1 ANATOMY AND ASSESSMENT - FINAL.pptx.pdf

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NCM 112
CARE OF THE
CLIENT WITH
PROBLEMS IN
OXYGENATION,
ACUTE AND
CHRONIC
REVIEW OF THE
ANATOMY AND
PHYSIOLOGY
OF THE
RESPIRATORY SYSTEM
✔ Babies are born with pink lungs but they darken as we
breathe polluted air.
✔ You breathe on an average of 14-20 times per minute, 20K
(approx.) per day, 7.8M (approx.) per year, and breathed
468M (approx.) in 60 years of
lifetime---INVOLUNTARILY.
✔We lose half liter of water a day through breathing.
This is the water vapor we see when we breathe into
a glass.
✔It is impossible to breathe and swallow
simultaneously.
ANATOMIC AND PHYSIOLOGIC
REVIEW OF THE UPPER AND
LOWER RESPIRATORY TRACT
ANATOMIC AND PHYSIOLOGIC
REVIEW
Composed of:
(1) upper respiratory tract
(2) lower respiratory tract

Together, the two tracts are responsible for
ventilation
*movement of air in and out of the airways
ANATOMIC AND PHYSIOLOGIC
REVIEW
The upper tract (upper airway) warms and
filters inspired air so that…..
The lower respiratory tract (the lungs) can
accomplish gas exchange.

Gas exchange
involves delivering oxygen to the tissues through
the bloodstream and expelling waste gases, such
as carbon dioxide, during expiration
UPPER RESPIRATORY TRACT
▪ Upper airway structures consist of the
1. Nose
2. sinuses and nasal passages
3. pharynx, tonsils and adenoids,
4. larynx, and
5. trachea.
UPPER RESPIRATORY TRACT
▪ Lower airway structures consist of the
1. Lungs : bronchial and alveolar structures
LOWER RESPIRATORY TRACT
▪ The lungs are paired elastic
structures enclosed in the
thoracic cage, which is an
airtight chamber with
distensible walls
LOWER RESPIRATORY TRACT
LUNGS
Each lung is divided into
lobes
Right---3 lobes
Left---2 lobes
The left lobe is slightly
smaller than the right
lobe.
PLEURA
▪ Serous membrane that
lined the lungs and wall of
the thorax.
▪ The visceral pleura covers
the lungs; the parietal
pleura lines the thorax.
PLEURA
Importance:

✔ You breathe 20,000 times (approx.) per day
involuntarily
✔ To avoid friction
MEDIASTINUM
▪ The mediastinum is in the
middle of the thorax,
between the pleural sacs
that contain the two lungs.
▪ Heart, thymus, the aorta
and vena cava, and
esophagus.
BRONCHI AND BRONCHIOLES
▪ There are several division of the bronchi within each lobe of the lung

