness of both the respiratory and
cardiovascular systems is reflected in these important
parameters.
• The partial pressure of oxygen, PO2, often called oxygen
tension, can be measured both in vitro and in vivo
51
53. • A fine piece of platinum or some other noble metal wire,
embedded in glass for insulation purposes, with only the
tip exposed, is placed in an electrolyte into which oxygen is
allowed to diffuse.
• If a voltage of about 0.7 V is applied between the platinum
wire and a reference electrode (also placed into the
electrolyte), with the platinum wire negative, reduction of
the oxygen takes place at the platinum cathode.the oxygen takes place at the platinum cathode.
• As a result, an oxidation-reduction current proportional to
the partial pressure of the diffused oxygen can be
measured.
• The electrolyte is generally sealed into the chamber that
holds the platinum wire and the reference electrode by
means of a membrane across which the dissolved oxygen
can diffuse from the blood. 53
54. • The platinum cathode and the reference electrode can be
integrated into a single unit (the Clark electrode).
• This electrode can be placed in a cuvette of blood for in vitro
measurements, or a micro version can be placed at the tip of a
catheter for insertion into various parts of the heart or vascular
system for direct in vivo measurements.
• One of the problems inherent in this method of measuring P02
is the fact that the reduction process actually removes a finiteis the fact that the reduction process actually removes a finite
amount of the oxygen from the immediate vicinity of the
cathode.
• By careful design and use of proper procedures, modern PO2
electrodes have been able to reduce this potential source of
error to a minimum.
54
55. • Another apparent error in PO2 measurement is a gradual
reduction of current with time, almost like the polarization
effect described for skin surface electrodes in Section 4.2.2.
• This effect, generally called aging, has also been minimized
in modern PO2 electrodes.
• The measurement of the partial pressure of carbon dioxide,
PCO2 makes use of the fact that there is a linear relationship
between the logarithm of the P and the pH of a solutionbetween the logarithm of the PCO2 and the pH of a solution
• Since other factors also influence the pH, measurement of
PCO2 is essentially accomplished by surrounding a pH
electrode with a membrane selectively permeable to CO2.
55
56. • A modern, improved type of PCO2 electrode is called the
Severinghaus electrode.
• In this type of electrode, the membrane permeable to
the CO2 is made of Teflon, which is not permeable to
other ions that might affect the pH.
• The space between the Teflon and the glass contains a
matrix consisting of thin cellophane, glass wool, or sheer
nylon.
matrix consisting of thin cellophane, glass wool, or sheer
nylon.
• This matrix serves as the support for an aqueous
bicarbonate layer into which the CO2 gas molecules can
diffuse.
• One of the difficulties with older types of CO2 electrodes
is the length of time required for the CO2 molecules to
diffuse and thus obtain a reading. 56
57. • The principal advantage of the Severinghaus-type electrode
is the more rapid reading that can be obtained because of
the improved membrane and bicarbonate layer.
• In some applications, measurements of P02 and PC02 are
combined into a single electrode that also includes a
common reference half-cell.
• Such a combination electrode is shown in diagram form in• Such a combination electrode is shown in diagram form in
Figure 4.18.
57
59. 4. Specific Ion Electrodes
Just as the glass electrode provides a semi permeable
membrane for the hydrogen ion in the pH electrode ,
other materials can be used to form membranes that are
semi permeable to other specific ions.
In each case, measurement of the ion concentration is
accomplished by measurement of potentials across a
membrane that has the correct degree of permeability
to the specific ion to be measured.to the specific ion to be measured.
The permeability should be sufficient to permit rapid
establishment of the electrode potential.
Both liquid and solid membranes are used for specific
ions.
As in the case of the pH electrode, a silver-silver chloride
interface is usually provided on the electrode side of the
membrane, and a standard reference electrode serves as
the other half-cell in the solution.
59
60. • Figure 4.19 shows a solid-state electrode of the
type used for measurement of fluoride ions.
• Figure 4.20 shows three specific ion electrodes
along with a pH glass electrode. The sodium
electrode in Figure 4.20(a) is commonly used to
determine sodium ion activity in blood and other
physiological solutions.
• The cationic electrode (b) is used when studying
alkaline metal ions or enzymes.
• The cationic electrode (b) is used when studying
alkaline metal ions or enzymes.
• The ammonia electrode (d) is designed for
determinations of ammonia dissolved in aqueous
solutions.
• Its most popular application is in determining
nitrogen as free ammonia or total Kjeldahl
nitrogen.
60
61. • Figure 4.21 is a diagram showing the construction
of a flow-through type of electrode.
• This is a liquid-membrane, specific-ion electrode.
