Patient Care and Monitoring Systems

Patient care

• Patient care is the focus of many clinical disciplines – Various disciplines sometimes overlaps – Each has its own primary focus, emphasis, and methods of care delivery – Each discipline’s work is complex • Collaboration among disciplines adds complexity. • In all disciplines, the quality of clinical decisions depends in part on the quality of information available to the decision-maker.

Care Process

• Care begins with collecting data and assessing the patient’s current status • Through cognitive processes specific to the discipline: – diagnostic labels are applied, – therapeutic goals are identified with timelines for evaluation, and – therapeutic interventions are selected and implemented • At specified intervals: – patient is reassessed, – effectiveness of care is evaluated, and – therapeutic goals and interventions are continued or adjusted as needed • If the reassessment shows that the patient no longer needs care, services are terminated

Discipline in patient care

• Patient care is a multidisciplinary process centered on – the care recipient in the context of the – family, – significant others, and – community.

Information to Support Patient Care

• The information for direct patient care is defined in the answers to the following questions: – Who is involved in the care of the patient?

– What information does each professional require to make decisions?

– From where, when, and in what form does the information come?

– What information does each professional generate? Where, when, and in what form is it needed?

History

• The genesis of patient care systems occurred in the mid 1960’s. • One of the first and most successful systems was the Technicon Medical Information System (TMIS), begun in 1965 as a collaborative project between Lockheed and El Camino Hospital in Mountain View, California.

• TMIS designed to simplify documentation through the use of standard order sets and care plans. • More than three decades later, the technology has moved on.

Recent History

• Part of what changed users’ expectations for patient care systems was: • Development and evolution of the HELP system at LDS Hospital in Salt Lake City, Utah. – Decision support to physicians during the process of care – Managing and storing data – Support nursing care decisions – Aggregate data for research leading to improved patient care.

Patient-Care Component

Problem lists

Patient Care Components

Examples: Hospital Examples: Ambulatory Care

Summary reports Order entry Problem-Oriented Medical Information System (PROMIS), Medical Center Hospital of Vermont, Burlington, VT [Weed, 1975]; Tri-Service Medical Information System (TRIMIS), Department of Defense [Bickel, 1979] Technicon Medical Information System (TMIS), Clinical Center at National Institutes of Health, Bethesda, MD [Hodge, 1990]; Decentralized Hospital Computer Program (DHCP), Department of Veteran’s Affairs [Ivers & Timson, 1985] Health Evaluation Logical Processing (HELP), Latter Day Saints Hospital, Salt Lake City, UT [Kuperman et al., 1991]; Technicon Medical Information System (TMIS), Clinical Center at National Institutes of Health, Bethesda, MD [Hodge, 1990]; Computer-Stored Ambulatory Record (COSTAR), Massachusetts General Hospital, Boston, MA [Barnett, 1976]; Summary Time-Oriented Record (STOR), University of California, San Francisco, CA [Whiting-O'Keefe et al., 1980] Regenstrief, Regenstrief Institute, Indianapolis, IN [McDonald, 1976]; Computer-Stored Ambulatory Record (COSTAR), Massachusetts General Hospital, Boston, MA [Barnett, 1976] The Medical Record (TMR), Duke University Medical Center, Durham, NC [Hammond et al., 1980];

Patient-Care Component

Results review Nursing protocols and care plans Alerts and reminders

Examples: Hospital Examples: Ambulatory Care

University of Missouri- Columbia System, Columbia, MO [Lindberg, 1965]; Decentralized Hospital Computer Program (DHCP), Department of Veteran’s Affairs[Ivers & Timson, 1985] Computer-Stored Ambulatory Record (COSTAR), Massachusetts General Hospital, Boston, MA [Barnett, 1976]; Summary Time-Oriented Record (STOR), University of California, San Francisco, CA [Whiting-O'Keefe et al., 1980] Health Evaluation Logical Processing (HELP), Latter Day Saints Hospital, Salt Lake City, UT [Kuperman et al., 1991]; Technicon Medical Information System (TMIS), El Camino Hospital, Mountain View, CA [Watson, 1977] Health Evaluation Logical Processing (HELP), Latter Day Saints Hospital, Salt Lake City, UT [Kuperman et al., 1991]; Beth Israel Hospital System, Boston, MA [Safran et al., 1989] Regenstrief, Regenstrief Institute, Indianapolis, IN [McDonald, 1976]; The Medical Record (TMR), Duke University Medical Center, Durham, NC [Hammond et al., 1980]

HELP System at LDS Hospital

Patient Monitoring

• •

“Repeated or continuous observations or measurements of the patient, his or her physiological function, and the function of life support equipment, for the purpose of guiding management decisions, including when to make therapeutic interventions, and assessment of those interventions” [Hudson, 1985, p. 630]. A patient monitor may not only alert caregivers to potentially life-threatening events; many provide physiologic input data used to control directly connected life support devices.