1. Right and left bronchi
2. Lobar bronchi (three in the right and two in the left lung)
3. Segmental bronchi (10 on the right and 8 on the left)
4. Subsegmental bronchi
5. Bronchioles
6. Terminal bronchioles
7. Respiratory bronchioles------ dead space (150mL of air)
8. Alveolar ducts and sacs
9. Alveoli
ALVEOLI
✔ Oxygen and carbon dioxide exchange takes place in
the alveoli.
✔ arranged in clusters of 15 to 20
ALVEOLI
Three types of alveolar cells---(Pneumocyte)
1. Type I are epithelial cells that form the alveolar walls.
2. Type II are metabolically active; secrete surfactant
-a phospholipid that lines the inner surface and prevents
alveolar collapse.
Reduces surface tension, thereby improving overall lung
function
3. Type III alveolar cell macrophages are large phagocytic
cells that ingest foreign matter (mucus, bacteria)
▪ act as an important defense mechanism
PHYSIOLOGY OF THE
RESPIRATORY SYSTEM
The respiratory system performs this function by
facilitating life-sustaining processes such as:
1. oxygen transport
2. respiration and ventilation, and
3. gas exchange.
LUNG VOLUMES AND LUNG
CAPACITIES
LUNG VOLUMES AND LUNG
CAPACITIES
Lung function which reflects the mechanics of
ventilation, is viewed in terms of lung volumes and
lung capacities.
Lung volumes:
✔ tidal volume,
✔ inspiratory reserve volume,
✔ expiratory reserve volume, and
✔ residual volume.
LUNG VOLUMES AND LUNG
CAPACITIES
Lung function which reflects the mechanics of
ventilation, is viewed in terms of lung volumes and
lung capacities.
Lung capacity:
▪ vital capacity,
▪ inspiratory capacity,
▪ functional
▪ residual capacity, and
▪ total lung capacity
LUNG VOLUMES
Tidal volume (VT or TV)
▪ The volume of air inhaled and exhaled with each
breath
▪ 500 mL or 5–10 mL/kg
LUNG VOLUMES
Inspiratory reserve volume (IRV)
▪ The maximum volume of air that can be inhaled after
a normal inhalation
▪ 3,000 mL
LUNG VOLUMES
Expiratory reserve volume (ERV)
▪ The maximum volume of air that can be exhaled
forcibly after a normal exhalation
▪ 1,100 mL
LUNG VOLUMES
Residual volume (RV)
▪ The volume of air remaining in the lungs after a
maximum exhalation
▪ 1,200 mL
LUNG CAPACITIES
Functional residual capacity (FRC)
▪ The volume of air remaining in the lungs after a
normal exhalation
▪ 2,300 mL
LUNG CAPACITIES
Vital capacity (VC)
▪ The maximum volume of air exhaled from the point of
maximum inspiration
▪ 4,600 mL
LUNG CAPACITIES
Inspiratory capacity (IC)
▪ The maximum volume of air inhaled after normal
expiration
▪ 3,500 mL
LUNG CAPACITIES
Total lung capacity (TLC)
▪ The volume of air in the lungs after a maximum
inspiration
▪ 5,800 mL
GAS EXCHANGE
GAS EXCHANGE
▪ Partial pressure of gases
▪ Pressure exerted by each type of gas in a mixture of
gases.
PARTIAL PRESSURE
ABBREVIATIONS
▪ P = pressure
▪ PO2 = partial pressure of oxygen
▪ PCO2 = partial pressure of carbon dioxide
▪ PAO2 = partial pressure of alveolar oxygen
▪ PACO2 = partial pressure of alveolar carbon dioxide
▪ PaO2 = partial pressure of arterial oxygen
▪ PaCO2 = partial pressure of arterial carbon dioxide
▪ Pv–O2 = partial pressure of venous oxygen
▪ Pv–CO2 = partial pressure of venous carbon dioxide
▪ P50 = partial pressure of oxygen when the hemoglobin is 50% saturated
NEUROLOGIC CONTROL OF
VENTILATION
NEUROLOGIC CONTROL OF
VENTILATION
▪ Resting respiration is the result of cyclical excitation
of the respiratory muscles by the phrenic nerve.
▪ The rhythm of breathing is controlled by respiratory
centers in the brain: Medulla oblongata and Pons
▪ The apneustic center in the lower pons stimulates the
inspiratory medullary center to promote deep,
prolonged inspirations.
▪ The pneumotaxic center in the upper pons is thought to
control the pattern of respirations.
NEUROLOGIC CONTROL OF
VENTILATION
▪ The central chemoreceptors: respond to chemical
changes in the cerebrospinal fluid, which result from
chemical changes in the blood.
▪ The peripheral chemoreceptors: respond first to
changes in PaO2, then to PaCO2 and pH.

