Rigel Vital Signs Rev 1.2 USA
2016-12-21
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Innovating Together An introduction to measuring and simulating Vital Signs We’ve picked your brains to develop the world’s most advanced vital signs simulator. Your ideas have had us thinking. Some of you wondered why the functions of an ECG patient simulator, NIBP and SPO2 simulator couldn’t be combined into one compact tester? So we put our heads together and used our unrivalled expertise to create the hand-held Rigel UNI-SIM. To see the result, or to contribute your own ideas, call us on 813-886-2775, email us at enquiry@rigelmedical.com or visit rigelmedical.com rigelmedical.com Innovating Together Innovating Together Contents Foreword 1 Introduction 6.4 Color coding 21 6.5 The ECG machine 22 2 6.6 Testing ECG monitor 2 22 1.1 Visual inspection 3 6.6.1 Linearity of heart rate measurement 23 1.2 Who should verify the correct operation? 3 6.6.2 QRS beep 23 6.6.3 Alarms (high and low) 23 2 Physiology of the Respiratory System 4 6.6.4 Arrhythmias recognition (Asystolic) 23 6.6.5 Sensitivity test (Gain) 23 23 5 6.6.6 Zero offset 3.1 Measuring blood pressure 6 6.6.7 Frequency response 24 3.2 Testing your NIBP monitor 7 6.6.8 Printer calibration (amplitude, timing) 24 3.3 Test setup 7 3 Blood Pressure 7 Respiration 24 3.3.1 System pressure leak test: 7 3.3.2 System overpressure valve test 8 7.1 3.3.3 Static pressure or linearity test 9 7.1.1 Linearity of respiration measurement 26 3.3.4 Dynamic pressure 9 7.1.2 Sleep apnea 26 3.4 9 7.1.3 Testing apnea alarms 26 Considerations 4 Invasive Blood Pressure 11 4.1 Testing IBP function 11 4.2 Test setup 11 4.2.1 Static pressure or linearity test 12 (verify alarm testing) 4.2.2 Dynamic pressure 5 Pulse Oxymetry 8.1 Testing temperature function Artifacts 14 Testing your SPO2 monitor – 15 pulse oximeter 27 on multiparametric monitors 8.1.1 Linearity of temperature measurement 27 8.1.2 Testing temperature alarms 28 9 Record Keeping 28 Conclusion 29 Considerations and Recommendations: 29 30 16 5.3.1 Testing monitor accuracy 16 Appendix A 5.3.2 Alarms and time response test 17 IEC 60601-1 collateral standards 5.3.3 Sensitivity test 17 Appendix B 5.3.4 Testing the SPO2 probe 17 IEC 60601-2 particular standards Appendix C 6 Electrocardiographs (ECG) 27 13 5.2 Test setup 8 Temperature 26 12 5.1 5.3 Testing respiration function 18 YSI 400 & 700 resistance reference table 6.1 Einthoven Triangle 19 Appendix D 6.2 Precordial leads 20 Example documentation template 6.3 Unipolar vs. bipolar leads 21 31 34 35 1 Foreword This booklet is written as a guideline for people involved in testing medical, electrical equipment. All reasonable care has been taken to ensure that the information, reference figures and data are accurate and have been taken from the latest versions of various standards, guidance notes and recognized “best practises” to establish the recommended testing requirements. Rigel Medical, their agents and distributors, accept no responsibility for any error or omissions within this booklet or for any misinterpretations by the user. For clarification on any part of this booklet please contact Rigel Medical before operating any test instrument. No part of this publication shall be deemed to form, or be part of any contract for training or equipment unless specifically referred to as an inclusion within such contract. Rigel Medical assumes that the readers of this booklet are electronically and technically competent and therefore does not accept any liability arising form accidents or fatalities directly or indirectly from the tests described in this booklet. Introduction For decades, considerable work has been carried out across many industries; to reduce the risk of injury and occupational death to members of the general public. In addition, to aid the process of treating members of the general public, the health sector has evolved, offering an ever increasing portfolio of treatments, monitoring and diagnostic tools. Risks due to injuries or fatalities during medical treatment or examination are reduced through the introduction of industry practises (i.e. disinfection), guidelines (i.e. best practise), standards (i.e. design criteria, quality processes) and regulations (i.e. mandatory criteria). To ensure the safety of patients, operators and the members of public, all medical electronic devices must meet the design criteria of the internationally published IEC 60601 standard (or 2 local equivalent where applicable). First published in the 1970’s, the IEC 60601 standard (then referred to as IEC 601) describes the design criteria of medical electronic equipment (ME Equipment) in areas such as: Electrical safety Functional accuracy Mechanical safety Radiation safety Operator safety and errors (labelling, unambiguous instructions) ■ Safety of software ■ Risk assessment and preventative actions ■ ■ ■ ■ ■ IEC 60601-1-X (X representing a specific standard number between 1 - 12) is the primary standard and has eleven (sub) standards directly relating to the safety of medical equipment. IEC 60601-2-X (X representing a specific standard number between 1—65). This part of the standard is specific to various types of medical equipment rigelmedical.com Innovating Together and provides additional information to the four basic standards. Appendix A and B provide an overview of the IEC 60601-1-X and IEC 60601-2-X standards. This booklet describes the common aspects of vital signs monitoring and performance testing of those vital signs. The main vital signs described are: ■ Blood pressure (Invasive or non invasive methods) ■ Temperature ■ Electro cardiogram (ECG ) ■ Respiration ■ Blood oxygen saturation (SpO2) To ensure the correct treatment, diagnoses or monitoring of patients, it is of critical importance that the vital signs monitor is able to provide accurate data across all available vital signs. Such accuracy is verified on a regular basis, based on risk assessment, manufacturer recommendations and stages of the monitor’s life cycle. Performances tests (also referred to as quality or functional tests) are typically executed using calibrated simulators across a number of applications and are all part of an acceptance test, preventative maintenance cycle or repair. A typical test cycle for a vital signs monitor might include: ■ Visual inspection ■ Self tests (where applicable) ■ Electrical safety testing (ground bonding, leakage currents) ■ Integrity of the device under test (i.e. leak test, over pressure test) ■ Parameter accuracy (temperature, pressure, SpO2, time etc….) ■ Check alarms (pitch, frequency, volume) ■ Physiological simulations (Dynamic Patient Simulation) 1.1 Visual Inspection The process of visual inspection is not clearly defined by any standard, however visual inspections form a critical part of the general safety and performance inspections during the functional life of medical equipment. Visual inspections are a relatively easy procedure to ensure that the medical equipment in use, still conforms to the specifications as released by the manufacturer and has not suffered from any external damage and / or contamination. These can include the following inspections: ■ Housing - Enclosure; look for damage, cracks etc. ■ Contamination; look for obstruction of moving parts, connector pins, etc. ■ Cabling (supply, Applied Parts etc); Look for cuts, wrong connections, etc. ■ Fuse rating; check correct values after replacement ■ Markings and Labelling; check the integrity of safety markings ■ Integrity of mechanical parts; check for any obstructions 1.2 Who should verify the correct operation? The correct function and operation of medical equipment is equally as important as the function it performs. An incorrect reading or missed condition might have considerable consequences for the patient therefore; the person carrying out 3 the maintenance must be technically competent, appropriately trained and aware of the various parameters being verified. Figure 1: A simplified representation of the circulatory system It is the responsibility of the medical equipment manufacturer to provide verification procedures to ensure optimum performance is being achieved. The person or organization carrying out the maintenance must make themselves aware of the required procedures and operation of the medical equipment. When in doubt, contact the manufacturer. 2 Physiology of the respiratory system All vital signs are related to the operation and functioning of the respiratory system. While the Electro Cardiogram (see chapter 6) shows the electrical activity of the human heart pumping the oxygenated blood (see chapter 5) around the arteries, blood pressure (see chapter 3 & 4) is generated. Respiration (see chapter 7) rates might show any obstruction (apnea) in the airways thus affecting the oxygen absorption in the lungs. The core body temperature, together with blood pressure being the most commonly measured vital signs, is maintained through good blood circulation (see chapter 8). The human heart is central to the respiratory system and can be seen as the main engine within. The heart circulates blood through the body and lungs (the carburetor of the body attaching oxygen to the hemoglobin protein in the red blood cells) in order to ensure oxygen is able to reach the (brain) tissues and organs in order to sustain life. 4 To establish a single circulation cycle, blood flows through the heart twice, passing through the left and right side of the heart respectively. Acting as two “pumps”, the heart circulates oxygenated blood (red circuit, systemic circulation) from the lungs through the left side of the heart, while deoxygenated blood from the tissues flows through the right side of the heart to the lungs in order to re-oxygenate the blood cells (blue circuit, pulmonary circulation). The two ventricles (chambers) provide the blood from the heart while blood is entering the heart in the two atria (chambers). Valves in and between the different chambers ensure the chambers can fill up with blood during the diastolic phase (the heart muscle relaxes) and pressures can build-up in the ventricles to provide the required condition to allow circulation from a high pressure (systolic rigelmedical.com Innovating Together phase) to the lower pressure areas. A complete cycle of events is referred to as the cardiac cycle, a single heart beat and involves; 1. Atrial systole, 2. Ventricular systole and 3. Complete cardiac diastole. Cardiac muscles are electrically stimulated and the cardiac cycle is triggered by Sinoatrial Node (S.A. Node), then synchronized through timing (delays) (Atrioventricular A.V. Node and bundle of His) which ensures coordinated contraction and relaxation of the different heart muscles to allow the individual chambers to fill-up and empty. While the heart is self-exciting and able to maintain it’s own pace (S.A. Node), the heart rate can be altered due tometabolic demands (e.g. exercise, emotion, anxiety). During the cardiac diastolic phase, the heart relaxes and blood is able to fill the two atria. As the atria fill up to around 70%, the pressure in the atria releases the valves to the ventricles (tricuspid and mitral valve). The remaining 30% of blood volume in the atria is pumped out as the atria contract (atrial systole) at the start of the heart beat. The ventricles contract (ventricle systole) resulting in the blood flowing out of the heart through the main heart valves (aortic and pulmonary valves) into the pulmonary and systemic circulation. The number of circulations per minute (or beats per minute) can vary due to age, as a result of exercise, hormone levels (ie caused by anxiety or stress) and physical condition (related to cardiac output). The greater the need for oxygen by the body, the greater the need for oxyhemoglobin. A human heart has a certain capacity to circulate blood (cardiac output) therefore; oneway to increase blood supply is to increase heart rate. In general; ■ The smaller the cardiac output, the higher the heart rate. ■ The greater the cardiac output, the lower the heart rate. This is evident in infants and children, having a relatively small cardiac output, thus higher heart rate. Their resting heart rate can be between 100—150 bpm. In comparison, a trained athlete has been able to increase their cardiac output through build up of exercise. The resting heart rate can be as low as 40 bpm or even lower. Cardiac output is not classed as a vital sign and therefore not considered further in this booklet. 