Oxygen Therapy
Introduction
& history
Oxygen
is an essential molecule for life. However oxygen is a commonly and wrongly
prescribed drug. Oxygen was isolated by Joseph Priestley in 1772. Thomas Beddoes
used oxygen for the first time in early 1800s for medical disorders. Oxygen was
commercially produced first time by Carl Von Linde in 1895 by fractional
distillation of liquid air. However in
last few decade only oxygen use have gained momentum. Response to hypoxia is variable among individual
organs and cells. Neurons, cardiomyocytes, and renal tubular cells are highly
sensitive to a sudden reduction in oxygen supply and are unable to survive long
periods of hypoxia. After complete cessation of cerebral perfusion, nuclear
magnetic resonance (NMR) measurements show a 50% decrease in cellular adenosine
triphosphate (ATP) within 30 seconds and irreversible damage occurs within 3
minutes. Kidneys and liver can tolerate 15–20 minutes of total hypoxia,
skeletal muscle 60–90 minutes, and vascular smooth muscle 24–72 hours. The most
extreme example of hypoxic tolerance is that of hair and nails which can grow
for several days after death. Goal of oxygen therapy is to-
•
Treat hypoxaemia
•
Decrease work of
breathing
•
Decreased
myocardial work
Oxygen
transport
Knowledge of oxygen transport mechanism is an
important to understand oxygen therapy. Only the salient points of oxygen
transport mechanism are given. Key steps in oxygen transport are uptake in the lungs, carrying
capacity of blood, global delivery from lungs to tissue, regional distribution
of oxygen delivery, diffusion from capillary to cell and cellular use of
oxygen. The delivery of oxygen from capillary blood to the
cell depends on:
• Factors that influence diffusion
• Rate of oxygen delivery to the capillary (DO2);
• Position of the oxygen-haemoglobin dissociation
relationship
• Rate of cellular oxygen utilisation and uptake
(VO2).
Figure1 : Oxygen
transport from atmosphere to mitochondria. Values in parentheses for a normal
75 kg individual (BSA 1.7 m2) breathing air (FIO2 0.21) at standard atmospheric
pressure (PB 101 kPa). Partial pressures of O2 and CO2 (PO2, PCO2) in kPa;
saturation in %; contents (CaO2, CvO2) in ml/l; Hb in g/l; blood/gas flows (Qt,
Vi/e) in l/min. P50 = position of oxygen haemoglobin dissociation curve; it is
PO2 at which 50% of haemoglobin is saturated (normally 3.5 kPa). DO2 = oxygen
delivery; VO2 = oxygen consumption, VCO2 = carbon dioxide production; PIO2, PEO2
= inspired and mixed expired PO2; PECO2 = mixed expired PCO2; PAO2 = alveolar
PO2.
Clinical
feature
Early detection of tissue
hypoxia is essential for successful treatment. But it is not always easy as the
clinical features are often nonspecific. Clinical manifestations of hypoxia
are highly variable and nonspecific and depend on both duration of the hypoxia
(acute or chronic) and the individual response to it. Symptoms and signs
associated with acute hypoxia include changes in mental status, dyspnea,
tachypnea, respiratory distress, and cardiac arrhythmias. Alterations in mental
status due to hypoxia range from impaired judgment to confusion or coma.
Cyanosis which is considered a hallmark of hypoxia, occurs only when the
concentration of reduced hemoglobin in the blood is 1.5
g/dl or greater. But this is not a reliable sign, as it may be absent in anemia
and during periods of poor peripheral perfusion.
