Basic Human Needs Oxygenation Ventilation/Perfusion
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Transcript Basic Human Needs Oxygenation Ventilation/Perfusion
Basic Human Needs
Oxygenation
Ventilation/Perfusion
Basic Needs: Oxygenation
Oxygenation
Oxygen is required to sustain life, primary basic
human need
The cardiac & respiratory systems function to
supply the body’s oxygen demands
Cardiopulmonary physiology involves delivery of
deoxygenated blood to the right side of the heart &
to the pulmonary system
What are the 2 mechanisms that
drive the function of the heart?
Electrical/conduction
Mechanical/pump
Coronary Artery Circulation
Right Coronary Artery
Left Coronary Artery
Circumflex
Systemic Circulation
LV to aorta to arteries to arterioles to
capillaries
Oxygen exchange occurs at the capillary
level
Waste product exchange occurs here also
and exits via venous system back to lungs
Blood Flow Regulation
Cardiac Output
Cardiac Index
Stroke Volume
Ejection Fraction
Stroke Volume
Preload
Myocardial Contractility
Afterload
Conduction System
Rhythmic relaxation & contraction of atria &
ventricles
Dependent on continuous transmission of
electrical impulses
Influenced by ANS (Sympathetic &
parasympathetic)
Conduction System
Originates in the sinoatrial node (SA node)
Intrinsic rate of 60-100 beats per minute
Electrical impulses transmitted through atria
along intra-nodal pathways to AV node
Conduction System
AV node mediates impulses between atria &
ventricles
Intrinsic rate 40-60 beats per minute
AV node assists atrial emptying by delaying
the impulses before transmitting it through to
the Bundle of His & Perkinje fibers
Conduction System
Intrinsic rate of Purkinje fibers 20-40 beats
per minute
EKG reflects the electrical activity of
conduction system
Normal Sinus Rhythm
Physiology of NSR
Electrical Cycle
NSR
Respiratory Physiology
Structure & Function
Respiratory Gas
Exchange
Structure & Function
Ventilation-Process of moving gases into and out
of the lung
Requires coordination of the muscular & elastic
properties of lungs & thorax as well as intact
innervation
Diaphragm-Major muscle of inspiration, innervated
by phrenic nerve (3rd cervical vertebrae)
Structure & Function
Work of Breathing
Degree of compliance of lungs
Airway resistance
Presence of active expiration
Use of accessory muscles of respiration
Lung Compliance
Ability of lungs to distend or expand in
response to increased intra-alveolar
pressure, the ease in which lungs are
inflated
Compliance is decreased in pulmonary
fibrosis, emphysema
Lung compliance is affected by surface
tension of alveoli, surfactant lowers surface
tension.
Airway Resistance
Pressure difference between the mouth &
the alveoli in relation to the rate of flow of
inspired gas
Airway resistance increased in airway
obstruction, asthma, tracheal edema
Structure & Function
Accessory Muscles
Assist in increasing lung volume during
inspiration
Scalene & sternocleidomastoid (inspiration)
COPD patients use these frequently
Abdominal muscles
Trapezius muscle and pectoralis play minor
role
Pulmonary Circulation
Move blood to and from the alveolocapillary
membrane for gas exchange
Begins at pulmonary artery which receives
deoxygenated blood from RV
Flow continues to PA to pulmonary arterioles to
pulmonary capillaries where blood comes in
contact with alveolocapillary membrane
Respiratory Gas Exchange
Diffusion-movement of molecules from an
area of higher concentration to areas of
lower concentration (oxygen & CO2)
Occurs at the alveolocapillary level
Rate of diffusion affected by thickness of
membrane
Increased thickness: COPD, pulmonary
edema, pulmonary infiltrates, effusions
Oxygen Transport
Consists of lung & cardiovascular system
Delivery depends on O2 entering lungs
(ventilation)
And blood flow to lungs & tissues (perfusion)
Rate of diffusion V/Q ratio
O2- carrying capacity
Oxygen Transport
O2 transport capacity affected by
hemoglobin
Oxyhemoglobin
CO2 Transport-diffuses into RBC’s & is
rapidly hydrated into carbonic acid
Regulation Of Respiration
CNS control rate, depth, & rhythm
Change in chemical content of O2, CO2 can
stimulate chemorecptors which regulate
neural regulators to adjust rate & depth of
ventilation to maintain normal Arterial Blood
Gases.