3 Blood pressure The most common vital sign parameter being monitored or measured is the (arterial) blood pressure. During the cardiac cycle, the ventricles contract (systole) and the blood pressure is at its highest (systolic) and during complete cardiac diastole, the blood pressure is at its lowest (diastolic) which enables the blood to circulate through the body through the systemic and pulmonary circulation. The blood flow and pressure change with each stage of the cardiac cycle and are reported in millimeters of mercury (mmHg). This is represented in figure 2. In a healthy patient, the average values for the different pressure variations are: ■ Systolic pressure ■ Diastolic pressure ■ Mean arterial pressure 120 mmHg 80 mmHg 90—93 mmHg 5 Figure 2: ECG waveform vs aortic pressure and plethymograph range from domestic use to comprehensive multi parameter monitors used in healthcare facilities. The principles of measuring NIBP can vary from: R R P T Q P S T Q S Systolic pressure Aortic pressure Diastolic pressure Ventricular pressure ■ Palpation method (feeling) — an indication of the minimum (systolic) blood pressure obtained through the touch/feel sensation at determined positions (radial, femoral, carotid) of the body. Palpation is often used in emergency and trauma cases where rapid detection of a present blood pressure is required or rapid loss of blood pressure is expected. Dicrotic notch SPO2 It is not uncommon to have deviations from these values which can be the result of for example; emotions, anxiety, drug-use, cardiac conditions, life style, fitness, age and diet. ■ Hypotension ■ Hypertension Blood pressure being abnormally lower than average Blood pressure being abnormally higher than average 3.1 Measuring blood pressure Blood pressure can be measured both noninvasively (NIBP) and invasively (IBP) and is associated with the pressure in the arterial blood vessels. While the invasive method (see 4) is more accurate, the non-invasive method (NIBP) is the most common. While invasive procedures require highly skilled people, the non-invasive method is relatively simple and can be done by both skilled and unskilled people. NIBP monitors 6 ■ Auscultatory method (listening) – as blood flow is interrupted (blocked by external cuff) and released (deflation of the cuff), sounds can be associated with the systolic and diastolic pressures. When a cuff is positioned around the upper arm and inflated to the point the artery is blocked (no blood flow), the cuff is then deflated. The pressure at which blood flow regains is the systolic pressure and is accompanied by a specific beating sound (referred to as first korotkoff sound) caused by turbulent blood flow in the artery. The pressure at which the sound stops (fifth korotkoff sound) is referred to as the diastolic pressure. Observation is done by listening through a stethoscope (or can be automated through microphone electronic pick-up), positioned directly on the elbow artery and the use of a calibrated manometer. (The mean arterial pressure is calculated from the systolic and diastolic pressures. There is no agreed standard but the formula below is often referred to: ■ Mean BP = 1⁄3* (systolic + 2 x diastolic) ■ Oscillometric method (measuring) – Unlike the auscultatory method, the oscillometric method measures the mean arterial pressure and calculates rigelmedical.com Innovating Together the systolic and diastolic pressures from pressure variations in the cuff when inflated (blocking the blood flow) and then deflated (blood flow regains). While the auscultatory method often relies on human interpretation (listening), the oscillometric method is done through automation and the use of electronic pressure sensors. Due to the use of electronic pressure transducers, regular calibrations are required and often advised by the manufacturer. 3.2 Testing your NIBP monitor As explained above, oscillometric NIBP monitors require regular performance verifications to ensure the correct operation. Common issues relating to the accuracy of the NIBP monitor are: ■ A leak in the cuff or pressure system, resulting in a lower blood pressure reading. ■ Acoustic variance of the cuff due to incorrect cuff volume, variety in materials used and positioning or applying cuff on patient. ■ Incorrect operation of the overpressure valve caused by a leak or complete malfunction. ■ Deviation in accuracy of the electronic pressure transducer caused by wear and tear of electronic components. ■ Changes in atmospheric pressure including pressure variations caused by closing doors/windows. A number of tests are provided to determine the correct operation of the NIBP monitors. These are: ■ ■ ■ ■ Pressure leak test (see 3.3.1) Over pressure valve test (see 3.3.2) Static pressure & linearity test (see 3.3.3) Dynamic pressure (see 3.3.4) 3.3 Test setup In the example below, the Rigel BP-SIM or UNISIM is used to reflect the NIBP simulator. Ensure the correct cuff size and positioning to reduce acoustic errors. An additional 500cc cylinder may also be used to provide a consistent reading. In order for the NIBP simulator to measure the pressure in the cuff and simulate into the NIBP monitor any pressure variations associated with the oscillometric method, the simulator must be inserted in (one of) the pressure tubes to the cuff as shown in the figure below. Figure 3: Test setup: Connecting the NIBP simulator SYS 120 mmHg DIA 80 mmHg HR 70 bpm UNI-SiM NIBP Monitor Cuff 3.3.1System pressure leak test The purpose of the pressure leak test is to verify and ensure the integrity of pressure system including the tubing and cuff. The leak test measures the pressure drop over time and must fall within acceptable values as documented by the supplier or manufacturer of the monitor and or cuffs. Often, the pressure drop is documented 7 as mmHg / min from a certain start pressure e.g. 200 mmHg. Refer to the service or maintenance instructions provided with the monitor as it may have to be set in service or calibration mode. For example: a manufacturer could specify a system leak test for a duration of three minutes where the expected total pressure drop must not exceed 15 mmHg. This is equal to 5 mmHg per minute. Some NIBP simulators like the Rigel UNI-SIM have a built-in pump to generate the required pressure levels. Inflate the pressure into the system and monitor the pressure drop and time. Figure 4 shows a sample screenshot from the Rigel UNI-SIM while performing the leak test. Figure 4: NIBP leak test on the Rigel UNI-SIM The purpose of the overpressure test is to determine whether the internal safety valve(s) are functioning correctly and release the internal pressure when it reaches the maximum allowable system pressure set by the monitor’s manufacturer. Refer to the service or maintenance instructions provided with the monitor as it may have to be set in service or calibration mode. For example: a manufacturer could specify the set-point of 300 mmHg as the maximum allowable system pressure for an adult setting and 150 mmHg for a pediatric setting (+/-10%). Some NIBP simulators like the Rigel UNI-SIM have a built-in pump to generate the required pressure levels. Inflate the pressure into the system until the monitor releases the overpressure valve, resulting in an almost instantaneous pressure drop. The inclusion of the original cuff or air reservoir of 500cc during this test is advised to provide consistency with the normal operation of the monitor. Figure 5 shows an example screen shot from the Rigel UNI-SIM displaying the set-point at which the pressure drop (valve release) occurred. Figure 5: NIBP pop-off test on the Rigel UNI-SIM Once the selected pressure is stabilized, the timer starts and the UNI-SIM will show real-time system pressure over time. 3.3.2 System overpressure valve test When dealing with pressure systems, it is important to ensure the system is able to vent when pressures reach a value exceeding the safety of the patient or operator and the correct functioning of the monitor itself. 8 rigelmedical.com Innovating Together In the example above, the test demonstrates that the valve was released at 331 mmHg. Figure 6: Dynamic pressure simulation settings on the Rigel UNI-SIM 3.3.3 Static pressure or linearity test The static pressure tests are useful for verifying the performance of the pressure transducer and verifying the integrity of tubing systems internal, external and cuff). In addition, the static pressure test can be used to test the accuracy over a range of pressures. Refer to the service or maintenance instructions provided with the monitor as it may have to be set in service or calibration mode. For example: A manufacturer could ask to perform a linearity test on the following static pressures: 250mmHg, 200mmHg, 150mmHg, 100mmHg, 50mmHg and 0mmHg. The reading values should be at +/-3mmHg from expected value. Some NIBP simulators like the Rigel UNI-SIM have a built-in pump to generate the required pressure levels. Inflate the pressure into the system (monitor with or without the cuff) and compare the reading from the monitor with that of the calibrated manometer (UNI-SIM). The inclusion of the original cuff or air reservoir of 500cc during this test is advised to provide consistency with the normal operation of the monitor. 