WEANING FROM MECHANICAL VENTILATION

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WEANING FROM MECHANICAL VENTILATION

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Title: WEANING FROM MECHANICAL VENTILATION

1
WEANING FROM MECHANICAL VENTILATION

Dr MEGHA JAIN

University College of Medical Sciences GTB
Hospital, Delhi
2
HEADINGS

Purpose of weaning and extubation.
Rationale of predictive indices in weaning.
Application of weaning parameters.
Methods of weaning.
Impediments to weaning.
Extubation and terminal weaning.

3
Different stages in mech. Ventilated pts.
1. Treatment of ARF
3. Assessing readiness to wean
5. Extubation
6. Reintubation
2. Suspicion
4. SBT
Admit
Discharge
4
DEFINITIONS

Weaning is the gradual reduction in the level of
ventilatory support.
Weaning success effective spontaneous breathing
without any mechanical assisstance for 24 hrs or
more.
Weaning failure when pt is returned to
mechanical ventilation after any length of
weaning trial.
Signs of weaning failure abnormal blood gases,
diaphoresis, tachycardia, tachypnea, arrythmias,
hypotension.

5
Morbidity Associated With Prolonged Intubation
and Mechanical Ventilation

Vocal cord granulomas
Ulceration of the true vocal cords
Circumferential fibrous stenosis of trachea
Epithelial damage, loss of cilia, and impairment
of tracheal mucus clearance
Risk factor for nosocomial pneumonia
Precludes oral feeding

6
The assessment of weaning proceeds in two phases

Phase 1 To ensure that certain basic criteria
regarding initial reason for
mechanical ventilation are satisfied
Phase 2 Determine whether weaning is likely
to succeed on the basis of specified
criteria

7
READINESS FOR VENTILATOR WEANING

Major determinants of ability to wean can be
classified into three categories
oxygenation
ventilatory pump function
neuropsychiatric status

8
OXGYGENATION

Criteria of Adequacy
PaO2 gt 60 mmHg on FIO2 lt0.4 at minimal PEEP,
PaO2/FIO2gt200
Selected causes of failure
Hypoventilation neurologic injury or drugs
V/Q mismatch severe CHF
Anatomic (R-to-L) shunt (e.g. intracardiac,
pulmonary
A-V malformation).

9
VENTILATION

Criterion of Adequacy
PaCO2 lt 50 mmHg or within 8 mmHg of baseline
Selected causes of failure
respiratory drive sedation, drug overdose.
resp bellows function diaph weakness, N-m
disease
CO2 production without compensatory ? in alveolar
Ve
fever, hypermetabolism, carbohydrate overfeeding
- dead space ventilation without compensatory ?
alveolar Ve
PE, bullous emphysema

10
NEUROPSYCHIATRIC INTEGRITY

Criteria of adequacy
Awake, alert, cooperative, with intact gag
and swallowing
Selected causes of failure
Cerebrovascular accident
Sleep deprivation/ICU psychosis
Drug therapy
Depression
Psychological dependency on ventilatory
support

11
WEANING CRITERIA

Used to evaluate the readiness of a patient for
weaning trial.
Common weaning criteria Ventilatory
criteria Oxygenation criteria Pulmonary
reserve Pulmonary measurements Other
factors

12
VENTILATORY CRITERIA

PaCO2 lt 50 mmhg with pH gt/
7.35.
VC gt 10 to 15 ml/kg
Spontaneous VT gt 5 to 8 ml/kg
Spontaneous RR lt 30/min
Minute ventilation lt 10 lts

PaCO2 most reliable indicator VC and spon VT
indicate mechanical cond of lungs A high spon RR
and MV indicate ? WOB
13
OXYGENATION CRITERIA

PaO2 without PEEP gt 60 mmhg _at_FiO2 upto 0.4
PaO2 with PEEP gt 100 mmhg _at_ FiO2 upto
0.4
SaO2 gt 90 _at_ FiO2 upto
0.4
Qs/Qt lt 20
P(A-a)O2 lt 350 mmhg
PaO2/FiO2 gt 200 mmhg

Qs/Qt estimate wasted pulmonary
perfusion P(A-a)O2 is related to degree of
hypoxemia/shunt In pts with anemia or dysfunct
Hb, PaO2 and SaO2 dont reflect true oxygenation
status So arterial oxygen content should be
measured
14
PULMONARY RESERVE AND MEASUREMENTS

Pulmonary reserve
Max. voluntary ventilation 2min.
vent_at_FiO2 upto 0.4
Max. Insp. Pressure lt -20
to -30 cmH2O in 20 sec.
Pulmonary measurements
Static compliance gt 30
ml/cm H2O
Vd/Vt
lt 60

Pulmonary reserve requires active pt
cooperation Pulmonary measurements indicate
workload needed to support spont. ventilation
15
COMBINED WEANING INDICES

Simplified weaning index evaluates efficiency of
gas exchange. ( fmv (PIP PEEP)/MIP)
PaCO2/40. should be lt 9/min.
CROP index evaluates pulmonary gas exchange and
balance b/w respiratory demands and respiratory
neuromuscular reserve. ( Cd MIP
PaO2/PAO2)/f. Should be gt 13 ml/breath/min.
RSBI should be lt 105 cycles/min/lt.
f/Vt. Most accurate test to predict
weaning success.