Factors Affecting Cardiopulmonary
Functioning
Physiological
Age
Medications
Stress
Developmental
Lifestyle
Environmental
Factors Affecting Oxygenation:
Physiologic
Any factor that affects cardiopulmonary functioning
directly affects the body’s ability to meet O2
demands
Physiologic factors include: decreased O2 carrying
capacity, hypovolemia, increased metabolic rate,
& decreased inspired O2 concentration
Conditions Affecting Chest Wall
Movement
Pregnancy
Obesity
Trauma
Musculoskeletal Abnormalities
Neuromuscular Disease
CNS Alterations
Influences of Chronic Disease
Alterations in Cardiac
Functioning
Disturbances in Conduction
Altered Cardiac Output
Impaired Valvular Function
Impaired Tissue Perfusion (Myocardial)
Disturbances of Conduction
Dysrhythmias-deviation
from NSR
Junctional
Classified by cardiac
response origin of impulse dysrhythmias
Tachycardia
Bradycardia
Supraventricular
dysrhythmias
Ventricular
dysrhythmias
Altered Cardiac Output
Left-sided heart failure
Right-sided heart Failure
Impaired Valvular Function
Stenosis
-Stenosis of valves can cause ventricles to
hypertrophy (enlarge)
Obstruction of Flow
Valve Degeneration
Lead to Regurgitation of Blood
Valves
Impaired Tissue Perfusion:
Myocardial
Insufficient blood flow from coronary arteries to
meet heart O2 demand
Manifested as angina, MI
Angina-transient imbalance between O2 supply &
demand’ resulting in chest pain
Atherosclerosis: most common cause of impaired
blood flow to organs
Myocardial Ischemia
Myocardial Infarction-sudden decrease in
coronary blood flow or an increase in
myocardial oxygen demand without
adequate perfusion
Infarction occurs because of ischemia
(reversible) or necrosis (irreversible) of heart
tissue
Impaired Tissue Perfusion
Cardiac perfusion
Cerebral perfusion (TIA, CVA)
Peripheral vascular perfusion
Incompetent valves
Thrombus formation
Blood alterations (anemia)
Electrical Picture of an MI
Alterations in Respiratory
Function
Goal of ventilation is to produce a normal arterial
CO2 tension (PaCO2) between 35-45mmHg and
maintain normal arterial O2 tension (PaO2)
between 95-100
Alterations affect ventilation or O2 transport
Hyperventilation, Hypoventilation, Hypoxia
Alterations in Respiratory
Function
Hyperventilation- state of ventilation in
excess of that required to eliminate the
normal venous CO2 produced by cell
metabolism
Anxiety, infection, drugs or acid-base
imbalance can produce hyperventilation
Hyperventilation
Lightheadedness
Disorientation
Dizziness
Tachycardia
Chest pain
SOB
Blurred vision
Extremity numbness
Hypoventilation
Alveolar ventilation is inadequate to meet
body’s O2 demand
PaCO2 elevates, PaO2 drops
Severe atelectasis can cause
hypoventilation
Hypoventilation and COPD
Hypoventilation
Disorientation
Lethargy
Dizziness
Headache
Decreased ability to follow instructions
Convulsions
Coma
Dysrhythmias, cardiac death
Hypoxia
Inadequate tissue oxygenation at the cellular level
Deficiency of O2 delivery or O2 utilization at cell
level
Causes: Decreased Hgb, diminished
concentration of inspired O2, decreased diffusion
poor tissue perfusion, impaired ventilation
Hypoxia
Restlessness
Inability to concentrate
Decreased LOC
Dizziness
Behavioral changes
Agitation
Change in vital signs
Cyanosis: Peripheral vs Central
Other Factors Affecting Oxygenation
Age
Environmental
Lifestyle
Medications
Stress
Infection
Pediatric Differences
Cardiac Functioning
Oxygenation
Normal Changes of Aging
Cardiovascular
Vascular
Pulmonary
Renal
Nursing Process
Assessment
History
Physical Exam
Diagnostic Tests
Blood Studies
Assessment: Nursing History
Client’s ability to meet
oxygen needs
Pain
Fatigue
Smoking
Dyspnea
Orthopnea
Environmental
Exposure
Respiratory Infections
Allergies
Health Risks
Medications
Cough
Wheezing
Altered breathing
patterns
Physical Exam
Inspection
Palpation
Percussion
Auscultation
Inspection of Cardiopulmonary
Status
Cyanotic mucous membranes
Pursed lip breathing
Jugular neck vein distention
Nasal faring
Use of accessory muscles
Peripheral or central cyanosis
Edema
Clubbing of fingertips
Altered breathing patterns
Pale conjunctivae
Marked clubbing of the nails.
