Emergency 2016; 4 (2): 65-71

OR I G I N A L RE S E A RC H

Ventilator Weaning and Spontaneous Breathing Trials; an
Educational Review
Hossam Zein1, Alireza Baratloo2, Ahmed Negida1∗, Saeed Safari2

1. Faculty of medicine, Zagazig University, Zagazig, Egypt.

2. Emergency Department, Shohadaye Tajrish Hospital, Shahid Beheshti University of Medical Sciences, Tehran, Iran.

Received: February 2016; Accepted: March 2016

Abstract: The term "weaning" is used to describe the gradual process of decreasing ventilator support. It is estimated that
40% of the duration of mechanical ventilation is dedicated to the process of weaning. Spontaneous breathing
trial (SBT) assesses the patient’s ability to breathe while receiving minimal or no ventilator support. The collec-
tive task force in 2001 stated that the process of SBT and weaning should start by assessing whether the underly-
ing cause of respiratory failure has been resolved or not. Weaning predictors are parameters that are intended to
help clinicians predict whether weaning attempts will be successful or not. Although the international consen-
sus conference in 2005 did not recommend their routine use for clinical decision making, researchers did not
stop working in this area. In the present article, we review some of the recent studies about weaning predictors,
criteria, procedure, as well as assessment for extubation a mechanically ventilated patient.

Keywords: Ventilator weaning; mechanical ventilation; emergency service, hospital; airway extubation; ventilator induced
lung injury

© Copyright (2015) Shahid Beheshti University of Medical Sciences

Cite this article as: Zein H, Baratloo A, Negida A, Safari S. Ventilator Weaning and Spontaneous Breathing Trials; an Educational Review.

Emergency. 2016; 4 (2): 65-71.

1. Introduction

T
he term "weaning" is used to describe the gradual pro-

cess of decreasing ventilator support. It is estimated

that 40% of the duration of mechanical ventilation is

dedicated to the process of weaning (1). Delayed weaning

can lead to complications such as ventilator induced lung

injury (VILI), ventilator associated pneumonia (VAP), and

ventilator induced diaphragmatic dysfunction (2-4). On the

other hand, premature weaning can lead to complications

like loss of the airway, defective gas exchange, aspiration and

respiratory muscle fatigue (5-7). Spontaneous breathing trial

(SBT) assesses the patient’s ability to breathe while receiving

minimal or no ventilator support. The collective task force in

2001 stated that the process of SBT and weaning should start

by assessing whether the underlying cause of respiratory

failure has been resolved or not (2). There is no consensus

about what criteria should be used to assess reversal of the

∗Corresponding Author: Ahmed Negida; Faculty of medicine, Zagazig Uni-
versity, Zagazig, El-Sharkia, Egypt. Email: ahmed01251@medicine.zu.edu.
eg ; postal code: 44519; Tel: +201125549087

underlying condition. A combination of subjective and ob-

jective criteria is usually used to determine disease reversal.

Usually the criteria used are improvement of gas exchange,

improvement of mental status, neuromuscular functional

assessment and radiographic signs (7). However, it should

be kept in mind that some patients who don’t meet these

criteria are eventually successfully weaned (8). Weaning pre-

dictors are parameters that are intended to help clinicians

predict whether weaning attempts will be successful or not.

Although the international consensus conference in 2005

did not recommend their routine use for clinical decision

making, researchers did not stop working in this area (9).

In the present article, we review some of the recent studies

about weaning predictors, criteria, procedure, as well as

assessment for extubation a mechanically ventilated patient.

2. Weaning predictors

2.1. Heart rate variability

The process of weaning leads to changes in the hemody-

namic and autonomic nervous systems. Two prospective ob-

servational studies showed that reduced heart rate variability

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H. Zein et al. 66

during spontaneous breathing trials (SBT) was significantly

associated with extubation failure (10-12). Acrentales et al.

found that spectral coherence between heart rate variability

and respiratory flow signals could predict extubation failure

with good sensitivity and specificity (13). However, all these

results still need validation in larger groups of patients.

2.2. Sleep quality

Poor quality of sleep may affect the function of the respi-

ratory muscles and weaning outcome. In a cross sectional

study, Chen et al. assessed the quality of sleep using the

Verran and Snyder-Halpern Sleep Scale and found that poor

quality of sleep was significantly associated with weaning

failure (14).

2.3. Hand grip strength

Muscle weakness can negatively affect the weaning outcome

(15). Cottereau et al. assessed handgrip strength by a hand-

held dynamometer and found that handgrip strength was

significantly associated with difficult or prolonged weaning

but not with extubation failure (16).