One of the difficulties encountered in the
measurement of specific ions is the effect of
other ions in the solution.
• In cases where more than one type of membrane• In cases where more than one type of membrane
could be selected for measurement of a certain
ion, the choice of membrane actually used might
well depend on other ions that may be expected.
• In fact, some specific-ion electrodes can be used
in measurement of a given ion only in the
absence of certain other ions.
61
62. • For measurement of divalent ions, a liquid
membrane is often used for ion exchange.
• In this case, the exchanger is usually a salt of an
organophosphoric acid, which shows a high degree
of specificity to the ion being measured.
• A calcium chloride solution bridges the membrane to
the silver-silver chloride electrode.the silver-silver chloride electrode.
• Electrodes with membranes of solid materials are
also used for measurement of divalent ions.
62
66. Transducers for biomedical
applications
• Several basic physical variables and the transducers
(active or passive)used to measure them are listed in
Table.
• It should be noted that many variables of great interest
in biomedical applications, such as pressure and fluid
or gas flow, are not included.or gas flow, are not included.
• These and many other variables of interest can be
measured, however, by first converting each of them
into one of the variables for which basic transducers
are available.
• Some very ingenious methods have been developed to
convert some of the more elusive quantities for
measurement by one of the transducers described.
66
68. Force TransducersForce Transducers
• A design element frequently used for the conversion
of physical variables is the force-summing member.
• One possible configuration of this device is shown in
Figure 2.12(a). In this case, the force-summing
member is a leaf spring.
• When the spring is bent downward, it exerts an
upward-directed force that is proportional to theupward-directed force that is proportional to the
displacement of the end of the spring.
• If a force is applied to the end of the spring in a
downward direction, the spring bends until its
upward-directed force equals the downward-directed
applied force, or, expressed differently, until the vector
sum of both forces equals zero.
68
69. • From this it derives its name ** force-summing
member.*' In the configuration shown, the force-
summing member can be used to convert a force
into a variable for which transducers are more
readily available.
• The bending of the spring, for example, results in
a surface strain that can be measured by means ofa surface strain that can be measured by means of
bonded strain gauges as shown in Figure 2.12(b).
• The transducers shown in Figure 2.13 utilize this
principle.
• The photographs illustrate that force and
displacement transducers are closely related.
69
70. • Sometimes, the terms isotonic and isometric are
used to describe the characteristics of these
transducers.
• Ideally a force transducer would be isometric; that
is, it would not yield (change its dimensions) when a
force is applied.
• On the other hand, a displacement transducer• On the other hand, a displacement transducer
would be isotonic and offer zero or a constant
resistance to an applied displacement.
• In reality, almost all transducers combine the
characteristics of both ideal transducer types.
70
71. • Figure 2.13, for example, shows the same basic
transducer type equipped with two different
springs.
• With the long, soft spring shown in the upper
photograph, the transducer assumes the
characteristics of an isotonic displacementcharacteristics of an isotonic displacement
transducer.
• With the short, stiff spring shown in the lower
photograph, it becomes an isometric force
transducer.
71
72. • Figure 2.12(c) shows measurement of displacement
using a differential transformer transducer.
• A less frequently used type of displacement
transducer is shown in Figure 2.12(d).
• Here the displacement of a spring is used to
modulate the intensity of a light beam via a
mechanical shutter.
• The resulting light intensity is measured by a photo
resistive cell.
• The resulting light intensity is measured by a photo
resistive cell.
• In this example, a multiple conversion of variables
takes place: force to displacement, displacement to
light intensity, and light intensity to resistance.
• This principle is actually employed in the commercial
transducer shown in Figure 2.14.
72
78. • If any one of the three variables can be measured, it
is possible—at least in principle—to obtain the other
two variables by integration or differentiation.
• Both operations can readily be performed by
electronic methods operating on either analog or
digital signals.
• Expressed in the frequency domain, the integration
of a signal corresponds to a low pass filter with aof a signal corresponds to a low pass filter with a
slope of 6 dB/octave, whereas differentiation
corresponds to a high pass filter with the same slope.
• Because the performance of analog circuits is limited
by bandwidth and noise considerations, integration
and differentiation of analog signals is possible only
within a limited frequency range.
78
79. • Usually, integration poses fewer problems than
differentiation.
• It should also be noted that discontinuities in the
transducer characteristic (e.g., the finite resolution
of a potentiometric transducer in which the
resistive element is of the wire-wound type) areresistive element is of the wire-wound type) are
greatly enhanced by the differentiation process.
• Table 2.2 shows that transducers for displacement
and velocity are readily available.