25Clubbing
Clubbing nails
Palpation
Palpate for thoracic excursion
PMI
Palpation of peripheral pulses
Palpation for skin temperature, capillary refill
Palpation of lower extremities for peripheral
edema
Auscultation
Identification of normal and abnormal breath
sounds
Blood Pressure
Heart sounds S1, S2
Abnormal heart sounds
Murmurs
Bruits
Diagnostic Tests
EKG
Holter Monitor
Stress tests
Echocardiogram
Cardiac cath
TEE
Pulmonary function
tests
Chest x-ray
Arterial blood gases
Pulse ox
Bronchoscopy
Thoracentesis
CT Scan/MRI
Ventilation/Perfusion
Scan
Bronchoscopy/Thoracentesis
Lab Studies
Electrolytes
Cardiac enzymes
BNP
Lipid Profile
Coagulation Studies
CBC
Troponin
D Dimer
C reactive protein
Sputum culture
Throat culture
AFB
Cytology
Nursing Diagnosis
Activity Intolerance
Ineffective Tissue Perfusion
Decreased Cardiac Output
Impaired Gas Exchange
Ineffective Airway Clearance
Ineffective Breathing Pattern
Fatigue
Anxiety
Planning for Care
Develop goals and outcomes
Set Priorities
Select appropriate interventions
Collaborate
Involve patient and family in care
Implementation:
Health Promotion/Prevention
Vaccinations
Healthy Lifestyle
Environmental pollutants
Implementation:
Acute Care
Dyspnea Management
Airway Management
Mobilization of Airway Secretions
Maintenance and Promotion of Lung
Expansion
Maintenance and Promotion of Oxygenation
Breathing Exercises
Hydration
Dyspnea Management
Treat underlying disease process and add
additional therapies as needed:
Pharmacological agents
Oxygen therapy
Physical techniques
Psychosocial techniques
Airway Maintenance
Mobilization of Secretions
Hydration
Humidification
Nebulization
Coughing techniques
Chest PT
Postural drainage
Suctioning
Artificial airways
Suctioning
Oropharyngeal
Nasopharyngeal
Orotracheal
Nasotracheal
Tracheal
Promotion or Maintenance of Lung
Expansion
Positioning of patient
Incentive Spirometer
Chest tubes
Oxygen Therapy
Goal is to prevent or relieve hypoxia
Not a substitute for other treatment
Treated as a drug
Safety precautions
Methods of O2 Delivery
Nasal cannula-1-4 liters/min
Oxygen Mask-Simple face mask, Venturi
mask, Non-rebreather face mask,
Rebreather mask
Home Oxygen Therapy
Medications Affecting
Cardiopulmonary Functioning
Cardiovascular agents: Nitrates, Calcium Channel
Blockers, Beta Blockers, ACE Inhibitors/Blockers
Positive Inotropic Agents (Digoxin)
Antiarrhythmic Agents
Antilipemic Agents (Statins)
Bronchodilators
Cough suppressants/expectorants
Benzodiazepines/Narcotics
Diuretics
Anticoagulants/Antiplatelet Agents
Acute MI Core Measures
www.the jointcommission.org
Aspirin at arrival
Aspirin prescribed at discharge
ACE Inhibitor/ARB prescribed at discharge for left ventricular systolic
dysfunction
Adult smoking cessation counseling
Beta Blocker prescribed at discharge
Beta Blocker at arrival
Thrombolysis within 30 minutes
Statin prescribed at discharge
Percutaneous coronary intervention within 90 minutes
Promoting Cardiovascular
Circulation
Positioning
Medications
Preventing venous stasis
Cardiopulmonary Resusitation
Alterations in Ventilation
COPD
Asthma
SIDS
Acute Respiratory Distress Syndrome
Pneumonia
Alterations in Perfusion
Cardiomyopathy
Congenital Heart Defects
Coronary Artery Disease
Deep Vein Thrombosis
Heart Failure
Hypertension
Dysrhythmias
Peripheral Vascular Disease
Cerebral Vascular Accident
Pulmonary Embolism
Shock
Clicker Question
During the first heart sound, S1 or “Lub”,
what valves are closing?
A. Aortic and pulmonic
B. Tricuspid and mitral
C. Aortic and mitral
D. Mitral and pulmonic
Clicker Question
Nursing care prior to cardiac catheterization
includes all of the following except:
A. Assess for allergy to iodine
B. Evaluation of peripheral pulses
C. Informed consent
D. Clear liquids prior to the test
Clicker Question
Treatment of suspected myocardial
infarction (MI) includes:
A. Oxygen, aspirin, morphine, nitroglycerin
B. Acetaminophen, bedrest, EEG
C. Oxygen, cardiac catheterization
D. Mechanical ventilation, CEA levels,
acetaminophen
Clicker Question
Which of the following is an early sign of
hypoxia?
A. Pallor
B. Restlessness
C. Difficulty breathing
D. Decreased heart rate
Clicker Question
3. When evaluating a postthoracotomy client with
a chest tube, the best method to properly maintain
the chest tube would be to:
A. Strip the chest tube every hour to maintain
drainage.
B. Place the device below the client’s chest.
C. Double clamp the tube except during
assessment.
D. Remove the tubing from the drainage device to
check for proper suctioning.
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Clicker Question
2. A client with a tracheostomy has thick
tenacious secretions. To maintain the
airway, the most appropriate action for the
nurse includes:
A. Tracheal suctioning
B. Oropharyngeal suctioning
C. Nasotracheal suctioning
D. Orotracheal suctioning
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To have a persons Heart in Your
Hands!!!!