Organ specific
sign and symptoms of hypoxia
|
|
System
|
Sign
and symptoms
|
Respiratory
|
Tachypnea, breathlessness,
dyspnea, cyanosis
|
cardiovascular
|
Increased cardiac
output, palpitations, tachycardia, arrhythmias, hypotension, angina,
vasodilatation, diaphoresis, and shock
|
CNS
|
Headache, impaired
judgment, inappropriate behavior, confusion, euphoria, delierium,
restlessness, papilledema, seizures, obtundation, coma
|
neuromuscular
|
Weakness, tremor,
asterixis,
hyper-reflexia, incoordination
|
metabolic
|
Sodium and water
retention, lactic acidosis
|
Mechanism
of hypoxia
Hypoxia is deficiency
of oxygen in tissue and hypoxemia is deficiency of oxygen in blood. Hypoxia may
occur even in absence of hypoxemia. There are several mechanisms of hypoxia.
Understanding of these mechanisms will help to treat the patient adequately.
The various mechanisms is being summarised in table 1.
Table1
: Mechanism of hypoxemia
Mechanism
|
Clinical conditions
|
Diagnostic criteria
|
General treatment
|
Response to oxygen
therapy
|
Low FiO2
|
High altitude, fire,
smoke
|
History, low
atmospheric pressure of oxygen
|
Supportive care
|
Rapid
|
Hypoventilation
|
Neuromuscular disease,
CNS depression, narcotics
|
Increase in PaCO2
similar to decrease in PaO2
|
ventilator care
(invasive/non invasive)
|
Good initial response
|
V/Q mismatch
|
COPD
|
Increase PAO2-PaO2,
corrected by 100% O2
|
Bronchodilator,
bronchial hygine
|
Moderately rapid
|
Right to left shunt
|
Pneumonia, collapse,
pulmonary edema
|
Not corrected by 100%
O2
|
Antibiotics,
diuretics, PEEP
|
variable
|
Diffusion defect
|
Interstitial lung
diseases
|
Low vital capacity,
low diffusion capacity
|
Corticosteroids,
immunosupresant etc
|
Moderately rapid
|
Indications
of oxygen therapy
In
acute care/ emergency setting
Role
of oxygen therapy in acute care setting is very essential. Restoration of global oxygen delivery is an important goal in early
resuscitation but thereafter circulatory manipulation to sustain “supranormal”
oxygen delivery does not improve survival and may be harmful. There are conditions
where oxygen is life saving particularly in acute conditions. Timely
administration of oxygen and in adequate dose is very important. There are
diseases where oxygen need to be give in higher dose and in some conditions it
need to be give in controlled amount.
Table
2: indications of oxygen in emergency care setting
Clinical conditions (grade of recommendations)
|
Comment
|
|
Critical illnesses requiring high levels of supplemental oxygen
|
Cardiac arrest or resuscitation(Grade D)
Shock, sepsis, major trauma,
near-drowning, anaphylaxis,
major pulmonary haemorrhage(Grade D)
Major head injury(Grade D)
Carbon monoxide poisoning(Grade C)
|
|
Serious illnesses requiring moderate levels of supplemental oxygen if
the patient is hypoxaemic
|
Acute hypoxaemia
(cause not yet diagnosed) (Grade D)
Acute asthma (Grade C)
Pneumonia ( Grade C)
Lung cancer (Grade C)
Postoperative breathlessness (Grade D)
Acute heart failure (Grade D)
Pulmonary embolism (Grade D)
Pleural effusions (Grade D)
Pneumothorax (Grade C & D)
Deterioration of lung fibrosis
or other interstitial lung
disease (Grade D)
Severe anaemia Grade B & D)
Sickle cell crisis (Grade B)
|
The initial oxygen therapy is nasal cannulae at 2–6 l/min (preferably)
or simple face mask at 5–10 l/min unless stated otherwise.