79
80. • However, the principles listed for these
measurements require that part of the transducer
be attached to the body structure whose
displacement, velocity, or acceleration is to be
measured, and that a reference point be available.
• Since these two conditions cannot always be met in• Since these two conditions cannot always be met in
biomedical applications, indirect methods
sometimes have to be used.
• Contactless methods for measuring displacement
and velocity, based on optical or magnetic
principles, are occasionally used.
80
81. • Magnetic methods usually require that a small
magnet or piece of metal be attached to the body
structure.
• Ultrasonic methods are used more frequently.
81
82. Pressure TransducersPressure Transducers
• Pressure transducers are closely related to force
transducers.
• Some of the force-summing members used in
pressure transducers are shown in Figure 2.15.
• Pressure transducers utilizing flat diaphragms• Pressure transducers utilizing flat diaphragms
normally have bonded or semiconductor strain
gauges attached directly to the diaphragms.
• Even smaller dimensions are possible if the
diaphragm is made directly from a thin silicon
wafer with the strain gages diffused into its
surface.
82
83. • The corrugated diaphragm lends itself to the design of
pressure transducers using unbonded strain gages or a
differential transformer as the transducer element.
• The LVDT blood pressure transducer uses these
principles.
• Flat or corrugated diaphragms have also occasionally
been used in transducers which employ the variable
reluctance or variable capacitance principles.reluctance or variable capacitance principles.
• Although diaphragm-type pressure transducers can be
designed for a wide range of operating pressures,
depending on the diameter and stiffness of the
diaphragm, Bourdon tube transducers are usually used
for high pressure ranges.
83
84. • It should be noted that the amount of deformation
of the force-summing member in a pressure
transducer actually depends on the difference in the
pressure between the two sides of the diaphragm.
• If absolute pressure is to be measured, there must be
a vacuum on one side of the diaphragm.
• It is much more common to measure the pressure• It is much more common to measure the pressure
relative to atmospheric pressure by exposing one
side of the diaphragm to the atmosphere.
• In differential pressure transducers the two
pressures are applied to opposite sides of the
diaphragm.
84
86. Flow TransducersFlow Transducers
• The flow rate of fluids or gases is a very elusive
variable and many different methods have been
developed to measure it.
86
87. Transducers with Digital OutputTransducers with Digital Output
• Increasingly, biomedical instrumentation
systems are utilizing digital methods for the
processing of data, which require that any data
entered into the system be in digital rather
than in analog form.
• Analog-to-digital converters, described in• Analog-to-digital converters, described in
Chapter 15, can be used to convert an analog
transducer output into digital form.
• It is often desirable to have a transducer
whose output signal originates in digital form.
87
88. • Although such transducers are very limited in their
application, they are available for measurement of
linear or rotary displacement.
• These transducers contain encoding disks or rulers
with digital patterns (see Figure 2.16)
photographically etched on glass plates.photographically etched on glass plates.
• A light source and an array of photo detectors, usually
made up of photos diodes or photo transistors, are
used to obtain a digital signal in parallel format that
indicates the position of the encoding plate, and
thereby represents the displacement being measured.
88
92. • The circulatory system carries nourishment and oxygen
to, and waste and carbon dioxide from, the tissues and
organs of the body
• In human circulatory system, the heart serves as a pump
to move blood through vessels called arteries and veins.
92
94. • The heart is a dual pump, consisting of a two chambered
pump on both the left and the right sides.
• The upper chambers are inputs to the pumps and are
called atria(atrium).
• The lower chamber of the heart are called ventricles and• The lower chamber of the heart are called ventricles and
are the pumps output.
94
95. • The heart has four valves
The tricuspid valve or right atrio-ventricular valve
Bicuspid Mitral or left atrio-ventricular valve
Pulmonary valve
Aortic valveAortic valve
95
96. • The deoxygenated blood is returned to the right side of the
heart via the venous system.
• Blood from the head and the arms, as well as rest of the
upper part of the body, returns to the heart through the
superior vena cava ; blood from the lower portion of thesuperior vena cava ; blood from the lower portion of the
body returns through the inferior vena cava.
• The inferior is placed lower in the body than superior.
96
97. • Blood leaves the right atrium through the tricuspid valve
to enter right ventricle.
• From right ventricle it passes through the pulmonary
semi lunar valve to pulmonary artery.
• This vessel carries blood to the lungs, where CO2 is
given out and O2 is taken in.
• Blood returning from lungs via pulmonary vein re-enters
the heart through left atrium.
• It then passes through the mitral valve to the left
ventricle and then back into the main stream of
circulatory system via the aortic valve.
97
98. • The great artery attached to the left ventricle is called
the aorta.
• Blood then circulates through the body to again return
to the right side of heart via superior and inferior vena
cava.
