RRT and Code Management 2021 PDF

Summary

This document details information on Rapid Response Teams (RRTs) and code management, including the roles of caregivers, medical equipment, medications, treatment, and care of patients after resuscitation.

Full Transcript

Chapter 10
RAPID RESPONSE TEAMS AND
CODE MANAGEMENT
Objectives 2
 Compare roles of caregivers in rapid response teams (RRTs) and
managing cardiopulmonary arrest situations.
 Identify equipment used during a code.
 Differentiate basic and advanced life-support measures used during a
code.
 Identify medications used in code management, including use, action,
side effects, and nursing implications.
 Discuss treatment of special problems that can occur during a code.
 Describe special concerns related to the geriatric population during a
code.
 Identify information to be documented during a code.
 Describe care of patients after resuscitation.
 Identify psychosocial, legal, and ethical issues related to code
management.
Cardiopulmonary Arrest 3

 Most codes filled with panic and pandemonium
 Best options
 Prevent
 Plan
 Practice
 RRT another option
Rapid Response Teams 4

 “Failure to rescue” is important concept to
address Assess pt deterioration.

 RRT established to address concerns
 Call BEFORE the cardiac/respiratory arrest
 Recommended by The Joint Commission and
Institute for Healthcare Improvement to
implement systems to request assistance for
worsening conditions
RRTs (continued) 5

 Call any time a staff member is concerned about
changes in a patient’s condition including:
 Heart rate, systolic blood pressure
 Respiratory rate, oxygen saturation
 Mental status
 Urinary output
 Laboratory values
 Some institutions empower family members to
activate the RRT
RRT Effectiveness 6

 RRT reduces:
 Cardiac arrests
 Critical care unit length of stay
 Incidence of acute illness, such as respiratory failure,
stroke, severe sepsis, and acute kidney injury
 Recent review of literature and meta-analysis of
1.3 million patients
 RRT was not associated with lower hospital mortality
rates in hospitalized adults
Codes 7

 Code, code blue, code 99, Dr. Heart
 Cardiac and/or respiratory arrest
 Lifesaving resuscitation and intervention needed
 BLS/AED
 ACLS
Code Team 8

 Notification system
 Members vary within setting
 Better patient management
 Care according to ACLS protocols
 Other healthcare workers manage other patients
Team Members 9

 Leader usually MD skilled in ACLS
 Nurses (usually ICU or ER)
 Primary nurse knows patient
 Second nurse gives medications and gets
equipment from crash cart
 Another nurse records events
 Nursing supervisor provides traffic control and
secures ICU bed (if needed)
Team Members 10

(continued)
 Anesthesiologist/anesthetist intubation
 Respiratory therapist manages airway, sometimes
intubates
 Pharmacist prepares medications in some settings
 Chaplain
 ECG technician
 Other personnel to run errands
Equipment 11

 Crash cart  Bag-valve-mask device
chest
 Backboard better  Airway supplies/suction
compressions
-

 Monitor/defibrillator/pac  Medications
emaker
 IV supplies
 AED
 Nasogastric tube
 Transcutaneous
pacemaker  BP cuff
 Things to Know 12

 Your cart
 Where it is located?
 How do you unlock it?
 How do you check it per unit
protocol?
 Your equipment
 O2 and suction
 Is child-sized equipment available if
needed (e.g., ED)?
Sequence of Events: BLS 13

 Advance directives or living wills
 Airway open
 Breathing
 Mouth to mask
 Bag-valve-mask device
 Circulation: chest compressions
 May do open chest compression in trauma patients
or after cardiac surgery
 ABC became CAB in 2010 guidelines
ACLS: Airway and 14

Breathing
 Airway management
 Manual ventilation
 Intubation
 Isolate airway and keep open
 High concentration of oxygen

 Delivery of tidal volume
 Protect airway
 Suction
 Administer selected medications

Naloxone
approved to
Atropine
go down ET
Vasopressin
Epinephrine tube
(higher doses DT
Lidocaine going in lungs)
ACLS: Airway and 15

Breathing
(continued)

Figure 10-2. Head-tilt/chin-lift technique for opening the airway. A, Obstruction by the tongue. B, Head-
tilt/chin-lift maneuver lifts tongue relieving airway obstruction.
ACLS: Airway and Breathing 16
(continued)

Stop CPR
for brea,ths

30 : 2

Figure 10-3. Rescue breathing with bag-mask device. (Reprinted with permission,
Cleveland Clinic Center for Medical Art & Photography © 2011-2012. All rights reserved.)
ACLS: Airway and 17

Breathing
(continued)
Advanced

airway
① stop
CPR

I breath

96-8 sec

Figure 10-04. Ventilation with a bag-valve device
connected to endotracheal tube.
ACLS: Airway and 18