3.3.4 Dynamic pressure Static testing is useful for verifying the performance of the pressure transducer but it does not prove the accuracy of the monitor under dynamic pressures. The performances of the computing algorithms that enable calculation of systolic, diastolic and mean blood pressures are tested in real conditions. Patient simulations — It maybe necessary to perform verifications using different patient settings for example; a low (hypotension), normal and high (hypertension) blood pressure; ■ Patient A : ■ Patient B : ■ Patient C : 80/40 Heart rate 80 120/80 Heart rate 80 180/140 Heart rate 80 Testing alarms – Most monitors are equipped with both audible and visual alarms. It is important to verify these alarms are working correctly. Refer to the monitor’s manual to understand the different alarm conditions. The simulator can be used to introduce certain conditions and arrhythmias that will trigger an alarm, subject to monitor and simulator features. Figure 6 shows an example screenshot from the Rigel UNI-SIM displaying the various dynamic pressure simulation settings available. 3.4 Considerations There are some physiological variations from one patient to another. Different patients have different arterial pulse shapes, arterial 9 compliance, flesh rigidity and other factors which simply make the BP cuff respond differently. The oscillometric signal is complex and changes not only in size but in shape in relation to the cuff pressure. Manufacturers of automated NIBP monitors are using different methods and aspects to determine the systolic and diastolic pressures. These methods and aspects can include: ■ Measuring the pulse size ■ Measuring the average pulse size ■ Determining the peak of the pulse size envelope ■ Measuring the average cuff pressure at a set point ■ Extracting data during cuff inflation or deflation All different methods and aspects will result in different readings on the same patient. As such, a single NIBP simulator will read different on a range of different makes of NIBP monitors. During a dynamic simulation, the NIBP monitor will inflate the cuff to a level above the expected systolic pressure. The NIBP simulator, such as the Rigel UNI-SIM is connected to the pressure system, and is able to measure the pressure drop in the cuff introduced by the monitor. When the system (cuff) pressure is above the systolic pressure, blood flow is unable to flow past the cuff. The pressure variations (oscillations) created by the simulator in the cuff are minimal and is the result of simulating the pulsating arterial blood against the cuff. As the pressure in the cuff drops, the simulator will simulate greater oscillations in the cuff, simulating 10 that blood flow is able to resume further along the artery (along the length of the cuff). When blood flow in the artery has been established across the full length of the cuff, the systolic pressure has been achieved although the monitor is not able to establish this at this time as the oscillations in the cuff continue to increase until the cuff pressure is equal to the mean arterial pressure. When the pressure drops below the mean arterial pressure, the oscillations from the simulator decrease again (simulating a reduced pressure on the artery). When the simulated oscillations reach a minimum, the monitor stops the deflation process and determines the systolic and diastolic pressures from the measured mean arterial blood pressure and or any of the aspects detailed above depending on the manufacturer. An example of the shape of the oscillometric wave form captured by the NIBP monitor is provided in figure 7. The deviation in NIBP simulation values compared to the values displayed on the monitor, varies between manufacturers of NIBP monitors and of NIBP simulators. Depending on shape of the simulated oscillometric waveform, each type of monitor might give a different interpretation of the systolic and diastolic values. Consistency in deviations is one way of ensuring that the monitor function hasn’t deteriorated though accurate simulation of the manufacturer’s oscillometric waveform will allow the verification of whether the correct components are being used (i.e. compatible or recommended cuffs and tubing), determine the accuracy of the calibration and accurately simulate alarm conditions. rigelmedical.com Innovating Together Figure 7: Oscillometric wave form To improve the accuracy of simulation, it is essential that the NIBP simulator can simulate manufacturer specific curves so the calculated data is taken from identical parts of the envelop. The Rigel UNI-SIM has the ability to create or upload manufacturer specific envelopes to ensure repeatable and accurate simulations. 4 Invasive blood pressure Arterial pressure can be monitored both invasively (IBP) and non-invasively (NIBP) as discussed in the previous chapter however, it must also be noted that the automated NIBP method can only provide an indirect and non-real time arterial pressure as it calculates pressures based on a typically 30 second cycle. When a greater accuracy or a real time arterial pressure is required e.g. when a patient’s blood pressure is expected to vary greatly during surgical procedures, it’s most common to use the invasive method. During an invasive blood pressure measurement, a liquid filled catheter is placed in the artery (radial, brachial, femoral or axillary). The arterial pressure is directly transferred to the liquid inside the catheter and tubing to the pressure transducer (non-invasive but external from the monitor). The pressure transducer converts the pressure to an electronic signal which is then connected to the monitor for further processing such as determining systolic and diastolic pressures. 4.1 Testing IBP function A number of tests are provided to determine the correct operation of the IBP monitors. These are: ■ Static pressure & linearity test (see 4.2.1) ■ Dynamic pressure (see 4.2.2) 4.2 Test setup The external pressure transducer produces a milli Volt (mV) signal. The IBP simulator will produce corresponding mV signals on the signal and excitation connections to the IBP monitor to simulate the external pressure transducer. 11 There are several types of connections depending on the monitor make and the sensitivity of the pressure transducer (mV/mmHg) will also vary by model. It is advised that the correct connections are made and tested prior to the simulations to avoid errors in the simulations. Start by setting the transducer sensitivity, typically 5µV/V/mmHg. Zero the system by simulating a zero pressure with the simulator and set up the zero value on the monitor (refer to the service or maintenance manual for instructions). In this example we connect the Rigel UNI-SIM to the IBP monitor and simulate dynamic pressure values. For example: A manufacturer could ask to perform a linearity test on the following static pressures: 250mmHg, 200mmHg, 150mmHg, 100mmHg, 50mmHg and 0mmHg. The reading values should be within +/-3mmHg from expected value. Figure 8: Test setup: Connecting the IBP simulator Once the zero is established, a number of different pressure values can be simulated. Record whether the alarm on the monitor occurs at the set value(s) and whether the alarm(s) is at the correct pitch and frequency (refer to the instruction manual). SYS 120 mmHg DIA 80 mmHg HR 70 bpm UNI-SiM IBP Monitor 4.2.1 Static pressure or linearity test (verify alarm testing) The static pressure tests are useful for verifying the performance of the pressure transducer. A linearity test can be done similar to that during the NIBP simulations, in order to verify the accuracy of the IBP monitor over a pressure range. 12 4.2.2 Dynamic pressure The accuracy of the pressure transducer can also be verified using a dynamic pressure simulation. The performance of the computing algorithms that enable calculation of systolic, diastolic and mean blood pressures are tested in real conditions. Patient simulations — It may be necessary to perform verifications using different patient settings for example; a low (hypotension), normal and high (hypertension) blood pressure; ■ Patient A : 80/40 heart rate 80 ■ Patient B : 120/80 heart rate 80 ■ Patient C : 180/140 heart rate 80 Testing alarms – Most monitors are equipped with both audible and visual alarms. It is rigelmedical.com Innovating Together important to verify these alarms are working correctly. Refer to the monitor’s manual to understand the different alarm conditions. 5 Pulse oxymetry If we consider the heart as the engine of the respiratory system (see chapter 2) and the lungs as the carburetor, oxygenated blood can be considered the fuel whereby the level of oxygen can be directly related to the potential capacity in the blood (or octane level in fuel 95—98% being a typical value). Oxygen is absorbed by the blood as it passes through the lungs, as oxygen sticks to the hemoglobin protein in the red blood cells. The quantity of oxygen absorbed (oxyhemoglobin) is a sign of the respiratory system’s vitality (performance), hence it is one of the most common monitored vital signs. Displayed in percentage oxyhemoglobin (SaO2, a direct measurement) in relation to hemoglobin, pulse oximeters can provide a real-time indication of the total oxygen saturation (SpO2) in the blood. To establish an indication of the oxygen saturation, the pulse oximeter relies on the different light absorption characteristics of oxyhemoglobin and hemoglobin at different spectrums of light. Using a red (650—700 nm) and infrared (850—950 nm) spectrum light source, a pulse oximeter can determine the oxygen concentration by measuring the difference between the red and infrared light being absorbed by the arterial blood. To do so, a finger probe (or ear probe) is placed on the finger. A red and infrared spectrum LED is driven by the monitor at consecutive intervals of typically 0.2 ms (5kHz). On the opposite side of the finger probe, a broadband receiver converts the unabsorbed red and infrared light signals into electrical signals. Other types of probes (i.e. foot probes) or techniques are available such as a reflective method used on the forehead. These however, are not part of this booklet although the principles are similar. Figure 9: The finger probe pulse oximeter Red LED Infrared LED SPO2 Photo Detector The red light is absorbed more in relation to infrared light when passing through hemoglobin (Hb, deoxygenated blood cells) whilst infrared light is absorbed more by oxyhemoglobin (HbO2 , oxygenated blood cells). The ratio at which the light is being received can therefore provide an indication of the level of oxygen concentration: In principle, this translates to: ■ Less infrared than red light being received: higher concentration of oxyhemoglobin (HbO2 ) ■ Less red than infrared light being received: lower concentration of oxyhemoglobin (Hb) A simplified representation of the absorption properties of hemoglobin and oxyhemoglobin is provided in figure 10. Note that this is not suitable for clinical use. 13 Figure 10: Absorption properties of hemoglobin and oxyhemoglobin. Figure 11: An example plethysmograph vs ECG waveform R Extinction Coefficient 10.0 Methemoglobin 1.0 P T P Oxyhemoglobin Q S 0.1 Reduced hemoglobin 0.01 600 640 680 720 760 800 840 600 920 960 Dicrotic notch 1000 Wavelength (nm) The red line shows the fully oxygenated hemoglobin (HbO2 - 100% SpO2) while the blue line shows the fully deoxygenated hemoglobin (Hb - 0% SpO2). At around 800nm wavelength the absorption is equal for both HbO2 and Hb, this is referred to as the isosbestic point (803nm) Typical ratio values are: ■ 100% SpO2 R/IR approximate ratio of 0.5 ■ 82% SpO2 R/IR approximate ratio of 1.0 ■ 0% SpO2 R/IR approximate ratio of 2.0 Different manufacturers use different wavelengths (within the described spectrum) and have different absorption look-up tables. This is referred to as the R-curves for each manufacturer. 