• The heart serves as a pump because of its ability to
contract under electrical stimulus. When an electricalcontract under electrical stimulus. When an electrical
triggering signal is received, the heart will contract,
starting in the atria. A fraction of second later the
ventricles also begin to contract.
• The ventricular contraction is known as systole. The
ventricular relaxation is known as diastole.
98
99. • The heart in a resting adult pumps approximately 3 to
5 litres of blood per minute. This is called cardiac
output (co) and is defined as the product of heart rate
in beats per minute and the volume of blood ejected
from the ventricle during systole.
CO=heart rate (beats/min) x stroke volume (L/beat)
• The heart wall consists of three layers• The heart wall consists of three layers
The Pericardium or Epicardium
The Myocardium
The Endocardium
99
102. • The conduction system of the heart consists of the
sinoatrial (SA) node, atrioventricular (AV) node,
bundle of His, the bundle branches, and Purkinje
fibers.
• The SA node serves as a pacemaker for the heart and
it provides the trigger signal (electrical impulses) toit provides the trigger signal (electrical impulses) to
control heart beat.
• The SA node fires electrical impulses through the
bioelectric mechanisms of depolarization and
repolarization.
102
103. • When the SA node discharges a pulse, then electrical
current spreads across the atria causing them to
contract. Blood in the atria is forced by the
contraction through the valves to the ventricles.
• The velocity of propagation for the SA node action
potential is about 30 cm/s in atrial tissue.potential is about 30 cm/s in atrial tissue.
• There is a band of specialized tissue between the SA
node and the AV node where the velocity of
propagation is faster than it is in atrial tissue and it is
of the order of 45 cm/s.
103
104. • the action potential will reach the AV node 30 to 50
ms after the SA node discharges.
• the ventricles will not contract in response to an action
potential before the atria are empty of their contents.
• Therefore a delay is provided at the AV node(110 ms).• Therefore a delay is provided at the AV node(110 ms).
• The AV node, then, operates like a delay line to retard
the advance of the action potential along the internal
electroconduction system toward the ventricles.
104
105. • The muscle cells of the ventricles are actually excited by
the Purkinje fibers. The action potential travels along
these fibers at a much faster rate, on the order of 2 to 4
m/s.
• The fibers are arranged in two bundles, one branch to the
left and one to the right.
• Conduction in the Purkinje fibers is very rapid,
consuming only 60 ms to reach the farthest Purkinjeconsuming only 60 ms to reach the farthest Purkinje
fibers.
• The action potential generated in the SA node stimulates
the muscle fibers of the myocardium (of ventricles),
causing them to contract. When the muscle is in
contraction, the volume of the ventricular chamber is less,
so blood is squeezed out.
105
106. • This electrical discharge can be mechanically plotted as a
function of time, and the resultant waveform is called an
electrocardiogram (ECG).
• Electrocardiogram is the waveform resulting from the
heart’s electrical activity.
• The instrument used to measure ECG is called the
electrocardiograph.
106
107. Electrocardiography
• The electrocardiogram (ECG or EKG) is a graphic recording or display
of the time-variant voltages produced by the myocardium during the
cardiac cycle.
107
The P, QRS, and T waves reflect the rhythmic electrical depolarization
and repolarization of the myocardium associated with the contractions
of the atria and ventricles.
The electrocardiogram is used clinically in diagnosing various diseases
and conditions associated with the heart.
It also serves as a timing reference for other measurements.
113. • For his diagnosis, a cardiologist would typically look
first at the heart rate.
• The normal value lies in the range of 60 to 100 beats
per minute.
• A slower rate than this is called bradycardia (slow
heart) and a higher rate, tachycardia (fast heart).
• He would then see if the cycles are evenly spaced.
• If not, an arrhythmia may be indicated.• If not, an arrhythmia may be indicated.
• If the P-R interval is greater than 0.2 second, it can
suggest blockage of the AV node.
• If one or more of the basic features of the ECG should
be missing, a heart block of some sort might be
indicated.
113
114. • In healthy individuals the electrocardiogram remains
reasonably constant, even though the heart rate changes
with the demands of the body.
• It should be noted that the position of the heart within the
thoracic region of the body, as well as the position of the
body itself (whether erect or recumbent), influences the
**electrical axis" of the heart. The electrical axis (which**electrical axis" of the heart. The electrical axis (which
parallels the anatomical axis) is defined as the line along
which the greatest electromotive force is developed at a
given instant during the cardiac cycle.
• The electrical axis shifts continually through a repeatable
pattern during every cardiac cycle.