2.4. Diaphragmatic dysfunction

The acquired diaphragmatic dysfunction following pro-

longed mechanical ventilation can affect the weaning out-

come (17). DiNino et al. assessed diaphragmatic dysfunction

by measuring the difference between diaphragm thickness at

the end of inspiration and expiration using ultrasonography

to view the diaphragm in the zone of apposition. They found

that a difference of 30% or more could predict extubation fail-

ure with a sensitivity of 88% and a specificity of 71% (18).

2.5. Oxidative stress markers

Oxidative stress is a key mechanism involved in ventilator

induced respiratory muscle dysfunction. Verona et al. esti-

mated the plasma levels of oxidative stress markers before

and after SBT. They found higher plasma concentration of

malondialdehyde and vitamin C, and lower level of nitric

oxide in plasma were significantly associated with SBT failure

(19).

3. Weaning criteria

Table 1 shows some of derivate criteria of readiness for wean-

ing trial (20, 21). According to the international consensus

conference recommendations in 2005, these criteria should

be thought of as considerations rather than as rigid thresh-

olds that patients must meet all of them to be successfully

weaned. Because many patients were successfully discon-

tinued from the ventilator although they didn’t meet one or

more of them (9).

Table 1: Criteria of readiness for weaning trial

Criteria
Subjective assessment

Adequate cough
No neuromuscular blocking agents
Absence of excessive trachea-bronchial secretion
Reversal of the underlying cause for respiratory failure
No continuous sedation infusion or adequate mentation

on sedation
Objective measurements

Stable cardiovascular status
Heart rate ≤ 140 beat/minute
No active myocardial ischemia
Adequate hemoglobin level ( ≥ 8 g/dl)
Systolic blood pressure 90–160 mmHg
Afebrile (36◦ C < temperature < 38◦ C)
No or minimal vasopressor or inotrope

(< 5 µg/kg/minute dopamine or dobutamine)
Adequate oxygenation

Tidal volume > 5 mL/kg
Vital capacity >10 mL/kg
Proper inspiratory effort
Respiratory rate ≤ 35/minute
PaO2 ≥ 60 and PaCO2 ≤ 60 mmHg
Positive end expiratory pressure ≤ 8 cmH2 O
No significant respiratory acidosis (pH ≥ 7.30)
Maximal inspiratory pressure (MIP) ≤ -20 – -25 cmH2 O
O2 saturation > 90% on FIO2 ≤ 0.4 (or PaO2 /FIO2 ≥ 200)
Rapid Shallow Breathing Index

(respiratory Frequency/Tidal Volume) < 105

4. Weaning procedure

4.1. Planning

Step1:
A weaning plan starts with assessing the ability of the patient

for spontaneous breathing. Three main strategies are used by

clinicians to perform SBT.

SBT Strategies
* T-piece trial, in which only supplemental oxygen is supplied

through a T-piece connected to an endotracheal tube.

* Continuous positive airway pressure (CPAP) trial using a

CPAP level equal to the previous positive end-expiratory

pressure (PEEP) level.

* Invasive ventilation with low level of pressure support (5-8

cmH2O) or automatic tube compensation. There is no cur-

rent evidence suggesting that one of these approaches is su-

perior to the others (22, 23). A recent Cochrane systematic

review concluded that there is no difference between T-piece

trials and pressure support trials regarding extubation fail-

ure and mortality with low quality of evidence. However,

pressure support was found to be superior to T-piece in the

proportion of successful SBT in patients considered to have

simple weaning with moderate quality of evidence (relative

risk 1.09; 95%CI: 1.02-1.17) (24). Neil R MacIntyre suggested

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67 Emergency 2016; 4 (2): 65-71

that the T-piece approach may be considered if there is bor-

derline performance with other techniques or there are con-

cerns that loss of PEEP would precipitate latent cardiac dys-

function or lung failure (7).

SBT Duration
Based on strong evidence, the collective task force in 2001

recommended that the duration of SBT should be at least 30

minutes and not longer than 120 minutes (2). This means

that physicians should wait at least 30 minutes to judge toler-

ance of the SBT, but they shouldn’t wait longer than 120 min-

utes if tolerance of the SBT is not clear (7). The initial few

minutes of the SBT should be monitored closely before judg-

ment is made to continue the SBT. There are some evidence

regarding the harmful effects of respiratory muscle fatigue, if

they occur early in failing SBTs (7, 25-27).