5.1 Artifacts It is important to realize that light is passing through different types of tissue (skin, muscle, bone), cells and vessels (arterial and venous). Therefore, to determine the amount of arterial oxyhemoglobin, the monitor will look at the “pulsating” light absorption waveform, the so called plethysmograph (see figure 11). 14 As the heart pumps the blood through the lungs, the level of oxyhemoglobin is “restored” (typically 5% of oxygen in lungs) at every systolic cycle after which it will be absorbed at the capillaries (typically around 40%) until the next systolic cycle. At the peak of the plethysmograph, the monitor measures the total light absorption (arterial and other cells, tissues, venous vessels) while at the troughs, the monitor measures all but the arterial absorption (all remaining cells and tissues). By subtracting peak from the trough, the monitor is able to determine the arterial oxyhemoglobin, the value for SpO2. See figure 12. rigelmedical.com Innovating Together Figure 12: Light absorption in the red spectrum Transmitter RED 660nm Light Signal Max is normally called IDC Light Signal Max absorption due tobone, skin and other tissues and pigment INCIDENT LIGHT Light Signal Min is normally called IDC + AC Transmitter RED 660nm absorption due to MetHb absorption due to COHb Light Signal Max Hb02: DC absorption Hb: DC absorption Light Signal Max remaining light Reciever The monitor will therefore only respond to peak values in a pulsating plethysmograph. The measurement process within pulse oximetry can be affected by motion and low perfusion (peak to trough value less than 5%). Motion introduces varying levels of oxyhemoglobin which might introduce incorrect readings (heart rate and SpO2 %) where as low perfusion can introduce higher inaccuracy due to noise signal ratio. External light sources may also introduce errors when they contain red and infrared spectrum light. These light sources could introduce a stable amount of light (DC or non pulsating) or a pulsating amount (AC) at frequencies of 50, 60Hz or their harmonics. Monitors must therefore be able to differentiate between a normal plethysmograph and one with artifacts. Sp02 = 80% Reciever Sp02 = 100% Modern technologies in pulse oximeters are able to differentiate and provide accurate readings during low perfusion, motion and light artifacts however, it is suggested that the performance under such conditions is verified on a regular basis. Recent developments in pulse oximetry see the use of additional light spectrums to obtain more detailed information on the exact content of the arterial blood including methemoglobin (MetHb) and carboxyhemoglobin (COHb). 5.2 Testing your SPO2 monitor – Pulse oximeter Most pulse oximeters on the market are capable of measuring under extreme conditions (artifacts, low perfusion). In order to establish the correct operation under these conditions, it is important to verify both the performance of the monitor as well as the SpO2 probe and its connection cables. 15 All parts of the SpO2 probe (LED’s, broad band detector, lens and cabling) are subject to wear and tear and when faulty (or in poor quality) might introduce inconsistent and inaccurate performance with potentially serious implications on the treatment of well-being of patients. For this reason, we include both the monitor and the SpO2 probe when discussing the testing procedures for pulse oximetry. Common issues relating to the accuracy of the SpO2 monitor are: ■ ■ ■ ■ ■ ■ ■ Faulty (near faulty) LED’s (red and infrared) Non-OEM probes (white label) Contaminated lens / probe window Damaged wiring or extension cable Inaccurate calibration of SpO2 monitor Testing of audible alarms Display of plethysmograph A number of tests are provided to determine the correct operation of the SpO2 monitors. These are: ■ Testing ■ Testing ■ Testing ■ Testing monitor accuracy (see 5.3.1) alarms and response time (see 5.3.2) under low perfusion (see 5.3.3) probe quality (see 5.3.4) 5.3 Test setup In the example below, the Rigel SP-SIM or UNISIM is used to represent the SpO2 simulator. Ensure the correct adaptor module is provided during the test as connector shape and pin-out configuration differ between different makes of SpO2 probes and monitors. 16 Figure 13: Test setup: Connecting the SPO2 simulator (opto-electronic method) SPO2 98% HR 70 bpm Probe Interface SPO2 UNI-SiM SpO2 Probe SpO2 Monitor 5.3.1 Testing monitor accuracy The purpose of this test is to verify the performance of the monitor measurement circuits and SpO2 probe characteristics by simply displaying the SpO2% value and heart rate on the monitor. To simulate the heart rate, the UNI-SIM simulates the (pulsating) plethysmograph at rates of 30 to 300 beats per minute (bpm). Simulated saturation levels can be set between 50 and 100%. In order to verify a range of possible measurements, some simulations can be performed across a number of critical values (see alarm testing) as example: normal, low and critical. In addition, artifacts (light, motion and arrhythmia’s) can be introduced to test the performance of SpO2 monitors either for evaluation, acceptance and as part of preventative maintenance. Note that the precision of pulse oximeters can vary greatly between brands but typically does not exceed +/-2%. rigelmedical.com Innovating Together 5.3.2 Alarms and time response test Use the different values of SpO2 simulation to trigger audible alarms. Alarms of medical devices are specified by the IEC 60601 standard and must be documented by the manufacturer, such as pitch, frequency and strength. Consult the monitor’s service or instruction manual for details on the types of alarms available. In addition, the SpO2 value is updated at set intervals e.g. every 15 seconds. The set response time can be verified using the chronometer function in the UNI-SIM. The response time and alarm function can be combined in a single test setup i.e. by setting the SpO2 value to 94% with a target of 85%. Wait for the SpO2 monitor to display the 94% SpO2. Activate the chronometer function on the UNISIM. This will change the simulation to 85% SpO2 and starts the timer. When the monitor reaches the alarm (i.e. when set to 85% SpO2), press the capture button on the UNI-SIM to display the time taken to alarm. Record whether the alarm on the monitor occurs at the set value(s) and whether the alarm(s) is at the correct pitch and frequency (refer to the instruction manual). 5.3.3 Sensitivity test To determine whether the SpO2 monitor is able to measure accurately under different pulse volumes, e.g. as a result of different types of patients (normal adult, obese, pediatric, skin color variation), the UNI-SIM can be used to simulate a variety of pulse volumes and skin colors. Using the SpO2 simulator, the pulse volume can be reduced until the monitor displays “no SpO2 signal”. The value before this point highlights the minimum sensitivity of the monitor. It is important to realize that the quality of the probe can affect the outcome of this test as non-original probes might have poorer quality components and have less sensitivity compared to the original probes (OEM). Record the sensitivity value over time to monitor the performance of the oximeter. 5.3.4 Testing the SPO2 probe The SpO2 sensor is often the weakest link in the chain of SpO2 measurement. Probes are considered consumables as they suffer significant wear and tear thus are easily replaceable.To test the functionality of the probe it is important to realize the different parts that make up the probe and connections: 1. Red LED 2. Infrared LED 3. Broadband detector 4. Lens 5. Cabling 6. Connector 7. Extension cable (where applicable) The quality or function of the LED’s will deteriorate over time. To test the accuracy, the UNI-SIM is able to simulate through the red and infrared circuit individually. This will allow for comparison between the two circuits as the reading on the monitor should be within 1% of each other. When one of the LED’s has deteriorated, the readings will differentiate by more than 2% of SpO2 value. Replace the probe and repeat the test again to ensure the new probe is as expected. 17 When testing the probe, always ensure that the cable and extension leads are flexed during the tests so that open or short circuits cause an alarm or a “no reading” on the monitor. Suggestion: Always record the findings on each type of SpO2 probe to build-up an expected performance reference list (perfusion, Delta R / IR reading). This will help in identifying poor or (near) faulty SpO2 probes in the future. Consideration: Some simulators on the market might make use of an optical finger, capturing the signals from the SpO2 probe and changing the characteristics before converting them back to red and infrared signals. The advantage would be the elimination of probe adaptor boxes however, the disadvantages are significant; Red – Infrared light / blood absorption characteristics have a strong and direct link with the wave length used (LED spectrum). An optical finger may use different wave length or single LED compared to the manufacturer (OEM). This could result in inaccurate readings. Probe placement will also affect the result and as such can be influenced thus not able to form an accurate reference value. 6 Electrocardiographs (ECG) The heart, central in the respiratory system, converts bio-electric pulses to a bio- mechanical operation (blood flow). The function of the heart 18 is monitored by measuring the electrical activity (milli-volt signals) generated in the heart and is referred to as Electrocardiography. The most common ECG tracing of a cardiac cycle (heart beat) is represented below and consists of a P wave, the QRS complex and a T wave. The typical duration of the electrical activity is usually around 400-600 ms. The ECG trace represents the change in voltage across different parts of the body (limbs) because of depolarization (contracting or systole) and repolarisation (relaxing or diastole) in the heart muscles. The baseline voltage of the ECG is referred to as the isoelectric line. Figure 14: An example of an ECG trace QRS R appr. 1-2mV Other forms of problems associated with the quality of the SpO2 LED’s are a deterioration of the perfusion sensitivity (see 5.3.3). This could be due to quality of the LED’s, broadband detector or the lens (contamination or cuts). T P isoelectric line S Q PR 100-200 QT 300-400 400-600 1. The P wave is generated during the atrial depolarization. 2. Following this, the right and left ventricles are depolarized, generating the QRS complex. 