History of Physiological data measurements

• 1625 Santorio-measure body temperature with spirit thermomoeter. – Santorio was first to apply a numerical scale to his thermo scope, which later evolved into the thermometer.

• Timing pulse with pendulum. Principles were established by Galileo. These results were ignored.

– Claudius Galen, was physician to five Roman emperors. – He also understood the value of the pulse in diagnosis. – John Floyer, seconds. 1707, measuring them. acknowledged Galen's skill in identifying various pulse beats, but was appalled that even 1500 years later the doctors were still not using any standard procedure for – He said that the pulse should be counted using a watch or a clock and he had a special pulse watch made for timing 60 – He published his findings in his works called " Physician's Pulse Watch" , but doctors largely ignored Floyer's advice for over a hundred years .

History

• 1852 Ludwig Taube Course of patient’s fever measurement • At this time Temperature, pulse rate respiratory rate had become standard vital signs.

• Scipione Riva-Rocci introduced the sphygmomanometer (blood pressure cuff). (4th vital sign).

– Scipione Riva-Rocci his fundamental contribution (1896) was the mercury sphygmomanometer, which is easy to use and gives sufficiently reliable results. – This device, the standard instrument for measuring blood pressure, led to many new developments in the therapy of hypertension disease. • Nikolai koroktoff applied the cuff with the stethoscope (developed by Renne Lannec-French Physician) to measure systolic and diastolic blood pressures.

What is blood pressure?

• Blood is carried from the heart to all parts of your body in vessels called arteries. • Blood pressure is the force of the blood pushing against the walls of the arteries. • Each time the heart beats (about 60-70 times a minute at rest), it pumps out blood into the arteries. • Your blood pressure is at its highest when the heart beats, pumping the blood. • This is called • This is the

systolic diastolic

– Both are important. pressure. • When the heart is at rest, between beats, your blood pressure falls. pressure. • Blood pressure is always given as these two numbers, the systolic and diastolic pressures. • When the two measurements are written down, the

systolic

pressure is the first or top number, and the

diastolic

pressure is the second or bottom number (for example, 120/80).

Harvey Cushing

• 1900s Harvey Cushing introduced an apparatus to measure blood pressure during operations .

• Raised the questions: 1.

2.

3.

Are we collecting too much data? Are the instruments used in clinical medicine too accurate? Would not approximated values be just as good? Cushing answered his own questions by stating that vital sign measurement should be made routinely and that accuracy was important [Cushing, 1903].

History (Cont.)

• • • • • 1903 Willem Einthoven devised the string galvanometer – An instrument used to detect, measure, and determine the direction of small electric currents by means of mechanical effects produced by a current-carrying coil in a magnetic field. to measure ECG (Nobel Prize 1924) – 1901, Einthoven invented a new galvanometer for producing electrocardiograms using a fine quartz string coated in silver based on ideas by Deprez and d'Arsonval, who used a wire coil. His "string galvanometer" weighs 600 pounds. Einthoven acknowledged the similar system by Clément Ader (1841-1926), but later, in 1909, calculated that his galvanometer was in fact many thousands of times more sensitive. Improvement over the capillary galvanometer, and the original galvanometer invented by Johann Salomo Christoph Schweigger (1779-1857) in Halle in 1820. Einthoven published the first electrocardiogram recorded on a string galvanometer in 1902.

1905, Einthoven began transmitting electrocardiograms from the hospital to his laboratory 1.5 km away via telephone cable. On March 22nd that year the first telecardiogram was recorded from a healthy and vigorous man and the tall R waves were attributed to his cycling from laboratory to hospital for the recording.

electrocardiograph

• An instrument used in the detection and diagnosis of heart abnormalities that measures electrical potentials on the body surface and generates a record of the electrical currents associated with heart muscle activity. Also called

cardiograph

.

History

• 1950 The ICU’s were established to meet increasing demand for acute and intensive care required by patients with complex disorders.

• 1963 Day - treatment of post– percent.

contact”.

myocardial-infarction

patients in a coronary-care unit reduced mortality by 60 • 1968 Maloney - having the nurse record vital signs every few hours was “only to assure regular nurse–patient • Late ‘60s and early ‘70 bedside monitors built around bouncing balls or conventional oscilloscope.