Breathing
(continued)

Figure 10-5. End-tidal carbon dioxide detector connected to an endotracheal tube. Exhaled
carbon dioxide reacts with the device to create a color change indicating correct endotracheal
tube placement.
ACLS 19

 Primary survey
 ABCD (early defibrillation)
 Use of automatic external defibrillator (AED)
 Secondary survey
 Advanced skills His & T's

 Differential diagnosis
ACLS: Circulation 20
 Large-bore Ivs/Biggest veins
 May insert central line or intraosseous cannula if IV
access is difficult
 Administer medications via endotracheal tube
(ETT) if needed
 Lidocaine
 Epinephrine
 Vasopressin
 Defibrillation
 Differential diagnosis
Logical Flow of Events 21

 BLS  Crowd control
 ACLS/AED  Notification of family
and communication
 Ongoing assessment
 Pulse oximetry  Family presence in code

 ETCO2  If successful code,
transfer to ICU
 Pulse checks
 ABGs
 Lab work
ACLS Summary 22

 Treat patient, not monitor
 CPR throughout
 Early defibrillation essential
 Use ETT as needed for medication administration
 Provide treatment according to algorithms
Circulation 23

Figure 10-6. Defibrillator. (Courtesy Philips Healthcare, Andover, Massachusetts.)
Dysrhythmia 24

Management
 Algorithms
 Early defibrillation
 Public access defibrillation encouraged
 AED used in field
 AED may be used during in-hospital codes; newer
defibrillators have built-in AED
Reverse Causes: H’s & T’s 25

 Hypoxia  Tablets (overdose)
 Hypovolemia  Tamponade (cardiac)
 Hypothermia  Tension pneumothorax
 H+ ions (acidosis)  Thrombosis (coronary)
 Hypokalemia or  Thrombosis (pulmonary)
hyperkalemia
Defibrillation 26

Figure 10-7. Paddle placement for defibrillation.
Defibrillation (continued) 27

Figure 10-8. Anteroposterior placement of adhesive electrode pads for defibrillation or
transcutaneous pacing.
VF and Pulseless VT 28
Defibrillated

 ABCD, initiate CPR
-

 Shock, CPR, shock, CPR, shock
 200 (biphasic), 360 (monophasic) joules
 IV access
 Epinephrine or vasopressin
-

 Intubate if unable to effectively manage airway
and ventilate patient
VF and Pulseless VT 29

(continued)
 Drug-shock continues
 Epinephrine repeated as needed; vasopressin is
given only once
 Consider antidysrhythmic drugs

-
Amiodarone (drug of choice) 1) 300 mg
↳
 Lidocaine
caronlybe 2) 150mg amiodaro e

 Procainamide
 Magnesium if level is low or torsades is present
 Sodium bicarbonate (only if severely acidotic)
Pulseless Electrical Activity 30

(PEA) defibrillate
*

 Rhythm without pulse
 Airway, oxygen, intubate, IV access
 ABCD with CPR
 Treat cause
 Epinephrine
Asystole 31
* defibrillate

 / with CPR
ABCD
 Airway, oxygen, intubate, IV access
 Confirm in two leads
 Treat cause (see PEA)
 Epinephrine
Symptomatic Bradycardia 32

 ABCD with CPR
 Airway, oxygen, IV access
 Atropine Img total of 3 doses
possible
 Consider cause
Box 11.
3
 Transcutaneous pacing SISX of
-

 May need -
sedation/analgesia
symp, brady
 Dopamine or epinephrine
 No lidocaine
Unstable Tachycardia 33

 ABCD
 Airway, oxygen, IV access
 Identify the unstable tachycardia
 Sedation T
 Cardioversion to prevent Ron T

 Reassess patient and rhythm
Defibrillation 34

 Primary treatment for VF and pulseless VT
 Monophasic waveform vs. Biphasic
 Electrical current
 200 to 360 joules vs. 120 joules to 200 joules
Defibrillation 35

(continued)
 Completely depolarize the heart
 Allow for the resumption of rhythm
 Safety is essential
 Complications
 Skin burns
 Damage to heart muscle
Defibrillation 36

(continued)
 External paddles (traditional)
 External “hands-off” defibrillation with
multipurpose pads (ECG, pace, defib)
 Paddle/pad placement
 Transverse/anterior
 Anterior-posterior
Defibrillation 37

(continued)
 Internal paddles
 “Spoons”
 Cardiac surgery
 Open-chest CPR

 Lower joules
Defibrillation 38

(continued)
 Automatic implantable cardioverter-defibrillator
(AICD)
 Recognizes ectopy
 Delivers countershock
 Prevents episodes of sudden death
Procedure for Defibrillation 39