3. During the T wave, the ventricles re-polarize. 4. During the latter part of the T wave, the human heart is most vulnerable against disturbance or fibrillation. rigelmedical.com Innovating Together 6.1 Einthoven Triangle As a result of the body’s natural impedance, the electrical activity results in different potentials across the body. One of the most referred to means of measuring the electrical potentials is by positioning electrodes (limb leads) on the patient in a triangular shape, the einthoven triangle, placed on the left leg (LL), right arm (RA) and left arm (LA). The ECG waveform, (PQRST) can now be determined at various locations of the body, to specifically highlight anomalies in a specific part of the waveform. These can be directly related to the performance of the atrium and ventricle muscles. Figure 16: A typical waveform (Lead I) and the derived shapes (Lead II and III) These limbs can also be referred to as: Left leg (LL) Right arm (RA) Left arm (LA) Right leg (RL) = = = = Left foot or foot (F) Right (R) Left (L) Neutral (N) This is represented in the diagram below: l Figure 15: The Einthoven triangle R _ L + _ l _ + N Using vectors, Lead I, II and III can be separated into Augmented limb leads whereby the potential is measured from one (positive) of the three positions on the Einthoven triangle and the combined other two (negative) as shown in figure 17 on the following page. + F Lead (+) positive (-) negative I LA RA II LL RA III LL LA V1= ΦLA-ΦRA Potential V2= ΦLL-ΦRA V3= ΦLL-ΦLA Whereby you can calculate that Lead I + Lead III = Lead 2 (Kirchhoff’s law) (ΦLA-ΦRA)+(ΦLL-ΦLA)=ΦLL-ΦRA 19 Figure 17: Augmented limb leads R Lead aVL aVF aVR L 5 KΩ 5 KΩ aV L 5 KΩ R The precordial leads (V1,V2,V3,V4,V5 and V6) are placed in close proximity to the heart to ensure sufficient signal strength and accuracy. L Placements of the leads are in accordance with figure 18 below. aV F Figure 18: Precordial lead placement For figure 18 use IEC Code 1 for lead identification, not those shown, including the chest leads which should be C1 – C6 not ‘Y’. F R R (RA) + F (LL) L(LA) + (RA) L(LA) + F(LL) 6.2 Precordial leads When a more detailed electrocardiogram is required, additional leads, the precordial leads, are placed on the chest. The different lead configurations will allow diagnosis of numerous heart conditions by studying relative amplitudes, heart rates and uniformity across the different leads. F 5 KΩ + L (LA) F(LL) R(RA) L L R 5 KΩ C2 C1 C3 C4 F 5 KΩ N F aVR 20 C5 C6 rigelmedical.com Innovating Together Figure 19: Example of a 12 lead ECG 12-Lead 2 hhh PR0.138s QT/QTc Sex: P-QRS-Axes aVR Name: ID: Patient ID Incident: Age: 26 HR 62 bpm oo Normal ECG **Unconfirmed** 14:37:18 Normal sinus rhythm QRS 0:112s 0.390s/0.395s 27 o 80 o 49o lv1 lv4 l aVL lv2 lv5 l aVF lv3 lv6 x1.0 .05-150Hz 25mm/sec 6.3 Unipolar vs. bipolar leads ECG leads are split between unipolar and bipolar leads. The limb leads (I, II and III) are bipolar, having both a positive and negative pole. The augmented leads (aVL, aVF and aVR) and precordial leads (V1-6) are considered unipolar, having only a true positive pole. The negative pole consists of signals from other poles. 6.4 Color coding ECG leads are marked with both abbreviations and color coding according to the corresponding placement on the body. There are 2 common markings available on the market today. These are shown in the table below. Table 1: ECG Abbreviations and color coding Elecrode Right Arm Left Arm Right Leg Left Leg Chest 1 Chest 2 Chest 3 Chest 4 Chest 5 Chest 6 IEC Code 1 Abbreviation R L N F C1 C2 C3 C4 C5 C6 Colour Red Yellow Black Green White/Red White/Yellow White/Green White/Brown White/Black White/Violet ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ IEC Code 2 (American) Abbreviation Colour RA White LA Black RL Green LL Red V1 Brown/Red V2 Brown/Yellow V3 Brown/Green V4 Brown/Blue V5 Brown/Orange V6 Brown/Violet ❑ ■ ■ ■ ■ ■ ■ ■ ■ ■ 21 6.5 The ECG Machine To observe an ECG, the difference between two electrical signals at different points on the body must be amplified. Then the electrical potentials can be displayed on the screen. ECG machines may typically use 3 lead, 5 lead or 12 lead configurations. Placement of the ECG leads is standardized so that the interpretation of the ECG is consistent. Cardiac conditions that can be diagnosed using ECG’s include abnormally fast heart rate (tachycardia), abnormally slow rate (bradychardia), heart block, acute myocardial infraction (a blood clot in the heart), ischemia (a restriction in the blood supply to a part of the heart) and numerous other conditions. These conditions come under the generic term of heart arrhythmias. Figure 20: Patient on ECG recorder Therefore, the following simulations and performance tests are often part of the regular maintenance: ■ ■ ■ ■ ■ ■ ■ ■ ■ Linearity of heart rate measurement QRS Beep Alarms (high and low) Alarms for disconnected electrodes Arrhythmias recognition (asystolic) Sensibility test Zero offset Frequency response Printer calibration (amplitude, timing) The most common instrument used for the above is a patient or ECG simulator. In the example below, the patient simulator from the UNI-SIM is used; Figure 21: Test setup: Connecting the ECG simulator ECG Interface 5 4 HR 70 BPM UNI-SiM ECG Recorder 6.6 Testing ECG monitor Due to the important analyzing role of the ECG monitor, it is crucial to ensure that the input 22 ! 1V 3 RL 2 V6 LL 1 V5 LA 10 V4 RA 9 V3 8 V2 7 6 ECG circuits of the ECG monitor are able to measure the small ECG signals accurately. That the software is able to interpret these signals to the corresponding conditions and that alarms are visible and audible according to the manufacturers specifications. rigelmedical.com Innovating Together 6.6.1 Linearity of heart rate measurement The purpose of this test is to verify the capability of the monitor to measure and display heart rate accurately. It is recommended to simulate several values in range spanning 30-300 beats per minute (bpm). Compare the readings with the simulated values and check whether this is within manufacturer specifications (normally +/- 1 bpm or +/- 1% of reading). 6.6.2 QRS beep To aid the monitoring process, it is a requirement to fit the ECG monitor with an audible QRS beep. This provides a clear “beep” each time the QRS wave passes. Frequency and pitch variations can provide a clear indication of the heart rate without having to have line of sight to the ECG recorder. 6.6.3 Alarms (high and low) IEC 60601-1-8 provides the requirements for alarms on medical devices. Alarms can vary in frequency, pitch, volume and melody. In general, the greater the urgency, the higher the pitch, volume and pulse frequency (or melody). During the performance test of the ECG recorder, alarms can be tested by simulating different heart rates and arrhythmias using a patient simulator. At the end of the test, the final alarm condition can be tested by disconnecting the leads one by one. The monitor should go into alarm condition when this happens. Record whether the alarm on the monitor occurs at the set value(s) and whether the alarm(s) is at the correct pitch and frequency (refer to the instruction manual). 6.6.4 Arrhythmias recognition (asystolic) ECG monitors, which are able to interpret the ECG recording, are required to provide an alarm when they detect a seizure in blood circulation (or lack of pulse). This is the case during ventricular fibrillation and asystole (flat line) when no electrical nor mechanical activity is present in the heart. Ventricular fibrillation is a condition whereby the ventricles contract erratically with the net result of poor to no blood circulation from the ventricles to the body. During coarse VFIB, the waveform amplitudes are significantly larger than during fine VFIB. The latter is close to an asystole. All cases of VFIB lead to rapid loss of consciousness in the patient and must be treated immediately with the use of a defibrillator. 6.6.5 Sensitivity test (gain) To ensure the input circuits of the ECG recorder are sensitive enough to measure the ECG mV signals, the input amplifier settings are tested by supplying a normal sinus rhythm (NSR) at (e.g.) 60 bpm and with a 1mV amplitude. When the NSR is displayed on the screen, change the gain of the monitor and check if the changes in amplitude are relative to the gain change i.e. a doubling in gain would result in a doubling of amplitude. The heart rate should not be affected. Some ECG recorders are supplied with a printer and can allow for gain and amplitude settings to be easily crossed referenced. 6.6.6 Zero offset The zero offset test demonstrates the aligning of the isoelectric line of the ECG wave form with the zero line of the ECG recorder. This is achieved by checking whether the ECG line (flat line on the 23 recorder) is at zero mV when no leads are connected. When the recorder is equipped (usually) with a printer, the printed line shall be at zero mVolt. 6.6.7 Frequency response To limit the sensitivity of the ECG recorder from external signals i.e. mains frequency and other artifacts, the input circuits are equipped (usually) with filters. So called high pass filters – HPF’s (allowing signals of greater frequency to pass through) and low pass filters – LPF’s (allowing frequencies of lower frequencies to pass through) provide a bandwidth of allowable frequencies. Typical values are 0.5Hz / 1 Hz for HPF’s and 40 Hz for LPF’s inmonitormode and 0.05 Hz for HPF and 40 / 100 / 150 Hz for LPF’s in diagnostic mode. These filter settings can be selected based upon the application. To test the settings of the filters, performance wave forms such as a sinus of triangular waveform can be simulated to the ECG recorder. By varying the frequency in-and outside the bandwidth, the performance can be verified. 6.6.8 Printer calibration (amplitude, timing) ECG recorders with build-in printer facility are required to be tested for linearity of the printer speed. Printer rolls typically move at 25 mm / seconds. To test printer speed and linearity, a fixed frequency sinusoidal wave can be simulated. This should result in a consistent wave length width across the print out and must correspond to the print speed. ECG recording paper consists of a matrix of squares each 1mm x 1mm. At a speed of 25mm/s and a sensitivity of 10mm/mV each square represents 0.04s and 0.1mV respectively. 