114
115. • Under pathological conditions, several changes may occur
in the ECG. These include
(1) altered paths of excitation in the heart,
(2) changed origin of waves (ectopic beats),
(3) altered relationships (sequences) of features,
(4) changed magnitudes of one or more features, and
(5) differing durations of waves or intervals.
115
116. • An instrument used to obtain and record the
electrocardiogram is called an electrocardiograph.
• The electrocardiograph was the first electrical device to
find widespread use in medical diagnostics, and it still
remains the most important tool for the diagnosis of
cardiac disorders.
• Although it provides invaluable diagnostic information,• Although it provides invaluable diagnostic information,
especially in the case of arrhythmias and myocardial
infarction, certain disorders—for instance, those
involving the heart valves—cannot be diagnosed from
the electrocardiogram.
• Other diagnostic techniques, however, such as
angiography and echocardiography , can provide the
information not available in the electrocardiogram. 116
117. • The first electrocardiographs appeared in hospitals
around 1910, and while ECG machines have
benefited from technological innovations over the
years, little has actually changed in the basic
technique.
• Most of the terminology and several of the methods
still employed date back to the early days ofstill employed date back to the early days of
electrocardiography and can be understood best in
an historical context.
117
118. HistoryHistory
• The discovery that muscle contractions involve
electrical processes dates to the eighteenth century.
• At that time, however, the technology was not
advanced enough to allow a quantitative study of the
electrical voltages generated by the contracting heartelectrical voltages generated by the contracting heart
muscle.
• It was not until 1887 that the first electrocardiogram
was recorded by Waller, who used the capillary
electrometer introduced by Lippman in 1875.
118
119. • The string galvanometer, which was introduced to
electrocardiography by Einthoven in 1903, was a
considerable improvement.
• String galvanometer electrocardiographs like the one
shown in Figure 4.4 were used until about 1920, when
they were replaced by devices incorporating electronic
amplification.amplification.
• While recording systems of this type are mechanically
more rugged than the fragile string galvanometers,
they still require photosensitive film or paper which
has to be processed before the electrocardiogram can
be read.
119
120. • This disadvantage was overcome with the
introduction of direct writing recorders (about
1946), which used ink or the transfer of pigment
from a ribbon to record the ECG trace on a moving
paper strip, where it was immediately visible
without processing.without processing.
• Later, a special heat-sensitive paper was developed.
120
121. Electrodes and Leads
• To record an electrocardiogram, a number of electrodes,
usually five, are affixed to the body of the patient.
• The electrodes are connected to the ECG machine by
the same number of electrical wires.
• The wires, and the electrodes to which they are
connected are usually called leads.connected are usually called leads.
• The waveform obtained using a particular configuration
of electrodes is also called lead.
• The ECG waveform is very dependent on the placement
of the electrodes.
• ECG is recorded from a number of different leads,
usually 12, to ensure that no important detail of the
waveform is missed. 121
122. Electrodes
• The placement of the electrodes, as well as the color
code used to identify each electrode, is shown in
figure
• In his experiments Einthoven had found it
advantageous to record the electrocardiogram fromadvantageous to record the electrocardiogram from
electrodes placed vertically as well as horizontally on
the body.
• He had his patients place not only both arms but also
one leg into the earthenware crocks used as
immersion electrodes.
122
123. • The leg selected was the left one, probably
because it terminates vertically below the heart.
• The early electrocardiograph machines thus
employed three electrodes, of which only two
were used at one time.
• With the introduction of the electronic amplifier,
an additional connection to the body was neededan additional connection to the body was needed
as a ground reference.
• Although an electrode could have been
positioned almost anywhere on the body for this
purpose, it became a convention to use the
**free'' right leg.
123
124. • Plate electrodes are normally used for the
electrodes at the extremities, the chest electrode is
often the suction type
• It should be noted that abbreviations referring to
the extremities are used to identify the electrodes
even when they are actually placed on the chest, as
in the case of the patient-monitoring applications.in the case of the patient-monitoring applications.
124
125. The standard lead system
• In standard ECG recording there are five electrodes
(electrode positions) connected to the patient: right arm
(RA),left arm (LA), left leg (LL), right leg (RL), and chest
(C).
• The electrode on the right leg (RL) is only for ground
reference.reference.
• The recording obtained across different pairs of electrodes
results in different waveform shapes and amplitudes. These
different views are called leads.
• Each lead conveys a certain amount of unique information
that is not available in the other leads.
125
128. • Bipolar leads are designated as lead I, lead II, and lead
III
• In bipolar leads , the ECG is recorded by using two
electrodes such that the final trace corresponds to the
difference of electrical potential existing between them.
• They are called standard leads or Einthoven leads.
• In lead I, the electrodes are placed in the right and left
arm.arm.