|
conditions requiring controlled or low-dose oxygen therapy
|
COPD(Grade C)
Exacerbation of CF(Grade D)
Chronic neuromuscular
Disorders(Grade D)
Chest wall disorders(Grade D)
Morbid obesity (Grade D)
|
60 min [Grade D]
|
Conditions for which patients should be monitored closely but oxygen
therapy is not required unless the patient is
hypoxaemic
|
Myocardial infarction and acute
coronary syndromes(Grade D)
Stroke (Grade B)
Pregnancy and obstetric
Emergencies (Grade A- D)
Hyperventilation or dysfunctional
Breathing (Grade C)
Most poisonings and drug
Overdoses (Grade D)
Poisoning with paraquat or
Bleomycin (Grade C)
Metabolic and renal disorders (Grade D)
Acute and subacute neurological
and muscular conditions
producing muscle weakness (Grade C)
|
|
Long
term oxygen therapy
Long term oxygen
therapy (LTOT) is a mode of delivery oxygen particular for chronic respiratory
diseases with hypoxia. Initially it was established in patient of chronic
obstructive pulmonary disease (COPD) and
later on extrapolated in various other diseases like interstitial lung disease,
bronchiectasis, cystic fibrosis, khyphoscoliosis, sleep apnea, severe cardiac
failure etc. Nocturnal oxygen therapy trial (NOTT) and medical research council
oxygen therapy trial long back has established the role of LTOT in COPD
patient.
General selection
criteria for LTOT-
- A definitive documented diagnosis of chronic hypoxemia (3 week apart)
- Patient is on optical medical management and stable
- Oxygen administration should have been shown to improve hypoxemia and provide clinical benefit
Specific criteria for
LTOT-
- At rest, in non recumbent position, the PaO2 of 55 mm Hg or less
- Patient with PaO2 between 55 to 60 mm Hg is considered for LTOT if-
- Patient on optimal medical treatment with demonstrable hypoxic organ dysfunction like secondary pulmonary arterial hypertension, cor pulmonale, polycythemia or CNS dysfunction
- When there is demonstrable fall in PaO2 < 55 mm Hg during sleep, associated with disturbed sleep pattern, cardiac arrhythmias or pulmonary hypertension. These patient may be benefited from nocturnal oxygen therapy.
- When there is demonstrable fall in PaO2 during exercise and oxygen administration is shown to improve exercise performance, duration or capacity. These patient may be benefited from oxygen therapy during exercise.
For LTOT oxygen supply
source can be compressed gas cylinder, liquid oxygen system and oxygen
concentrator. Delivery devices includes nasal cannulae, prongs and masks. There
are some oxygen conserving devices which reduce wastage and cost. These devices
includes reservoir oxygen delivery, electromechanical pulsing device,
transtracheal catheter etc.
Oxygen
delivery devices
Method of oxygen delivery is determined by degree of
hypoxaemia, required precision,
comfort of the
patient, cost and availability. Oxygen delivery systems are basically two
types-
- Rebreathing systems
- Have a CO2 absorber
- Used in anaesthesia
- Non-rebreathing systems
a) Low flow (variable performance)
b) High flow (fixed performance)
Table3: low flow and high
flow system
Low flow system
|
High flow system
|
Nasal cannula and catheters
Facemasks
-Simple facemask
-Reservoir masks
-Partial rebreather
-Non rebreathers
Endotracheal and tracheostomy tubes with T Piece
|
Venturi masks
Non rebreathing reservoir mask with blending device
and high flow meters
Endotracheal and tracheostomy tubes with mechanical
ventilation
|
FiO2 depends upon:
•
Size of available oxygen reservoir
•
Flow rate
•
Breathing pattern (VT and RR)
|
FiO2 depends on:
•
velocity of the jet (the size of orifice and oxygen flow rate)
•
size of the valve ports
High flow systems deliver about 40 l/min of gas
through the mask, which is usually sufficient to meet the total respiratory
demand
This ensures that the breathing pattern will not
affect the FiO2
|
Table4 :Following is an
example how FiO2 depends
on ventilatory minute volume and flow rate of oxygen.