The Hering–Breuer Reflex
▪ Safety mechanism of the respiratory center
▪ Ensures that the lungs never over inflates
NEUROLOGIC CONTROL OF
VENTILATION
▪ Proprioceptors in the muscles and joints respond to
body movements causing increase in ventilation.
ROM exercises in an immobile patient stimulate
breathing.
ASSESSMENT OF PATIENTS
WITH
LUNG PROBLEM
ASSESSMENT OF PATIENTS WITH
LUNG PROBLEM
HEALTH HISTORY and GENERAL APPEARANCE:
▪ Dyspnea
▪ Cough
▪ Sputum production
▪ Chest pain
▪ Wheezing
▪ Hemoptysis
▪ Clubbing of Fingers
▪ Cyanosis
DYSPNEA
▪ Subjective feeling of difficult or labored breathing,
shortness of breath
▪ A multidimensional symptom common to many
pulmonary and cardiac disorders
▪ Particularly when there is decreased lung compliance
or increased airway resistance.
DYSPNEA
Tachypnea
▪ Abnormally rapid respiration
Orthopnea
▪ Shortness of breath when lying flat, relieved by sitting or
standing
Stridor
▪ High pitch-pitched sound heard (usually on inspiration) when
someone is breathing through a partially blocked upper airway
Noisy breathing
▪ result from a narrowing of the airway or localized obstruction of
a major bronchus by a tumor or foreign body.
COUGH
▪ Reflex that protects the lungs from the accumulation
of secretions or the inhalation of foreign bodies.
▪ Results from the irritation or inflammation of the
mucous membranes anywhere in the respiratory tract
▪ Mucus, pus, blood, or an airborne irritant, such as
smoke or a gas, may stimulate cough reflex.
COUGH
SPUTUM PRODUCTION
▪ Reaction of the lungs to any constantly recurring
irritant and often results from persistent coughing
▪ The nature of the sputum is indicative of its cause.
COUGH
Bacterial infection
▪ Profuse amount of purulent sputum (thick and yellow, green or rust
colored)
Viral bronchitis
▪ Thin mucoid sputum
Chronic bronchitis/bronchiectasis
▪ Gradual increase of sputum over time
Lung tumor
▪ Pink-tinged mucoid sputum
Pulmonary edema
▪ Profuse, frothy, pink material
Lung abscess
▪ Foul smelling sputum and bad breath
CHEST PAIN
▪ Chest pain associated with pulmonary conditions
may be sharp, stabbing, and intermittent, or it may be
dull, aching, and persistent.
▪ The pain usually is felt on the side where the
pathologic process is located
▪ Pleuritic pain from irritation of the parietal pleura is
sharp and seems to “catch” on inspiration
“like the stabbing of a knife”
WHEEZING
▪ A high-pitched, musical sound heard mainly on expiration
(asthma) or inspiration (bronchitis).
▪ Major finding in a patient with bronchoconstriction or
airway narrowing.
▪ It is heard with or without a stethoscope, depending on its
location.
▪ Rhonchi are low-pitched continuous sounds heard over
the lungs in a partial airway obstruction.
▪ It is heard with or without a stethoscope, depending on its
location.
HEMOPTYSIS
Expectoration of blood from the respiratory tract
The most common causes are:
▪ Pulmonary infection
▪ Carcinoma of the lung
▪ Abnormalities of the heart or blood vessels
▪ Pulmonary artery or vein abnormalities
▪ Pulmonary emboli and infarction
HEMOPTYSIS
▪ Determine the source of bleeding
*hemoptysis is reserved for blood coming from the respiratory tract
▪ Bloody sputum from the nose or the nasopharynx—sniffing
Note:
▪ Blood from the lung is usually bright red, frothy, and mixed with
sputum.
alkaline pH
▪ If the hemorrhage is in the stomach—hematemesis
“coffee grounds”
acid pH
CLUBBING OF FINGERS
▪ Sign of lung disease
found in patients
with chronic
hypoxic conditions,
chronic lung
infections, and
malignancies of the
lung.
CYANOSIS

▪ bluish coloring of the skin
▪ very late indicator of hypoxia
▪ Cyanosis appears when the hemoglobin becomes
unoxygenated, reducing the effective circulating
hemoglobin to two thirds of the normal level.
PHYSICAL ASSESSMENT OF THE
RESPIRATORY SYSTEM
CYANOSIS
▪ Affected by room lighting
▪ Patient’s skin color

✔ Central cyanosis
✔ Peripheral cyanosis
 PHYSICAL ASSESSMENT OF
THE LOWER RESPIRATORY
STRUCTURES AND BREATHING
THORACIC INSPECTION

✔ Color
✔ Turgor
✔ Asymmetry
THORACIC INSPECTION
PHYSICAL ASSESSMENT OF THE
LOWER RESPIRATORY STRUCTURES
AND BREATHING
When you perform lung physical assessment, what
technique will you use?
a. inspection, auscultation, percussion and palpation
b. Auscultation, inspection, percussion and palpation
c. Inspection, palpation, percussion and auscultation
d. Palpation, percussion, auscultation and inspection
CHEST CONFIGURATION