• In lead II, the electrodes are placed in the right arm and
left leg and in lead III, they are placed on the left arm
and left leg.
• In all lead connections, the difference of potential
measured between two electrodes is always with the
reference to a third point on the body, the “right leg”.
128
129. Einthoven triangle
• Einthoven proposed that the electric field of the heart
could be represented diagrammatically as a triangle,
with the heart ideally located at the centre. The
triangle known as “ Einthoven triangle”.
129
130. • Lead I: PD between left arm and right arm(LA-RA). LA
is connected to the amplifier's non inverting input, while
RA is connected to the inverting input.
• Lead II: PD between left leg and right arm(LL-RA). The
LL electrode is connected to the amplifier's non
inverting input, while the RA is connected to the
inverting input (LA is shorted to RL).inverting input (LA is shorted to RL).
• Lead III: PD between left leg and left arm(LL-LA). The
LL is connected to the noninverting input while LA is
connected to the inverting input (RA is shorted to RL).
130
132. • In augmented unipolar limb leads,
the limb electrode – is the exploratory electrode
(active electrode)
The leads are aVR, aVL, aVF.
132
133. • In the lead aVR(augmented vector right), the right arm is
recorded with respect to a reference established by joining
the left arm and the left leg electrodes. RA is connected to
the non inverting input, while LL and LA are summed at the
inverting input.
• In the aVL(augmented vector left), the left arm is recorded• In the aVL(augmented vector left), the left arm is recorded
with respect to the common junction of the right arm and
left leg. LA is connected to the non inverting input, while LL
and RA are summed at the inverting input.
133
134. • In the aVF(augmented vector foot) lead, the left leg is
recorded with respect to the two arm electrodes tied
together. LL is connected to the non inverting input,
while RA and LA are summed at the inverting input.
• In all three augmented leads, the signals from two limbs• In all three augmented leads, the signals from two limbs
are summed in a resistor network and then applied to
the amplifier's inverting input, while the signal from the
remaining limb electrode is applied to the noninverting
input.
134
137. • For the unipolar chest leads, a single chest electrode
(exploring electrode) is placed on each of the six
predesignated points on the chest (V1 to V6).
• The three limb electrodes are used to obtain the central
terminal.
• The exploratory electrode records the potential of the
heart action on the chest at six different positions.heart action on the chest at six different positions.
137
139. • The principal parts or building blocks of an ECG
recorder are shown in figure .
• Also shown are the controls usually found on ECG
recorders; the dashed lines indicate the building block
with which each control interacts.
• The connecting wires for the patient electrodes
originate at the end of a patient cable, the other end oforiginate at the end of a patient cable, the other end of
which plugs into the ECG recorder.
• The wires from the electrodes connect to the lead
selector switch, which also incorporates the resistors
necessary for the unipolar leads.
139
140. • A pushbutton allows the insertion of a standardization
voltage of 1 mV to standardize or calibrate the recorder.
• Although modern recorders are stable and their sensitivity
does not change with time, the ritual of inserting the
standardization pulse before or after each recording when
recording a 12-lead ECG is still followed.
• Changing the setting of the lead selector switch introduces
an artifact on the recorded trace.an artifact on the recorded trace.
• A special contact on the lead selector switch turns off the
amplifier momentarily whenever this switch is moved and
turns it on again after the artifact has passed.
• From the lead selector switch the ECG signal goes to a
preamplifier, a differential amplifier with high common-
mode rejection.
140
141. • It is ac-coupled to avoid problems with small dc voltages
that may originate from polarization of the electrodes.
• The preamplifier also provides a switch to set the
sensitivity or gain.
• Older ECG machines also have a continuously variable
sensitivity adjustment, sometimes marked standardization
adjustment.
• By means of this adjustment, the sensitivity of the ECG• By means of this adjustment, the sensitivity of the ECG
recorder can be set so that the standardization voltage of 1
mV causes a pen deflection of 10 mm.
• In modern amplifiers the gain usually remains stable once
adjusted, so the continuously variable gain control is now
frequently a screwdriver adjustment at the side or rear of
the ECG recorder.
141
142. • The preamplifier is followed by a dc amplifier called
the pen amplifier, which provides the power to
drive the pen motor that records the actual ECG
trace.
• The input of the pen amplifier is usually accessible
separately, with a special auxiliary input jack at the
rear or side of the ECG recorder.rear or side of the ECG recorder.
• Thus, the ECG recorder can be used to record the
output of other devices, such as the
electromotograph, which records the Achilles reflex.
• A position control on the pen amplifier makes it
possible to center the pen on the recording paper.