Criteria of successful SBT
Table 2 illustrates the criteria used by clinicians to judge tol-

erance of SBTs (20). According to Neil R MacIntyre, these cri-

teria should be interpreted in the context of each other and

as changes from baseline, not as rigid thresholds (7).

Definition of weaning outcome based on SBT
The International Consensus Conference in 2005 suggested a

new classification of weaning outcomes (table 3). This clas-

sification has been shown in multiple observational studies

to have prognostic value. Some studies showed that only the

prolonged weaning group significantly had higher mortality

and longer hospital stay compared to the other two groups

(28-31). Jeong et al. concluded that ventilator free days, ex-

tubation failure, tracheostomy, and mortalities increased sig-

nificantly across groups (32). Funk et al. also concluded that

ventilator free days and intensive care unit (ICU) free days

increased significantly in the difficult and prolonged classes

(31).

Step 2 :
If SBT was successful, step 2 would be assessment for airway

removal. But, if SBT was unsuccessful, the collective task

force in 2001 (2) recommended the following processes as

step 2:

* Searching for an underlying cause of respiratory failure and

Table 2: Criteria of successful spontaneous breathing trials

Respiratory rate < 35 breaths/minute
Good tolerance to spontaneous breathing trials
Heart rate < 140 /minute or heart rate variability of >20%
Arterial oxygen saturation >90% or PaO2 > 60 mmHg on
FiO2 <0.4
80 < Systolic blood pressure < 180 mmHg or <20% change from
baseline
No signs of increased work of breathing or distress *
* Accessory muscle use, paradoxical or asynchronous rib cage-
abdominal movements, intercostal retractions, nasal flaring,
profuse diaphoresis, agitation.

correcting it if possible.

* Using a comfortable non-fatiguing form of respiratory

support. Neil R MacIntyre showed that this support should

be interactive and well synchronized with the patient effort

(33).

* Screen every 24 hours for readiness for another SBT.

4.2. Options

Protocolized versus non-protocolized weaning
Weaning protocols usually consist of 3 parts: 1) objective cri-

teria to judge readiness to wean; 2) guidelines to decrease

support gradually; and 3) criteria to assess readiness for ex-

tubation (34). The latest Cochrane systematic review showed

that the use of protocols led to shorter total duration of me-

chanical ventilation and no extra side effects with moder-

ate quality of evidence. It also showed that protocols led to

shorter duration of weaning and ICU length of stay with low

quality of evidence. There were considerable variations in

the types of protocols used, types of patients and usual prac-

tices in ICUs, therefore the reviewers could not recommend

a certain protocol for general use (35).

Automated versus non automated weaning
Automated systems use closed loop circuits to automatically

adjust the level of support given to the patient. The latest

Cochrane systematic review showed that automated systems

were associated with shorter duration of weaning (36). How-

ever there was substantial heterogeneity in the result (87%).

It also showed that automated systems led to shorter dura-

tion of mechanical ventilation, length of ICU stay with mod-

erate heterogeneity. It did not show the automated systems

to be beneficial in reducing the length of hospital stay, mor-

tality rates, or need for re-intubation. Compared to usual

protocolized systems, automated systems showed shorter

duration of weaning and shorter total duration of mechan-

ical ventilation.

4.3. Sedation optimization strategies

Excessive sedation can result in poor performance in SBTs

and prolong the duration of mechanical ventilation (7). The

Table 3: classification of weaning outcomes

Outcome definitions
Simple

Successful SBT after the first attempt
Difficult

Failed SBT at first attempt and
Required up to three trials or
Required <7days to reach successful SBT

Prolonged
Required >7days to reach successful SBT

profuse diaphoresis, agitation.

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H. Zein et al. 68

most important sedation strategies are aiming at reduc-

ing the duration of mechanical ventilation and daily seda-

tion interruption. Atiken et al. investigated the benefits

of protocolized sedation versus non-protocolized sedation

in a Cochrane systematic review including 633 patients and

found that protocolized sedation did not result in a reduc-

tion in the duration of mechanical ventilation, ICU length of

stay, hospital length of stay or mortality rates. However they

graded the quality of evidence as low due to the conflicting

results from the two included studies (37). Another Cochrane

systematic review investigated the benefits of daily sedation

interruption versus no interruption. It found that there is no

strong evidence that daily sedation interruption reduced the

duration of mechanical ventilation, length of hospital or ICU

stay or mortality. In a subgroup analysis of studies performed

in North America, they found that daily sedation interrup-

tion reduced the total duration of mechanical ventilation.