Patient in respiratory distress
|
Stable patient
|
|
Ventilatory
minute volume
(Respiratory
rate x
tidal volume)
|
30 l/min
(40 breaths/min x
750 ml/breath)
|
5 l/min
(10 breaths/min x
500 ml/breath)
|
Oxygen
flow rate
|
2L/min
|
2L/min
|
Calculation
of inspired
oxygen
concentration
(FiO2)
|
2 l/min of 100% oxygen
+
28 l/min of air drawn into the
mask (21% oxygen)
=
30 l/min minute volume
Thus
FiO2 =
(1.0x2) + (0.21x28) /30
= 0.26 (26%)
|
2 l/min of 100% oxygen
+
3 l/min of air drawn into the
mask (21% oxygen)
=
5 l/min minute volume
Thus
FiO2 =
(1.0x2) + (0.21x3)/
5= 0.53 (53%)
|
Table5
: delivery devices and FiO2
Delivery devices
|
Oxygen flow(lit/min)
|
FiO2
|
Nasal cannula
|
1
2
3
4
5
6
|
24%
28%
32%
36%
40%
44%
|
Simple face mask
|
6-10
|
40-60%
|
Reservoir mask
|
6-10
|
40-60%
|
Partial rebreathing
|
8-10
|
35-80%
|
Non rebreahting
|
8-10
|
40-100%
|
Unconventional oxygen
delivery
In critically ill patient conventional oxygen delivery
system may not work all the time. Therefore alternate modalities of oxygen
carriers have developed and are being used in certain clinical situation. They
have shown some early promising result and may play a bigger role in days to
come. Theses alternate systems includes-
- Blood substitutes-
Due to complication related to blood transfusion and
need for safer alternative to blood that can carry oxygen scientist has
developed several blood substitute. These artificial oxygen carriers are of two
types-
- Hemoglobin based oxygen carriers (HBOC)-
In HBOC hemoglobin is modified to improve oxygen off
loading by decreasing oxygen affinity. This at present in investigational
stage. Other red cell substitutes under trial are polymerized, pyridoxylated,
stroma free human hemoglobin and oligomeric hemoglobin solution.
- Perfluorocarbon based oxygen carriers-
Chemically inert synthetic molecules and can augent
oxygen delivery to tissue.
- Extracorporeal membrane oxygenation (ECMO)-
It is a artificial technique to provide life support
when lung is unable to maintain sufficient oxygenation of the body’s organ
system. It is a modified cardiopulmonary bypass technique where patient’s
circulation is connected to a external blood pump and membrane oxygenator.
- Heliox therapy-
It is a mixture of helim and oxygen with reduced
density and viscosity of oxygen in a concentration depended manner. Clinical
utility of heliox has been observer in decompression illness, severe asthma,
COPD, upper airway obstruction, broncholitis, croup, post extubation stridor
etc.
How
to calculate required FiO2 ?
The amount of required
FiO2 can be calculated from alveolar gas equation-
PAO2=FIO2(PB-PH2O)-PACO2[FIO2 +
(1-FIO2) / R]
Where PAO2 is partial
pressure of alveolar oxygen, FiO2 is fraction of inspired oxygen, PB
barometric pressure, PH2O
water vapor pressure (usually 47mmHg), PACO2 is partial pressure of alveolar
carbon dioxide (which is usually similar to PaCO2 that is partial pressure of
carbon dioxide in arterial blood) and R is the respiratory quotient (0.8)
In abbreviated from the
alveolar gas equation is PAO2=FIO2(PB-47)-1.2(PaCO2)
FiO2 is calculated for
the equation bellow after calculation PAO2 from alveolar gas equation
FiO2 = (PAO2 + PaCO2 /
R )/ PB-PH2O
For
example a patient has a PaO2 of 41mmHg on FiO2 of 40% (0.4)
and PaCO2 is 25 mmHg, his arterial (A - aO2) oxygen gradient calculated as
follows
PAO2=FIO2
(PB-47)-1.2(PaCO2)
PAO2=0.4(760-47)-1.2(25)=285.2-30=255.2
Therefore arterial (A -
aO2) oxygen gradient is 255.2- 41= 214.2
To increase PaO2 to 60
mmHg the inspired oxygen tension should be 214.2+60= 274.2
Therefore required FiO2
is
(PAO2 + PaCO2 / R)/
PB-PH2O= (274.2+ 30)/713= 0.42
Oxygen
in flight
Some patient required
oxygen during flight. The following table shows the British Thoracic Society
recommendations. Since hypoxic challenge test is not available widely in India
we have to recommend according to SpO2 level.