142
143. • All modern ECG recorders use heat-sensitive paper,
and the pen is actually an electrically heated stylus,
the temperature of which can be adjusted with a
stylus heat control for optimal recording trace.
• Beside the recording stylus, there is a marker stylus
that can be actuated by a pushbutton and allows the
operator to mark a coded indication of the lead
being recorded at the margin of thebeing recorded at the margin of the
electrocardiogram.
• Normally, electrocardiograms are recorded at a
paper speed of 25 mm/s, but a faster speed of 50
mm/s is provided to allow better resolution of the
QRS complex at very high heart rates or when a
particular waveform detail is desired.
143
144. • The power switch of an ECG recorder has three
positions.
• In the ON position the power to the amplifier is turned
on, but the paper drive is not running.
• In order to start the paper drive, the switch must be
placed in the RUN position.
• In some ECG machines the lead selector switch has• In some ECG machines the lead selector switch has
auxiliary positions (between the lead positions) in which
the paper drive is stopped.
144
145. • In older ECG machines a pushbutton or metal
**finger contact" allows the operator to check
whether the recorder is connected to the power line
with the right polarity.
• Because the improper connection of older machines
can create a shock hazard for the patient, this test
must be performed prior to connecting themust be performed prior to connecting the
electrodes to the patient.
• Modern ECG machines, which have line plugs with
grounding pins, do not require such a polarity test.
145
146. • A more severe problem is the protection of the
electrocardiograph from damage during defibrillation.
• The voltages that may be encountered in this case can
reach several thousand volts.
• Thus, special measures must be incorporated into the
electrocardiograph to prevent burnout of components
and provide fast recovery of the trace so as to permit
electrocardiograph to prevent burnout of components
and provide fast recovery of the trace so as to permit
the success of the counter-shock to be judged.
146
147. Types of ECG recorders
(ECG read out devices)
1. Single-channel recorders.
2. Three-channel recorders.
3. Vector electrocardiographs
(vectorcardiographs).(vectorcardiographs).
4. Electrocardiograph systems for stress testing
5. Electrocardiographs for computer processing
6. Continuous ECG recording (Holter recording)
147
148. Single-channel recorders
• The most frequently used type of EGG recorder is
the portable single-channel unit
• For hospital use this recorder is usually mounted on
a cart so that it can be wheeled to the bedside of a
patient with relative ease.patient with relative ease.
148
150. • If the electrocardiogram of a patient is recorded in
the 12 standard lead configurations, the resulting
paper strip is from 3 to 6 ft long.
• Even if folded in accordion fashion, the strip is still
inconvenient to read and store.
• Therefore, it is usually cut up, and sections of the
recordings from the 12 leads are mounted as shownrecordings from the 12 leads are mounted as shown
in figure .
• Because it is easy to mix up the cut sections, the lead
for each trace is encoded at the margin of the paper,
using the marker pen, during the recording process.
• The code markers consist of short marks (dots) and
long marks (dashes) and look similar to Morse code.
150
151. • No standard code has been established for this
purpose, however.
• The cut sections of the electrocardiogram can be
mounted by inserting them in pockets of a special
folder with cutouts to make the trace visible.
• This is the way in which the electrocardiogram in figure
was mounted.was mounted.
• It should be noted that the recordings from the three
limb leads are longer than those from the other lead
selections in order to show several QRS complexes;
they are called rhythm strips.
151
152. • Commercial systems are available to simplify the
mounting by die-cutting the paper strip and using
mounting cards with adhesive pads.
• With the automatic three-channel recorders described
in the next section, the mounting is greatly simplified.
152
153. Three-channel recorders.
• Where large numbers of electrocardiograms are recorded
and mounted daily, substantial savings in personnel can be
achieved by the use of automatic three-channel recorders.
• These devices not only record three leads simultaneously
on a three-channel recorder, but they also switch
automatically to the next group of three leads.automatically to the next group of three leads.
• An electrocardiogram with the 12 standard leads,
therefore, can be recorded automatically as a sequence of
four groups of three traces.
• The time required for the actual recording is only about 10
seconds.
153
154. • The groups of leads recorded and the time at which the
switching occurs are automatically identified by code
markings at the margin of the recording paper.
• At the end of the recording, standardization pulses are
inserted in all three recording channels.
• Although the actual recording time is reduced
substantially compared to single-channel recorders,
more time is required to apply the electrodes to themore time is required to apply the electrodes to the
patient because separate electrodes must necessarily
be used for each chest position.
• The mounting of the electrocardiogram, however, is
simplified substantially, for no cutting or mounting of
the individual lead selections is required.
• A modern recorder of this type is shown in figure
154
156. Vector electrocardiographs
(vectorcardiographs).