24 A signal with an amplitude of 1 mV and frequency of 1 Hz should have an amplitude of 10 mm and wave length of 25 mm. Figure 22: A sinusoidal test signal of 1Hz and 1mV amplitude 1 mV 1s 0 1mV -1mV 7 Respiration Unless a human is subject to mechanical ventilation, inspiration of the lungs is controlled by the increase in volume of the thoracic cavity. The thoracic cavity volume is increased as a result of (Involuntary) contraction of the diaphragm (layer between lungs and abdominal cavity). In addition to the diaphragm, the intercostal muscles also aid the breathing process by lifting the lower and upper ribs. Expiration of the lungs is a result of the elasticity of the lungs, forcing air out when the diaphragm and intercostals muscles relax. When a patient is under general anaesthetic, he/she might no longer be able to sustain the involuntary control of the diaphragm and intercostals muscles. A mechanical ventilator is then required to deliver a set volume per breath rigelmedical.com Innovating Together and respiratory rate (breaths per minute). Monitoring the respiration rate on patients subject to anesthesia is vital as it provides immediate warning of changes to the respiration rate including obstruction of the trachea (airpipe). An obstruction in the trachea stops the oxygen supply to the lungs and stops the expiring of carbon dioxide from the blood which can lead to a cardiac arrest and subsequent death if untreated e.g. removing the obstruction via an endotrachea tube). Figure 23: Respiration through limb and augmented leads L R C2 C1 C3 C4 There are several ways of deriving respiration rate from the ECG leads and signals. C5 C6 N F 1. Most commonly used, is the measurement of the transthoracic impedance between the ECG leads ie Lead I, II or III. As the thoracic cavity expands (inspiration), the impedance of the chest increases. While during expiration, the thoracic cavity reduces in volume thus decreasing its impedance. L R C2 C1 C3 2. Another method of determining the respiration is through observing the change in the ECG amplitude (ECG Derived Respiration – EDR) as a result of changes in the position between electrodes and heart as the chest cavity expands and the heart moves as a result of changes in the position of the diaphragm. This method can be visualized on a recorded ECG. 3. A third method to establish the respiration rate is by observing the changes in R-R intervals. (time between the R-peaks of two successive QRS waves). C4 C5 C6 N F In all instances, the ECG leads are placed on a human chest as shown above. Respiration rates can be monitored through all limb and augmented leads. Most monitors and recorders allow a selection of leads. 25 7.1 Testing respiration function The most common method of monitoring respiration at bedside is through impedance measurement across the ECG leads. The tests to perform on such monitor are: ■ Linearity of respiration measurement ■ Sleep apnea ■ Alarms (high and low) Figure 24: Test setup: Connecting the respiration / ECG simulator While sleep apnea can be monitored indifferent ways (CO2 monitoring, SpO2 etc), its most commonly monitored through the respiration rate on bedside monitors via ECG leads. Sleep apnea will appear as an absence in breath rate (breath rate = 0) and a respiration monitor should sound an alarm when sleep apnea is detected. ! 5 4 1V 3 RL 2 V6 LL 1 V5 LA 10 V4 RA 9 V3 8 V2 7 6 ECG Interface the blood. As a result, the level of carbon dioxide increases in the blood (level of oxyhemoglobin drops) as it is not able to pass out through the lungs and no new oxyhemoglobin enter the blood stream. While this is not a direct health risk as the brain will signal a wake-up, when left untreated, it can lead to more serious conditions such as high blood pressure and heart failure. RESP 15 bpm UNI-SiM ECG Recorder 7.1.1 Linearity of respiration measurement The purpose of this test is to verify the capability of the monitor to measure and display respiration rate values. It is recommended to simulate several values across a range rates from 100 bpm down to (sleep) apnea (see 7.1.2). Check the specification of the monitor to verify the readings are within the required accuracy. Typical accuracies are within +/- 1bpm. 7.1.2 Sleep apnea During our sleep, our airways can become obstructed, preventing oxygen to reach the lungs and stopping the expiring of carbon dioxide from 26 7.1.3 Testing apnea alarms In order to act swiftly to a deteriorating condition of the patient, respiration monitors are supplied with alarms to indicate a unacceptable change in respiration rate (too high, too low or apnea). Using a patient simulator, normal (e.g. 15 breath per minute — bpm), low (e.g. 5 bpm), high (e.g. 30 bpm) and apnea (0 bpm) can be simulated. Depending on the application of the monitor (i.e. adult or pediatric monitoring), the range of values could vary due to natural change in respiration rate in infants (higher) and adults (lower) or when testing monitors used for exercise stress testing (>30 bpm). Record whether the alarm on the monitor occurs at the set value(s) and whether the alarm(s) is at the correct pitch and frequency (refer to the instruction manual). rigelmedical.com Innovating Together 8 Temperature One of the most commonly monitored vital signs is the body temperature. Several devices have been marketed over the years from contact based temperature measurement such as the mercury filled thermometers (no longer available due to the toxic nature of mercury) and resistor based sensors to non-contact infrared based temperature sensors. Our core body temperature (Tc) varies by gender and can vary between different stages of the day. In women, the core body temperature also changes during the menstrual cycle, peaking at the time of ovulation. The average core body temperature is 37°C ± 0.5°C. Depending on the placement, application and method, different temperature readings are expected in healthy individuals as shown in table 2 on the following page. The most common temperature sensors used on bedside monitoring are electrical temperature sensors based on a temperature related varying resistor (thermistors). These thermistors are commonly known as NTC’s (negative temperature coefficient – meaning that that the resistance decreases when temperature increases) and PTC’s (positive temperature coefficient – meaning that the resistance is increasing as temperature increases). The YSI 400 and YSI 700 have become the standard NTC’s used in the medical industry. While the YSI 400 is slightly more accurate over the range of 0-75ºC, the YSI 700, which contains a dual element (Ra = 6kΩ @ 25ºC and Rb = 30kΩ @ 25ºC), is able to provide it’s accuracy over a wider range (-25ºC to 100ºC). Body temperature is simulated by the different resistor values corresponding to the required temperature. Please see table 3 on the following page. 8.1 Testing temperature function on multiparametric monitors We have the following performance tests : ■ Linearity of temperature measurement ■ Alarms (high and low) Ensure the correct temperature sensor (YSI400 or 700) on the patient simulator is selected. Figure 25: Test setup: Connecting the temperature simulator T1 37 oC T2 25 oC YSI 400 UNI-SiM Temperature Monitor 8.1.1 Linearity of temperature measurement The purpose of this test is to verify the linearity of the monitor over the most typical range of temperatures such as body normal, fever (high), hypothermia (low) and room temperature. A patient simulator is often able to simulate across this range between 25-41°C. Check the specification of the monitor to verify the readings are within the required accuracy. 27 Table 2: Different temperature reading methods Placement Application Method Accuracy Ear (Tympanic) Non-invasive contact and non-contact Core temperature (Tc) Rectally Invasive contact Core temperature (Tc) Orally Invasive contact 0.3 to 0.6˚C < Tc Armpit (Axillary) Non-invasive contact 0.6 to 1.2˚C < Tc Skin temperature Non-invasive contact and non-contact Depending on direct environment Table 3: Resistor values on YSI 400 and 700 sensors (Body) temperature Resistor Value 41˚C 37˚C 33˚C 25˚C (room) YSI 700 (a) 3,070 Ω 3,610 Ω 4,260 Ω 6,000 Ω YSI 400 1,152 Ω 1,355 Ω 1,599 Ω 2,252 Ω YSI 700 (b) 15,520 Ω 18,210 Ω 21,430 Ω 30,000 Ω A more detailed range of resistor values vs temperature is provided in Appendix C. 8.1.2 Testing temperature alarms In order to act swiftly to a deteriorating condition of the patient, temperature monitors are supplied with alarms to indicate an acceptable change in core or skin temperature. (too high or too low). Using a patient simulator, normal (37°C), low (33°C), high (41°C ) and room (25°C) temperature may be simulated. Record whether the alarm on the monitor occurs at the set value(s) and whether the alarm(s) is at the correct pitch and frequency (refer to the instruction manual). 9 Record keeping Overall, the area of risk assessment and the creation of risk management files has become a growing feature of routine safety and performance testing decisions, with different organizations and 28 departments drawing-up individual plans to deal with specific safety hazards. Comparison with previous and expected test results will therefore allow you to monitor deterioration of the device under test and prevent potential failure before a fault occurs. To ensure proper record keeping is maintained it is important to provide a procedure in which data is collected regarding: ■ ■ ■ ■ ■ Inspection date Visual inspection Electrical safety Functional testing Next inspection date Rigel Medical have developed Med-eBase, a software package to automate the generation of test reports including visual inspection, electrical safety and performance testing. An example of such test template is provided in Appendix D. rigelmedical.com Innovating Together Going forward, determining the appropriate levels of both electrical and functional testing will be central to the introduction of cost effective yet reliable preventative maintenance campaigns. Conclusion Planned preventative maintenance is an important aspect during the useful life of a medical electronic device. To ensure safety of the patient and operator, procedures are required to cover: ■ ■ ■ ■ Visual inspection Electrical safety testing (see IEC 62353) Performance or functional testing Record keeping This booklet has provided a basic introduction to vital signs monitoring and suggested test procedures for each vital sign. Always ensure that the function and operation of the DUT is understood before commencing on the planned preventative maintenance. Without fully understanding the function and or operation, visual inspections, electrical safety tests and functional tests might be incorrect or incomplete. Prior to any testing, ensure that the manufacturer’s recommendations are available as they often supersede any general inspection guidelines. 2. Always ensure that the DUT does not pose any danger to the user and / or people within the vicinity to the safety test. (e.g. moving parts, open conductors, live components, heat etc). 3. Ensure that manufacturer’s instructions are followed and any performance is checked against manufacturer’s documentation. 4. Ensure high accuracy and repeatability of simulations and measurement readings (some manufacturers might specify full scale accuracy which will effect the accuracy of low value readings or measurements). 