Table 6:
Pulse oxymetry
|
recommendation
|
SpO2 >95%
|
Oxygen not required
|
SpO2 92-95% without
risk factors
|
Oxygen not required
|
SpO2 92-95% with risk
factors (eg COPD, asthma, previous venous thromboembolism etc)
|
Hypoxic challenge
test
|
SpO2 <92%
|
In flight oxygen
|
After Hypoxic challenge test
|
|
Blood gas report
|
recommendation
|
PaO2 >55 mmHg
|
Oxygen not required
|
PaO2 50-55 mmHg
|
borderline
|
PaO2 <50 mmHg
|
In flight oxyen
|
How
to write an oxygen prescription?
In study it has been found
that 21% of prescriptions inappropriate and 85%patients inadequately supervised.
Oxygen should always be prescribed or ordered on a
designated Document. The use of oxygen by paramedics, nurses, doctors,
physiotherapists and others in emergency situations is similar to the use of
all other medicinal products by these people. Clinical governance requires that
the intentions of the clinician who initiates oxygen therapy should be
communicated clearly to the person who actually administers oxygen to the
patient and an accurate record must be kept of exactly what has been given to
the patient Safe and effective treatment
prescriptions should contain-
Ø
The indication
Ø
flow rate
Ø
delivery system
Ø
duration
Ø how to monitoring of
treatment
Ø specific instruction during
exercise and sleep if indicated
Side
effect
Inappropriate dose and
failure to monitor treatment can have serious consequences. Vigilant monitoring
to detect and correct adverse effects swiftly is essential. The
toxic effects of oxygen on the lung occur due to physiological disturbances
caused by excess oxygen administration or free radical production during
hyperoxic exposure that override the intrinsic antioxidant defence mechanism. Physiological
complications includes-
- Suppression of hypoxic ventilator drive seen patient with chronic hypoxemia and hypercapnea whose ventilator drive is primarily driven by hypoxia (eg COPD). This can be prevented by controlled oxygen delivery.
- Absorption atelectasis seen in patient receiving very high FiO2.
- FiO2 >80% cause mild increase in peripheral vascular resistance and mild decrease in cardiac output.
- Inhalation of 100% FiO2 causes about 10% decrease in minute ventilation and decrease in diffusion capacity.
Excess
free radicals interact with cellular components, resulting in cytotoxic events
which produce a characteristic cascade of biochemical, cellular, morphologic, and
physiological changes. The biochemical reactions, in turn, result in a sequence
of characteristic cellular and morphologic changes. Four basic phases
constitute the development of oxygen toxicity in lung tissue. The first three
phases—initiation, inflammation, and destruction—occur during exposure to both
lethal and sublethal doses of hyperoxia. The fourth phase—proliferation and
fibrosis—occurs if there is re-exposure to sublethal oxygen levels. Therefore
it is essential to administer oxygen in adequate dose and stop oxygen therapy
when it is no longer indicated.
Pulmonary Changes
during Hyperoxic Exposure in Humans
|
||
O2 at 1 atm
|
Duration of exposure
|
Pathophysiological
changes
|
100%
|
>12 h
|
Decreased
tracheobronchial clearance; decreased forced vital capacity; cough; chestpain
|
>24hr
|
Altered endothelial
function
|
|
>36hr
|
Increased
alveolar-arterial oxygen gradient; decreased carbon monoxide diffusing
capacity
|
|
>48hr
|
Increasing alveolar
permeability; pulmonary
edema; surfactant
inactivation
|
|
>60hr
|
Acute respiratory
distress syndrome
|
|
60%
|
7 days
|
Mild chest
discomfort without changes in lung
mechanics; possible
changes in morphometry
|
24-28%
|
months
|
Subclinical
pathological changes; no clinical toxicity
documented
|
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