• The voltage generated by the activity of the heart
can be described as a vector whose magnitude and
spatial orientation change with time.
• In the type of electrocardiography described thus
far, only the magnitude of the voltage is recorded.far, only the magnitude of the voltage is recorded.
• Vectorcardiography, on the other hand, presents an
image of both the magnitude and the spatial
orientation of the heart vector.
• The heart vector, however, is a three-dimensional
variable, and three ** views'' or projections on
orthogonal planes are necessary to describe the
variable fully in two-dimensional figures.
156
157. • Special lead placement systems must be used to pick up
the ECG signals for vector electrocardiograms, the Frank
system being the one most frequently employed.
• The vectorcardiogram is usually displayed on a cathode-
ray tube, similar to those used for patient monitors.
• Each QRS complex is displayed as a sequence of
**loops" on this screen, which is then photographed
with a Polaroid camera.
• Vectorcardiographs that use computer techniques to• Vectorcardiographs that use computer techniques to
slow down the ECG signals and allow the recording of
the vectorcardiogram with a mechanical X-Y recorder are
also available.
157
158. Electrocardiograph systems for stress
testing.
• Coronary insufficiency frequently does not manifest itself in
the electrocardiogram if the recording is taken during rest.
• In the Masters test or two-step exercise test, slphysiological
stress is imposed on the cardiovascular system by letting the
patient repeatedly walk up and down a special pair of 9-inch
high steps prior to recording his electrocardiogram.high steps prior to recording his electrocardiogram.
• Based on the same principle is the exercise stress test, in
which the patient walks at a specified speed on a treadmill
whose inclination can be changed.
• While the Masters test is normally conducted using a
regular single-channel electrocardiograph, special systems
are available for the exercise stress test.
• These systems, however, are usually made up of a number
of individual instruments which are described in this book.158
159. An exercise stress test system typically consists of the following
parts:
1. A treadmill which may incorporate an automatic programmer to
change the speed and inclination in order to apply a specific
physiological stress.
2. An ECG radiotelemetry system to allow recording of the ECG
without artifacts while the patient is on the treadmill.
3. An ECG monitor with a cathode-ray-tube display and heart rate
meter.meter.
4. An ECG recorder.
5. An automatic or semiautomatic sphygmomanometer for the
indirect measurement of blood pressure. Because the exercise
stress test involves a certain risk for patients with known or
suspected cardiac disorders, a dc defibrillator is usually kept
available while the test is performed.
159
160. Electrocardiographs for computer
processing.
• The automatic analysis of electrocardiograms by computers is used
increasingly
• This technique requires that the ECG signal from the standard leads
be transmitted sequentially to the computer by some suitable means,
together with additional information on the patient.
• The automatic three-channel recorders can frequently be adapted for
this purpose.this purpose.
• The ECG signals can either be recorded on a tape for later computer
entry or can be directly transmitted to the computer through special
lines or regular telephone lines using a special acoustical coupler .
• Information regarding the patient is entered with thumbwheel
switches or from a keyboard and is transmitted along with the ECG
signal.
• During the transmission of the signal, the electrocardiogram is
simultaneously recorded to verify that the transmitted signals are free
of artifacts.
160
161. Continuous ECG recording (Holter
recording).
• A normal electrocardiogram represents only a brief sample of cardiac activity,
arrhythmias which occur intermittently or only under certain conditions, such
as emotional stress, are frequently missed.
• The technique of continuous ECG recording, which was introduced by Norman
Holter, makes it possible to capture these kinds of arrhythmias.
• To obtain a continuous ECG, the electrocardiogram of a patient is recorded• To obtain a continuous ECG, the electrocardiogram of a patient is recorded
during his normal daily activity by means of a special magnetic tape recorder.
• The smallest device of this type can actually be worn in a shirt pocket and
allows recordings of the ECG for four hours. Other recorders, about the size of a
camera case, are worn over the shoulder and can record the electrocardiogram
for up to 24 hours.
• The recorded tape is analyzed using a special scanning device which plays
back the tape at a higher speed than that used for recording.
161
162. • By this method a 24-hour tape can be reviewed in as little
as 12 minutes.
• During the playback, the beat-to-beat interval of the
electrocardiogram is displayed on a cathode-ray tube as a
picket-fence-like pattern in which arrhythmia epsiodes
are clearly visible.
• Once such an episode has been discovered, the tape is• Once such an episode has been discovered, the tape is
backed up and slowed down to obtain a normal
electrocardiogram strip for the time interval during which
the arrhythmias occurred.
• A special time clock is synchronized by the tape drive to
correlate the onset of the episode with the activity of the
patient.
162