5. When determining the correct means of testing a specific medical device, ensure that the chosen test procedures are applicable to the DUT and are clearly documented for future use. Rigel Medical offers a range of test equipment to cover simulation and performance testing as well as a range of electrical safety analyzers to meet the IEC 62353 and IEC 60601 requirements. Please visit our website www.rigelmedical.com for a full overview of our product offering or register online for our free newsletter on future product releases and product innovations. For further questions or comments relating to this booklet or on the Rigel Medical product offering, please contact John Backes via email at johnb@rigelmedical.com Considerations and recommendations 1. Ensure that the operator of test equipment is properly trained on both the test equipment and DUT to ensure that valid measurements are taken and understood and prevent unnecessary danger during the safety test. 29 Appendix A IEC 60601-1 Collateral Standards (© IEC Geneva, Switzerland) 30 IEC 60601-1-1 MEDICAL ELECTRICAL EQUIPMENT – PART 1: GENERAL REQUIREMENTS FOR SAFETY 1: COLLATERAL STANDARD: SAFETY REQUIREMENTS FOR MEDICAL ELECTRICAL SYSTEMS IEC 60601-1-2 (ACDV) MEDICAL ELECTRICAL EQUIPMENT - PART 1-2: GENERAL REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE - COLLATERAL STANDARD: ELECTROMAGNETIC PHENOMENA REQUIREMENTS AND TESTS IEC 60601-1-3 MEDICAL ELECTRICAL EQUIPMENT – PART 1: GENERAL REQUIREMENTS FOR SAFETY – COLLATERAL STANDARD: GENERAL REQUIREMENTS FOR RADIATION PROTECTION IN DIAGNOSTIC X-RAY EQUIPMENT IEC 60601-1-4 MEDICAL ELECTRICAL EQUIPMENT: PART 1-4: GENERAL REQUIREMENTS FOR COLLATERAL STANDARD: PROGRAMMABLE ELECTRICAL MEDICAL SYSTEMS IEC 60601-1-6 MEDICAL ELECTRICAL EQUIPMENT - PART 1-6: GENERAL REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE - COLLATERAL STANDARD: USABILITY IEC 60601-1-8 (CCDV) MEDICAL ELECTRICAL EQUIPMENT - PART 1-8: GENERAL REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE - COLLATERAL STANDARD: GENERAL REQUIREMENTS, TESTS AND GUIDANCE FOR ALARM SYSTEMS IN MEDICAL ELECTRICAL EQUIPMENT AND MEDICAL ELECTRICAL SYSTEMS IEC 60601-1-9 MEDICAL ELECTRICAL EQUIPMENT - PART 1-9: GENERAL REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE - COLLATERAL STANDARD: REQUIREMENTS FOR ENVIRONMENTALLY CONSCIOUS DESIGN IEC 60601-1-10 MEDICAL ELECTRICAL EQUIPMENT - PART 1-10: GENERAL REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE - COLLATERAL STANDARD: REQUIREMENTS FOR THE DEVELOPMENT OF PHYSIOLOGIC CLOSED-LOOP CONTROLLERS IEC 60601-1-11 MEDICAL ELECTRICAL EQUIPMENT - PART 1-11: GENERAL REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE - COLLATERAL STANDARD: REQUIREMENTS FOR MEDICAL ELECTRICAL EQUIPMENT AND MEDICAL ELECTRICAL SYSTEM USED IN HOME CARE APPLICATIONS IEC 60601-1-12 (CDM) MEDICAL ELECTRICAL EQUIPMENT - PART 1-12: GENERAL REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE - COLLATERAL STANDARD: REQUIREMENTS FOR MEDICAL ELECTRICAL EQUIPMENT AND MEDICAL ELECTRICAL SYSTEMS USED IN THE EMERGENCY MEDICAL SERVICES ENVIRONMENT rigelmedical.com Innovating Together Appendix B IEC 60601-2 Particular Standards (© IEC Geneva, Switzerland) IEC 60601-2-1 MEDICAL ELECTRICAL EQUIPMENT - PART 2-1: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ELECTRON ACCELERATORS IN THE RANGE 1 MEV TO 50 MEV IEC 60601-2-2 MEDICAL ELECTRICAL EQUIPMENT - PART 2-2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF HIGH FREQUENCY SURGICAL EQUIPMENT IEC 60601-2-3 (ADIS) MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF SHORT-WAVE THERAPY EQUIPMENT IEC 60601-2-4 MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF CARDIAC DEFIBRILLATORS AND CARDIAC DEFIBRILLATORS MONITORS IEC 60601-2-5 MEDICAL ELECTRICAL EQUIPMENT - PART 2-5: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ULTRASONIC PHYSIOTHERAPY EQUIPMENT IEC 60601-2-6 (ADIS) MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF MICROWAVE THERAPY EQUIPMENT IEC 60601-2-7 MEDICAL ELECTRICAL EQUIPMENT - PART 2-7: PARTICULAR REQUIREMENTS FOR THE SAFETY OF HIGH-VOLTAGE GENERATORS OF DIAGNOSTIC X-RAY GENERATORS IEC 60601-2-8 MEDICAL ELECTRICAL EQUIPMENT - PART 2-8: PARTICULAR REQUIREMENTS FOR THE SAFETY OF THERAPEUTIC X-RAY EQUIPMENT OPERATING IN THE RANGE 10 KV TO 1 MV IEC 60601-2-10 (CCDV) MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF NERVE AND MUSCLE STIMULATORS IEC 60601-2-11 MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF GAMMA BEAM THERAPY EQUIPMENT IEC 60601-2-13 MEDICAL ELECTRICAL EQUIPMENT - PART 2-13: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ANAESTHETIC WORKSTATIONS IEC 60601-2-16 (RDIS) MEDICAL ELECTRICAL EQUIPMENT - PART 2-16: PARTICULAR REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE OF HAEMODIALYSIS, HAEMODIAFILTRATION AND HAEMOFILTRATION EQUIPMENT IEC 60601-2-17 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF REMOTE-CONTROLLED AUTOMATICALLY DRIVEN GAMMARAY AFTER-LOADING EQUIPMENT IEC 60601-2-18 MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ENDOSCOPIC EQUIPMENT IEC 60601-2-19 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS OF SAFETY OF BABY INCUBATORS IEC 60601-2-20 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF TRANSPORT INCUBATORS IEC 60601-2-21 MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF INFANT RADIANT WARMERS IEC 60601-2-22 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF DIAGNOSTIC AND THERAPEUTIC LASER EQUIPMENT 31 32 IEC 60601-2-23 MEDICAL ELECTRICAL EQUIPMENT - PART 2-23: PARTICULAR REQUIREMENTS FOR THE SAFETY, INCLUDING ESSENTIAL PERFORMANCE, OF TRANSCUTANEOUSPARTIAL PRESSURE MONITORING EQUIPMENT IEC 60601-2-24 (ADIS) MEDICAL ELECTRICAL EQUIPMENT - PART 2-24: PARITCULAR REQUIREMENTS FOR THE SAFETY OF INFUSION PUMPS AND CONTROLLERS IEC 60601-2-25 MEDICAL ELECTRICAL EQUIPMENT - PART 2-25: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ELECTROCARDIOGRAPHS IEC 60601-2-26 (ADIS) MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ELECTROENCEPHALOGRAPHS IEC 60601-2-27 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ELECTROCARDIOGRAPHIC MONITORING EQUIPMENT IEC 60601-2-28 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF XRAY SOURCE ASSEMBLIES AND X-RAY TUBE ASSEMBLIES FOR MEDICAL DIAGNOSIS IEC 60601-2-29 MEDICAL ELECTRICAL EQUIPMENT - PART 2-29: PARTICULAR REQUIREMENTS FOR THE SAFETY OF RADIOTHERAPY SIMULATORS IEC 60601-2-31 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF EXTERNAL CARDIAC PACEMAKERS WITH INTERNAL POWER SOURCE IEC 60601-2-32 MEDICAL ELECTRICAL EQUIPMENT PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ASSOCIATED EQUIPMENT OF X-RAY EQUIPMENT IEC 60601-2-33 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF MAGNETIC RESONANCE EQUIPMENT FOR MEDICAL DIAGNOSIS IEC 60601-2-34 MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY, INCLUDING ESSENTIAL PERFORMANCE, OF INVASIVE BLOOD PRESSURE MONITORING EQUIPMENT IEC 60601-2-36 (1CD) MEDICAL ELECTRICAL EQUIPMENT - PART 2: PARTICULAR REQUIREMENTS FOR THE SAFETY OF EQUIPMENT FOR EXTRACORPOREALLY INDUCED LITHOTRIPSY IEC 60601-2-37 MEDICAL ELECTRICAL EQUIPMENT - PART 2-37: PARTICULAR REQUIREMENTS FOR THE BASIC SAFETY AND ESSENTIAL PERFORMANCE OF ULTRASONIC MEDICAL DIAGNOSTIC AND MONITORING EQUIPMENT IEC 60601-2-39 MEDICAL ELECTRICAL EQUIPMENT - PART 2-39: PARTICULAR REQUIREMENTS FOR THE SAFETY OF PERITONEAL DIALYSIS EQUIPMENT IEC 60601-2-40 MEDICAL ELECTRICAL EQUIPMENT - PART 2-40: PARTICULAR REQUIREMENTS FOR THE SAFETY OF ELETROMYOGRAPHS AND EVOKED RESPONSE EQUIPMENT IEC 60601-2-41 (CCDV) MEDICAL ELECTRICAL EQUIPMENT - PART 2-41: PARTICULAR REQUIREMENTS FOR THE SAFETY OF SURGICAL LUMINAIRES AND LUMINAIRES FOR DIAGNOSIS IEC 60601-2-43 MEDICAL ELECTRICAL EQUIPMENT - PART 2-43: PARTICULAR REQUIREMENTS FOR THE SAFETY OF X-RAY EQUIPMENT FOR INTERVENTIONAL PROCEDURES IEC 60601-2-44 (CCDV) MEDICAL ELECTRICAL EQUIPMENT - PART 2-44: PARTICULAR REQUIREMENTS FOR THE SAFETY OF X-RAY EQUIPMENT FOR COMPUTED TOMOGRAPHY rigelmedical.com Innovating Together IEC 60601-2-45 MEDICAL ELECTRICAL EQUIPMENT - PART 2-45: PARTICULAR REQUIREMENTS FOR THE SAFETY OF MAMMOGRAPHIC X-RAY EQUIPMENT AND MAMMOGRAPHIC STEREOTACTIC DEVICES IEC 60601-2-46 MEDICAL ELECTRICAL EQUIPMENT - PART 2-46: PARTICULAR REQUIREMENTS FOR THE SAFETY OF OPERATING TABLES IEC 60601-2-47 (RDIS) MEDICAL ELECTRICAL EQUIPMENT - PART 2-47: PARTICULAR REQUIREMENTS FOR THE SAFETY, INCLUDING ESSENTIAL PERFORMANCE, OF AMBULATORY ELECTROCARDIOGRAPHIC SYSTEMS IEC 60601-2-49 MEDICAL ELECTRICAL EQUIPMENT - PART 2-49: PARTICULAR REQUIREMENTS FOR THE SAFETY OF MULTIFUNCTION PATIENT MONITORING EQUIPMENT IEC 60601-2-50 MEDICAL ELECTRICAL EQUIPMENT - PART 2-5O: PARTICULAR REQUIREMENTS FOR THE SAFETY OF INFANT PHOTOTHERAPY EQUIPMENT IEC 60601-2-51 MEDICAL ELECTRICAL EQUIPMENT - PART 2-51: PARTICULAR REQUIREMENTS FOR SAFETY, INCLUDING ESSENTIAL PERFORMANCE, OF RECORDING AND ANALYSING SINGLE CHANNEL AND MULTICHANNEL ELECTROCARDIOGRAPHS IEC 60601-2-52 MEDICAL ELECTRICAL EQUIPMENT - PART 2-52: PARTICULAR REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE OF MEDICAL BEDS IEC 60601-2-53 MEDICAL ELECTRICAL EQUIPMENT, PART 2-53: PARTICULAR REQUIREMENTS FOR THE SAFETY AND ESSENTIAL PERFORMANCE OF A STANDARD COMMUNICATIONS PROTOCOL FOR COMPUTER ASSISTED ELECTROCARDIOGRAPHY IEC 60601-2-54 MEDICAL ELECTRICAL EQUIPMENT - PART 2-54: PARTICULAR REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE OF X-RAY EQUIPMENT FOR RADIOGRAPHY AND RADIOSCOPY IEC 60601-2-56 MEDICAL ELECTRICAL EQUIPMENT - PART 2-56: PARTICULAR REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE OF SCREENING THERMOGRAPHS FOR HUMAN FEBRILE TEMPERATURE SCREENING IEC 60601-2-57 PARTICULAR REQUIREMENTS FOR THE SAFETY AND ESSENTIAL PERFORMANCE OF INTENSE LIGHT SOURCES USED ON HUMANS AND ANIMALS FOR MEDICAL AND COSMETIC PURPOSES IEC 60601-2-62 (ACDV) MEDICAL ELECTRICAL EQUIPMENT - PART 2-62: PARTICULAR REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE OF HIGH INTENSITY THERAPEUTIC ULTRASOUND (HITU) SYSTEMS IEC 60601-2-63 (CCDV) MEDICAL ELECTRICAL EQUIPMENT - PART 2-63: PARTICULAR REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE OF DENTAL EXTRA-ORAL X-RAY EQUIPMENT IEC 60601-2-65 (CCDV) MEDICAL ELECTRICAL EQUIPMENT - PART 2-65: PARTICULAR REQUIREMENTS FOR BASIC SAFETY AND ESSENTIAL PERFORMANCE OF DENTAL INTRA-ORAL X-RAY EQUIPMENT 33 Appendix C YSI 400 & 700 resistance reference table 34 Temp 'C YSI 400 Resistance YSI 700 Resistance A YSI 700 Resistance B Temp 'C YSI 400 Resistance YSI 700 Resistance A YSI 700 Resistance B -1˚C 7741Ω 20620Ω 99800Ω 26˚C 2156Ω 5744Ω 28740Ω 0˚C 7355Ω 19590Ω 94980Ω 27˚C 2064Ω 5500Ω 27540Ω 1˚C 6989Ω 18620Ω 90410Ω 28˚C 1977Ω 5266Ω 26400Ω 2˚C 6644Ω 17700Ω 86090Ω 29˚C 1894Ω 5046Ω 25310Ω 3˚C 6319Ω 16830Ω 81990Ω 30˚C 1815Ω 4834Ω 24270Ω 4˚C 6011Ω 16010Ω 78110Ω 31˚C 1739Ω 4634Ω 23280Ω 5˚C 5719Ω 15240Ω 74440Ω 32˚C 1667Ω 4442Ω 22330Ω 6˚C 5444Ω 14500Ω 70960Ω 33˚C 1599Ω 4260Ω 21430Ω 7˚C 5183Ω 13810Ω 67660Ω 34˚C 1533Ω 4084Ω 20570Ω 8˚C 4937Ω 13150Ω 64530Ω 35˚C 1471Ω 3918Ω 19740Ω 9˚C 4703Ω 12530Ω 61560Ω 36˚C 1412Ω 3760Ω 18960Ω 10˚C 4482Ω 11940Ω 58750Ω 37˚C 1355Ω 3610Ω 18210Ω 11˚C 4273Ω 11380Ω 56070Ω 38˚C 1301Ω 3466Ω 17490Ω 12˚C 4074Ω 10850Ω 53540Ω 39˚C 1249Ω 3328Ω 16800Ω 13˚C 3886Ω 10350Ω 51130Ω 40˚C 1200Ω 3196Ω 16150Ω 14˚C 3708Ω 9878Ω 48840Ω 41˚C 1152Ω 3070Ω 15520Ω 15˚C 3539Ω 9428Ω 46670Ω 42˚C 1107Ω 2950Ω 14920Ω 16˚C 3378Ω 9000Ω 44600Ω 43˚C 1064Ω 2836Ω 14350Ω 17˚C 3226Ω 8594Ω 42640Ω 44˚C 1023Ω 2726Ω 13800Ω 18˚C 