▪ the ratio of the anteroposterior diameter to the lateral
diameter is 1:2.
four main deformities of the chest associated:
▪ barrel chest,
▪ funnel chest (pectus excavatum),
▪ pigeon chest
▪ (pectus carinatum), and
▪ kyphoscoliosis
CHEST CONFIGURATION
Barrel Chest
✔ occurs as a result of overinflation of the lungs.
✔ increase in the AP diameter of the thorax
✔ Emphysema
HALLMARK SIGN OF
EMPHYSEMA
CHEST CONFIGURATION
Funnel Chest (Pectus Excavatum)
✔ occurs when there is a depression in the lower
portion of the sternum.
✔ compress the heart and great vessels, resulting in
murmurs.
✔ May occur with rickets or Marfan’s syndrome.
FUNNEL CHEST (PECTUS
EXCAVATUM)
CHEST CONFIGURATION
Pigeon Chest (Pectus Carinatum).
▪ occurs as a result of displacement of the sternum.
▪ increase in the AP diameter.
▪ may occur with rickets, Marfan’s syndrome, or severe
kyphoscoliosis
PIGEON CHEST (PECTUS
CARINATUM)
CHEST CONFIGURATION
Kyphoscoliosis
▪ characterized by elevation of the scapula and a
corresponding S-shaped spine.
▪ limits lung expansion within the thorax.
▪ may occur with osteoporosis and other skeletal
disorders that affect the thorax
KYPHOSCOLIOSIS
THORACIC PALPATION
▪ palpates the thorax for tenderness, masses, lesions,
respiratory excursion, and vocal fremitus
Respiratory excursion
▪ thoracic expansion
▪ may disclose significant information about thoracic
movement during breathing
▪ Place both hands posteriorly at the level of T9 or T10.
▪ Observe for symmetry.
THORACIC PALPATION
TACTILE FREMITUS/FREMITUS
▪ Sound generated by the larynx travels distally along
the bronchial tree to set the chest wall in resonant
motion.
TACTILE FREMITUS: detection of the resulting
vibration on the chest wall by touch
THORACIC PALPATION
TACTILE FREMITUS/FREMITUS
▪ “ninety-nine” or “one, two, three,” or “eee, eee, eee”
▪ The vibrations are detected with
the palmar
surfaces of the fingers and hands, or the
ulnar aspect of the extended hands, on
the thorax.
▪ BONES ARE NOT ASSESSED!
TACTILE FREMITUS/FREMITUS
 The nurse is assessing tactile fremitus in a
client with pneumonia. For this examination,
the nurse should use the:
a. fingertips.
b. ulnar surface of the hand.
c. dorsal surface of the hand.
d. finger pads.
THORACIC PERCUSSION
▪ Percussion sets the chest wall and underlying
structures in motion, producing audible and tactile
vibrations.
▪ determine whether underlying tissues are filled with
air, fluid, or solid material.
THORACIC AUSCULTATION
▪ Useful in assessing the flow of air through the
bronchial tree and in evaluating the presence of fluid
or solid obstruction in the lung structures.
▪ Auscultates for normal breath sounds, adventitious
sounds, and voice sounds.
▪ Examination includes auscultation of the anterior,
posterior, and lateral thorax
THORACIC AUSCULTATION
BREATH SOUNDS
Normal breath sounds are identified as:
✔ vesicular,
✔ bronchovesicular, and
✔ bronchial (tubular) breath sounds
THORACIC AUSCULTATION
Abnormal (Adventitious) Breath Sounds
▪ An abnormal condition that affects the bronchial tree
and alveoli may produce adventitious (additional)
sounds.
▪ Adventitious sounds are divided into two categories:
1. Crackles: discrete, noncontinuous sounds
2. Wheezes: continuous musical sounds
THORACIC AUSCULTATION
CRACKLES (RALES)
1. Coarse crackles
▪ Discontinuous popping sounds heard in early
inspiration; harsh, moist sound originating in the
large bronchi
2. Fine crackles
▪ Discontinuous popping sounds heard in late
inspiration; sounds like hair rubbing together;
originates in the alveoli
THORACIC AUSCULTATION
WHEEZES
1. Sibilant wheezes
▪ Continuous, musical, high-pitched, whistle like
sounds heard during inspiration and expiration
caused by air passing through narrowed or partially
obstructed airways; may clear with coughing
▪ Bronchospasm, asthma, and build up of secretions
THORACIC AUSCULTATION
WHEEZES
2. Sonorous wheezes (rhonchi)
▪ Deep, low-pitched rumbling sounds heard primarily
during expiration; caused by air moving through
narrowed tracheobronchial passages
▪ Secretions or tumor
THORACIC AUSCULTATION
FRICTION RUBS (Pleural friction rub)
▪ Harsh, crackling sound, like two pieces of leather
being rubbed together.
▪ May subside when patient holds breath. Coughing
will not clear sound.
▪ Secondary to inflammation and loss of lubricating
pleural fluid
THORACIC AUSCULTATION
VOICE SOUNDS
Vocal resonance:
▪ The sound heard through the stethoscope as the
patient speaks
▪ larynx 🡪chest wall 🡪bronchi 🡪 alveolar tissue
▪ During the process, the sounds are diminished in
intensity and altered so that syllables are not
distinguishable.
▪ “ninety-nine” or “eee”
THORACIC AUSCULTATION
VOICE SOUNDS
▪ Bronchophony describes vocal resonance that is
more intense and clearer than normal.
▪ Egophony describes voice sounds that are distorted
(E🡪A)
▪ Whispered pectoriloquy: heard only in the presence
of rather dense consolidation of the lungs.

▪ All test for consolidation!
END