 Paddle or defibrillation pad placement
 Good contact with skin (protect from burns)
 Conductive medium with paddles
 Charge defibrillator to desired setting
 “I’m clear, you’re clear, everyone clear, oxygen
clear”
 Adequate pressure with paddles
 Shock
 Continue CPR 2 minutes, then assess rhythm
Automated External 40

Defibrillation (AED)
 External defibrillator with rhythm analysis
capabilities
 For cardiac arrest
 Procedure
 Place two adhesive pads
 Analysis by AED
 Shock advisory
Cardioversion 41

 Electrical current
 Lower joules (e.g., 50)
 Synchronized delivery on R wave (prevents “shock
on T”)
 Disrupts ectopic foci
Dysrhythmia Management 42
(Cont.)
Defibrillation Versus 43

Cardioversion
 No pulse—defibrillation
 Symptomatic tachycardia—cardioversion (can
also do overdrive pacing)
Documentation of Events 44

 Assign someone to document during code and
record rhythm strips
 Time started
 Actions taken and patient’s response
 Defibrillation
 Medications
 Procedures
 Pacemakers

 Intubation and airway management
 Vital signs
 Team members present
Ex. of Paper Documentation 45

Figure 10-15. Sample of a code record used for documenting activities during
a code. (Courtesy Cleveland Clinic, Cleveland, Ohio.)
Post-Resuscitation 46

 Goals
 Optimize cardiopulmonary function
 Transport to critical care unit
 Determine cause of arrest to prevent
 Management of patient care continues
Post-Resuscitation 47

(continued)
SBP
 Airway placement MAP365
190
 Maintenance of blood pressure and oxygenation
Ou sat >96 %
 Control of dysrhythmias
 Advanced neurological monitoring q4 neurochecus

 Capnography
 Capnography 48

Figure 10-16. Waveform capnography. A. Normal waveform indicating adequate ventilation pattern
(ETCO2 35 to 40 mm Hg). B. Abnormal waveform indicating airway obstruction or obstruction in breathing
circuit (ETCO2 decreasing).

Copyright © 2017 Elsevier Inc. All rights reserved.
Post-CPR Interventions 49

 12-lead ECG identify D event
if
oracute MI

 Arterial line BP
monitoring
 Pulmonary artery catheter
 Indwelling urinary catheter for hourly output
 NG tube if bowel sounds are absent or if patient is
mechanically ventilated
 Serial neurological exams
Risk of seizures
Post-CPR Care 50

 Palliative comfort care
 Pain management
 Sedation
 Anxiety management
 Head CT scan and EEG if comatose Lack of blood flow
to brain

 Blood glucose levels (may be hyperglycemic) possible
damagie
Catecholamines
Supporting the Family 51

 Should they be present during a code? yes

 Providing information
 Active communication
 Visitation after a code
 Support from chaplain and nursing staff
Supporting Other Patients 52

 Remove from the situation
 Talk with them
 Assess their feelings
 Continue their care
Therapeutic Hypothermia 53

 Fever from brain injury increases the level of
neurological damage post-CPR
 Increased length of stay

⑤  Lower body temperature is associated with better
recovery ↓ metabolic rate and
O2 consumption
 Optimal temperature is not known
 Firm guidelines have not been developed
Methods of Hypothermia 54

Figure 10-17. Arctic Sun 5000. Figure 10-18. Thermagard XP.
(Courtesy Medivance, (Courtesy Zoll, Chelmsford,
Louisville, Colorado.) Massachusetts.)
Nursing Care During 55

Hypothermia
 Monitor core body temperature
 Bladder catheter with a temperature probe
 Esophageal thermometer
 Pulmonary artery catheter Swan

 Axillary, tympanic, and oral probes do not
measure core body temperature and should not
be used 32-34 % 24 hrs after Rosc

& code and don't wave up per AHA
Monitoring with 56

Hypothermia
 Shivering
 Increase oxygen consumption
 Increases body temperature
 Controlled with
 IV sedatives
 Analgesics
 Neuromuscular blockade medications
 Hyperglycemia IV insulin
drip a hr
fingerstices
 Drugs can mask seizure activity
 Continuous EEG monitoring versed propofol
Complications 57

 Bleeding control first

 Infection
 Metabolic and electrolyte disturbances
 Hyperglycemia
Bradycardia
coagulopathy
Nursing Care 58

 Infection prevention
 Handwashing
 VAP prevention
 Hyperglycemic management
 IV insulin
 Monitor electrolytes
 During cooling, K+, Mg+, phosphate, and Ca+ may decrease
 During rewarming, K+, Mg+, phosphate, and Ca+ may increase
 Rewarm after 24 hours very slowly 0. 25-0 5/hr.

Rapid rewarming vasodilation hypotension & shock