3081Ω 8210Ω 40770Ω 45˚C 983.8Ω 2620Ω 13280Ω 19˚C 2944Ω 7844Ω 38990Ω 46˚C 946.2Ω 2520Ω 12770Ω 20˚C 2814Ω 7496Ω 37300Ω 47˚C 910.2Ω 2424Ω 12290Ω 21˚C 2690Ω 7166Ω 35700Ω 48˚C 875.8Ω 2334Ω 11830Ω 22˚C 2572Ω 6852Ω 34170Ω 49˚C 842.8Ω 2246Ω 11390Ω 23˚C 2460Ω 6554Ω 32710Ω 50˚C 811.3Ω 2162Ω 10970Ω 24˚C 2354Ω 6270Ω 31320Ω 51˚C 781.1Ω 2080Ω 10570Ω 25˚C 2252Ω 6000Ω 30000Ω rigelmedical.com Innovating Together Appendix D Example documentation template Appendix D Example documentation template Testing organization: Test before putting into service (reference value) Recurrent Test Test after repair Name of testing person: Responsible organization: ID Number: Equipment: Type: Production No./Serial Nr.: Manufacturer: Applied part type: Class of protection: 0 B BF CF I Mains connection: II 1) PIE Battery NPS DPS Accessories: Test: Measurement equipment: Complies Yes No Visual inspection: Measurements: Measured value Protective ground resistance Ω Equipment leakage current (according to Figure.....) mA Patient leakage current (according to Figure....) mA Insulation resistence (according to Figure.....) MΩ Functional Test (parameters tested): Deficiency / Note: Overall Assessment: No safety or functional deficiencies were detected No direct risk, deficiencies detected may be corrected on short term Equipment shall be taken out of operation until deficiencies are corrected Equipment does not comply – Modifications / Exchange of components / Taking out of service – is recommended Next recurrent test necessary in 6 / 12 / 24 / 36 months Name: 1) PIE NPS DPS Date/Signature: PERMANENT INSTALLED EQUIPMENT NON-DETACHABLE POWER SUPPLY CORD DETACHABLE POWER SUPPLY CORD Bibliography Jacobson, B., & Murray, A. (2007). Medical Devices; Use and Safety, Churchill Livingstone: Elsevier. Webster,G.J., (Ed.). (1997). Design of Pulse Oximeters (1st ed.), New York: Medical Science Series 12-Lead ECG System, http://www.bem.fi/book/15/15.htm (Aug 2011) 35 Vital Signs Simulators Rigel UNI-SIM Vital Signs Simulator Rigel BP-SIM NIBP Simulator The world’s first combined, fully functional NIBP, SpO2 and patient simulator in a single hand-held unit. Extremely accurate and featuring full synchronized functionality. A breakthrough in the way safety testing is implemented, the UNI-SIM saves time and money, as well as simplifying the testing process. The first hand-held NIBP simulator to incorporate custom settings, including pediatric and adult NIBP pressure simulations, pulse volume adjustments, heart rate and manufacturerspecific envelopes. Large capacity internal memory for data capture, storage and downloading of test results via Bluetooth. Features include: Features include: ■ Light, hand-held, battery operation ■ Light, hand-held, battery operation ■ Combined NIBP, SpO2 and ■ Adult & pediatric NIBP simulations patient simulator in one unit ■ Manufacturer specific O-curves ■ User configurable simulations ■ Overpressure and leak test ■ Full sychronised functionality ■ Memory for up to 10,000 devices ■ Memory for up to 10,000 devices 36 Bluetooth compatible Battery powered Barcode scanner Mains powered Med-eBase compatible Med-ekit compatible rigelmedical.com Innovating Together Rigel SP-SIM SpO2 Simulator Rigel 333 Patient Simulator The first hand-held SpO2 simulator featuring pulse volume adjustments, heart rate and manufacturer-specific R-curves. The large capacity internal memory enables test results to be captured, stored and downloaded via Bluetooth. The 333 is one of the smallest, most powerful and fully comprehensive patient simulators available. Providing a true 12 lead ECG signal with 43 arrhythmias, dual invasive blood pressure, respiration, temperature and industry standard waveforms. Features include: Features include: ■ Light, hand-held, battery operation ■ Light, hand-held, battery operation ■ Tests probe and monitor both at the same time ■ Accurate 12-lead simulation of 43 arrhythmias ■ User configurable simulations ■ Invasive blood pressure ■ Manufacturer R-curves ■ Temperature & respiration ■ Memory for up to 10,000 devices ■ Performance wave forms Please visit rigelmedical.com for more information 37 Electrical Safety Analyzers 38 Rigel 288 Electrical Safety Analyzer Rigel 277 Plus Electrical Safety Analyzer Rigel 266 Plus Electrical Safety Analyzer Rigel 62353 Electrical Safety Analyzer The 288 is the first truly hand-held medical electrical safety analyzer to combine the features of an automatic/manual tester with a data logging/asset management facility. Control is through a menu driven GUI. A large data memory and Bluetooth facility make this an effective mobile unit. The Rigel 277 Plus is a fully comprehensive electrical medical safety analyzer used within the widest possible range of applications. The ability to manage results and print records means that the user can manage the test and re-test procedure more productively. The Rigel 266 Plus is a highly compact, easy-to-use safety analyzer designed to test in accordance with IEC/EN 60601-1, MDA DB9801 and AS/NZ 3200. This compact unit provides a highly effective and portable test solution. The Rigel 62353 is a cost effective automatic safety analyzer dedicated to the IEC 62353 standard for routine and testing after repair of medical devices. Offering automatic test sequences, data entry and storage as well as PC download capabilities. Features include: ■ Light, hand-held, battery operation ■ Conform IEC 62353 / 60601/ VDE 0751 / NFPA-99 / AS-NZS 3551 ■ Memory for up to 10,000 devices ■ Bluetooth communication ■ Full, semi automatic & manual tests Features include: ■ Conform IEC 60601 / 61010 / AAMI / NFPA-99 / S-NZS 3200 ■ Onboard printer & QWERTY keyboard ■ 100mA to 25A ground bond current ■ Full, semi automatic & manual tests ■ Memory for up to 2,500 devices Features include: ■ Small and compact ■ Conform IEC 60601, MDA DB 9801 ■ 1-25A ground bond test current ■ Up to 5 applied parts ■ Direct print facility Features include: ■ Light, hand-held, battery operation ■ Conform IEC 62353 ■ Fully customisable test sequences ■ Data entry and storage ■ PC download ■ Full, semi automatic & manual tests rigelmedical.com Performance Analyzers Rigel Uni-Pulse Defibrillator Analyzer Rigel Multi-Flo Infusion Pump Analyzer Rigel Uni-Therm Electrosurgical Analyzer The innovative Rigel Uni-Pulse defibrillator analyzer is the most compact and versatile instrument on the market, able to accurately verify all mono and biphasic defibrillators and AED’s. Features include: onscreen waveform capture, built-in 12-lead ECG simulator, onboard memory and optional variable load box ensuring the Rigel Uni-Pulse meets all the requirements of IEC 60601-2-4. The market defining Rigel Multi-Flo infusion pump analyzer is a portable instrument to accurately and swiftly verify the performance of all infusion devices. Offering instantaneous flow and available in 1, 2 and 4 individual channel configuration. The Multi-Flo boasts a large color screen, providing precise information on flow rate, occlusion and back pressure and trumpet curves. The Rigel Uni-Therm offers the latest technology in high frequency power measurement. It’s small, easy-to-use, has a large color display and innovative navigation making this a fast, efficient test tool for testing the performance of all diathermy machines. A large internal memory and PC communication provides traceability of the test data. Features include: ■ IEC 60601-2-4 compliant ■ Mono and bi-phasic ■ Waveform capture, store & replay ■ Built-in 12 lead ECG simulator ■ Auto AED testing Features include: ■ IEC 60601-2-24 compliant ■ Instant flow and pressure ■ Compatible with all infusion devices ■ On-screen trumpet curve ■ Onboard data storage Features include: ■ HF leakage test ■ Power distribution from 0-5100Ω ■ Current measurement up to 6A RMS ■ Return plate security test (Rem) ■ Onboard data storage 39 Med-eKit Solutions 40 Med-eKit Pro Med-eKit Elite Med-eKit Lite Med-eKit Plus If you’re after a complete biomedical workshop on wheels, take a look at our configurable Rigel MedeKit Pro. Housed in a durable and handy trolley case, it accommodates up to 10 different testers and simulators, so you can carry your analyzer, vital signs simulator, defib analyzer, ventilator tester and more, safely and conveniently. The Med-eKit Elite is a handy and more specialised carrying solution. It has a hardwearing pelican case which can be customised to hold up to two individual testers (the Rigel 288 and UNI-SIM, for instance). It can also include a label and results printer, barcode scanner and PC software. This new case is a standard accessory for the Rigel 288, UNI-SIM and Uni-Pulse biomedical testing instruments. It can be configured to hold a number of different items of test equipment and accessories like a label results printer and a barcode scanner. Features include: ■ Integral wheels and extendable handle for easy use ■ Configurable with up to 10 tester functions ■ Durable and robust enclosure ■ Water-proof design ■ Secure locking Features include: ■ Configurable with up to 4 tester functions ■ Lightweight design ■ Durable and robust enclosure ■ Water-proof design ■ Secure locking Features include: ■ Carry securely on back/ easy access from front ■ Configurable compartments for testers and accessories ■ Extremely lightweight design ■ Suitable for up to 5 tester functions ■ Durable and water repellent design The Med-eKit Plus is a solution package offering a complete test set that includes electrical safety, vital signs simulator, ventilator test and more. It can also feature a laptop of your specification and our latest asset management software. You could make life a lot more efficient for yourself if you included a range of accessories like the compact barcode scanner and results/label printer. Features include: ■ Cost effective package deal ■ Configurable including up to 5 tester functions ■ Optional laptop included ■ Extremely lightweight design ■ Durable and water repellent design rigelmedical.com Asset Management Software You saw database management and work order schedules as a major benefit, as they lead to fast, efficient test device configuration. You asked for time and money-saving software to provide monthly schedule tests you could upload to your testers for easy re-test. You also wanted preventative maintenance which analysed and compared results and which also sent you an alarm when devices could be deteriorating or needed to be replaced. And you asked for test certificate software customisable for details and logos in PDF format. So we created Med-eBase software which can be used in a number of database environments, including: SQL and SQLite. This way your data’s secure and easily accessible. It can also be easily interrogated by third party software which makes compatibility with other software packages easy and straightforward. 41 Rigel Medical, Seaward Group USA, 6304 Benjamin Road, Suite 506, Tampa, Florida, 33634, United States Tel: 813-886-2775 Email: enquiry@rigelmedical.com Web: rigelmedical.com Version 1.2 - 2012 Part of
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