• ‘90

Computer-based patient monitors -

Systems with: – database functions, – report-generation systems, and – some decision-making capabilities.

Myocardial Infarction

• “

Heart attack

“, non-medical term, is "Myocardial Infarction". • Either term is scary. • "Myocardial Infarction" (abbreviated as "MI") means there is death of some of the muscle cells of the heart as a result of a lack of supply of oxygen and other nutrients. • This lack of supply is caused by closure of the artery ("coronary artery") that supplies that particular part of the heart muscle with blood. • This occurs 98% of the time from the process of arteriosclerosis ("hardening of the arteries") in coronary vessels.

Patient Monitoring in ICUs

• Categories of patients who need physiologic monitoring: 1. Patients with unstable physiologic regulatory systems; • Example: a patient whose respiratory system is suppressed by a drug overdose or anesthesia.

2. Patients with a suspected life-threatening condition; • Example: a patient who has findings indicating an acute myocardial infarction (heart attack).

3. Patients at high risk of developing a life-threatening condition; • Example: patients immediately post open-heart surgery, or a premature infant whose heart and lungs are not fully developed.

4. Patients in a critical physiological state; • Example: patients with multiple trauma or septic shock.

• •

Care of the Critically Ill

Requires prompt and accurate decisions. ICUs use computers almost universally :

– acquire physiological data frequently or continuously, (e.g. blood pressure) – communicate information from data-producing systems to remote locations (e.g., laboratory and radiology departments) – store, organize, and report data – integrate and correlate data from multiple sources – provide clinical alerts and advisories based on multiple sources of data – function as a decision-making tool that health professionals may use in planning then care of critically ill patients – measure the severity of illness for patient classification purposes – analyze the outcomes of ICU care in terms of clinical effectiveness and cost-effectiveness

Intensive care Unit Bed

Use of computers for patient monitoring

Automatic control Patient Transducers equipment Computer DBMS Clinician Display Mouse and keyboard Reports

Bed Bed

ICU

Bed WEB connection Nurse station Telemetry Bed

Some instruments in mind

Types of Data Used in Patient

Continuous

monitoring in different ICU ’s

Sampled Coded Data Free Text variables variables

Cardiac ECG Heart rate (HR) HR variability PVCs Temperature Central Peripheral Patient observation Color Pain Position Etc., All other observations or interventions that cannot be measured or coded Blood pressure Arterial/venous Pulmonary Left/right atrial/ventricular Systolic/Dyastol Per beat/average Systolic time intervals Respiratory Frequency Depth/vol/flow Pressure/Resist Respiratory gases Neurological EEG Frequency components Amplitudes Coherence Blood Chemistry Hb PH PO 2 PCO 2 Etc., Fluid balance Infusions Blood plasma Urine loss Interventions Infusions Drugs Defibrillation Artificial ventilations Anesthesia

Patient monitoring

Features Matrix ECG 3 leads ECG 5 leads ECG 10 leads Respiration Invasive BP Dual Temp/C.O.

NIBP SpO2

Understanding ECG - Normal ECG summary

Normal rate Sinus rhythm Normal Axis P wave QRS complex T waves QT interval U waves Between 50bpm and 99bpm Normal P wave before each QRS complex Regular QRS complexes May be a variation with respiration Axis between 30 degrees and +90 degrees May be negative in Lead V1 Normal morphology PR interval between 0.12 and 0.2 seconds Normal morphology No longer than 0.12 seconds Q waves are normal in Leads I, aVL and V6 R waves increase across the chest leads Normal morphology May be inverted in Lead III,aVR and V1 May also be inverted in V2 and V3 in blacks QTc between 0.35 and 0.43 seconds Small U waves often seen in leads V2 V4

Respiration

• • • •

Rate range

: 1 to 200 breaths/min

Impedance range

: 100 to 1000 ohms at 52.6 kHz

Detection sensitivity range

: 0.4 to 10 ohms impedance variation

Low rate alarm range

: 1 to 199 breaths/min •

High rate alarm range

: 2 to 200 breaths/min •

Apnea alarm rate

: 0 to 30 seconds in one-second increments • Cardiac artifact alarm • •

Waveform display bandwidth

: 0.05 to 2.5 Hz (-3 dB)

Analog output

: Selectable •

Trends

: 24 hours with 1-minute resolution • Invasive Blood pressure • •

Catheter sites

: Arterial, pulmonary arterial, central venous, left atrial, • intracranial, right atrial, femoral arterial, umbilical venous, umbilical arterial, and special.

Trends

: 24 hours with 1-minute resolution