However, the authors advised that the study results should

be used cautiously as the studies were heterogeneous in the

patients and methods (38). These results show that further

well-reported randomized clinical trials with large number of

patients and uniform interventions are needed to judge the

usefulness of these strategies.

5. Assessment for extubation

After successful SBT, the patient should undergo assessment

for removal of the airway. Assessment includes factors lead-

ing to extubation failure. Extubation failure is defined as re-

intubation within 48 hours of extubation. Re-intubation is

associated with prolonged hospital and ICU stay and more

tracheostomies (39). Re-intubation rate is commonly used

as an indicator of the aggressiveness of weaning behavior

in ICU units. It equals number of re-intubated patients di-

vided by total number of extubated patients. A value too high

suggests that weaning is done too early, and a value too low

suggests unnecessary conservative practices. Neil R MacIn-

tyre suggested that a value of 5-20% is generally accepted (7).

However, no significant differences were found between the

ranges of 7-15% and <7%. Table 4 shows factors leading to

extubation failure(34).

Stridor at extubation
Stridor at extubation occurs due to narrowing of the upper

airways. Cuff leak test has been introduced as a predictor

of stridor after extubation (40). The amount of air leaking

through the airway after deflating the cuff of the endotra-

cheal tube is measured. The average of three values of 6

consecutive breaths during continuous mandatory ventila-

tion 24 hours before extubation is taken. A value of <110 ml

is considered to identify patients at high risk for stridor after

extubation (41). However, it should be kept in mind that low

values may be due to crusts of secretions around the tube (7).

Table 4: Risk factors of extubation failure

Failure of two or more consecutive spontaneous breathing trials
Chronic heart failure
Partial pressure of arterial carbon dioxide > 45 mmHg after ex-
tubation
More than one coexisting condition other than heart failure
Weak cough
Upper-airway stridor at extubation
Age ≥ 65 years
APACHE II score >12 on the day of extubation
Patients in medical, pediatric or multispecialty ICU*
Pneumonia as a cause of respiratory failure
* Intensive care unit.

Steroids and/or epinephrine can treat post extubation stri-

dor. It is also possible to give steroids and/or epinephrine 24

hours before extubation for patients with low cuff leak values

(42).

Airway protection capacity
The ability of the patient to protect his airway from excessive

secretions by effective cough is evaluated. This includes not-

ing the quality of cough with airway suctioning, the amount

of secretions and the frequency of suctioning (4, 43, 44). Pa-

tients judged to be not capable of protecting their airway ef-

fectively should not be extubated (45).

Mental status
It is controversial whether patients should have intact cogni-

tive functions before extubation. A literature review showed

that a Glasgow coma score > 8 was associated with successful

extubation, if airway protection capacity is adequate (46).

The role of non-invasive ventilation (NIV )
Agarwal et al. conducted a meta-analysis of RCTs compar-

ing NIV with standard medical therapy in extubation fail-

ure (47). It showed that NIV when used prophylactically in

patients with high risk for extubation failure was associated

with lower risk for re-intubation and ICU mortality. How-

ever, when patients already developed respiratory distress,

NIV didn’t show the same benefits.

The role of high flow nasal cannula (HFNC)
Modern HFNC devices provide gas flow with a high rate up

to 70 Litter/minutr and thus can provide oxygen with a high

FiO2 up to 100%. Maggiore et al. conducted an RCT of HFNC

versus conventional venture mask for oxygen delivery after

extubation and found that HFNC was associated with bet-

ter oxygenation and lower re-intubation rate (48). Bortfain

et al. found that HFNC was associated with better oxygena-

tion, more ventilator free days and lower re-intubation rate

(49).

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69 Emergency 2016; 4 (2): 65-71

6. Appendix

6.1. Acknowledgements

We would like to express our special thanks to faculty mem-

bers of emergency department in Shahid Beheshti University

of Medical Sciences.

6.2. Author’s contributions

All the authors have contributed to drafting/revising the

manuscript, study concept, or design, as well as data inter-

pretation.

6.3. Conflict of interest

All authors declare that there is no conflict of interest in this

study.

6.4. Funding/ Support

All authors declare that this study was accomplished without

any funding or support and the authors were responsible for

all expenses. This study was conducted without any spon-

sors.

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	Introduction
	Weaning predictors
	Weaning criteria
	Weaning procedure
	Assessment for extubation
	Appendix
	References