16
RSBI

First described by Yang and Tobin in 1991.
Its a one min. trial of unassisted breathing
measured during the T piece trial.
Main defect excessive false ves
Should not be measured until sedative and
narcotic effects have adequately abated and the
pt. triggers 2 to 3 breaths/min above ventilator
set rate.
Measure RR and MV for 1 min. during unassisted
breathing( 0 PEEP/5 cmH2O PSV).
At end of 1 min. divide MV by RR to calculate
avg. tidal vol.
Divide RR by TV to obtain RSBI.

17
OTHER FACTORS

Metabolic factors Inadequate nutrition
protein catabolism Overfeeding - ? CO2
production Phosphate, ? Magnesium deficiency
- ?respi pump functn Impaired O2 delivery -
?respi pump functn.
Renal function Patient should have adeq
renal output (gt 1000 ml/day) Monitor
electolytes to ensure adequate respi msl functn
Cardiovascular function Ensures sufficient
O2 delivery to tissues Cardiac rate, rhythm,
BP, CO and CI should be optimal with
minimal pressure support
CNS assessment Assess for LOC, anxiety,
dyspnea, motivation CNS should be intact for
protection of airway.

18
Weaning methods

Spontaneous breathing trial
SIMV with pressure support.
PSV
Rapid ventilator discontinuation pt.on vent for
lt 72 hrs., has good spont RR, MV, MIP, f/Vt
SBT for 30 to 120
min. EXTUBATE if no other limiting
factor

19
Spontaneous Breathing Trial

T-Tube trial allows spont. breathing several
times per day interspersed with periods of
ventilatory support.
Initial SBTs may last only 5 to 30 min.
Resume mechanical ventilation at night or if
distress occurs.

ADVANTAGES Tests pts spon breathing
ability Allows periods of work and rest Weans
faster than SIMV
DISADVANTAGES Abrupt transition difficult for sm
pts No alarms, unless attached to vent. Requires
careful observn.
20
Weaning protocol for a SBT with a T-Tube
Verify that pt is a candidate for vent.
discontinuation
Primary cause reversed
Pt is afebrile, awake, alert and free of seizures
HD stable with adeq. Hb, S.E.
Oxygenation and ventilation adequate PaO2gt/
60mmhg on FiO2 lt/ 0.4 with PEEP/CPAP lt/ 5 to 8
cmH2O PaO2/FiO2 gt 150 to 200 mmhg PaCO2 lt 50 pH
gt 7.35
Other indices - f/VT lt 105
- MIP lt -20 cm H2O -
f lt 30 and gt 6/min. - VC gt 10 to 15
ml/kg - TV gt 5 ml/kg

21
Weaning protocol for a SBT with a T-Tube
Prepare for T-Tube trial
Adequate staff, equipment, no sedatives
3 min. screening trial
Measure TV,RR Measure MIP thrice selecting the
best
Formal SBT of upto 2 hrs.
MIP lt -20 cm H20 TV spon. gt 5 ml/kg RR spon. lt
35/min.
Continue trial for 30 120 min.
Extubate if no signs of intolerance
22
Signs of intolerance of SBT

Agitation, anxiety, diaphoresis or change in
mental status
RR gt 30 to 35/min
SpO2 lt 90
gt 20 ? or ? in HR or HR gt 120 to 140/min
SBP gt 180 or lt 90 mmhg.
Such pts are returned to full ventilatory
support for 24 hrs. to allow the ventilatory
msls. to recover.

23
Weaning with SIMV

Involves gradual reduction in machine rate based
on ABG and clinical assessment.
Rate is generally adjusted in increments of 2
breaths/min. followed by pt assessment.

ADVANTAGES Gradual transition Easy to use Minimum
MV guaranteed Alarm system may be used Should be
used in comb. with PSV/CPAP
DISADVANTAGES Pt. ventilator asynchrony Prolonge
s weaning May worsen fatigue
24
Pressure Support Ventilation (PSV)
Patient determines RR, VE, inspiratory time a
purely spontaneous mode

Parameters
Triggered by pts own breath
Limited by pressure
Affects inspiration only
Uses
Complement volume-cycled modes (i.e., SIMV)
Does not augment TV but overcomes resistance
created by ventilator tubing
PSV alone
Used alone for recovering intubated pts who are
not quite ready for extubation
Augments inflation volumes.

PSV is most often used together with other
volume-cycled modes. PSV provides sufficient
pressure to overcome the resistance of the
ventilator tubing, and acts during inspiration
only.
25
Pressure support ventilation

Begin with PSV that achieves a RR of 20 to 25/min
or less.
Adjust pressure to achieve a TV of 8 to 10 ml/kg.
Reduce PSV 2 to 4 cm H2O as tolerated, ideally at
least twice daily.
Consider extubation when pt. tolerates PSV of 5
to 8 cm H2O for 2 hrs with no apparent distress.

26
Pressure support ventilation
ADVANTAGES Gradual transition Prevents
fatigue Increased pt comfort Weans faster than
SIMV alone Every breath is supported Pt can
control cycle length, rate and inspiratory
flow. Overcomes resistive WOB d/t ET tube and
circuit.
DISADVANTAGES Large changes in MV can occur ?ed
MAP versus T-Tube TV not guaranteed
27
Mandatory minute ventilation

Also called minimum minute ventilation, provides
predetermined minute ventilation when pts spon.
breathing effort becomes inadequate.
Prevents hypoventilation and respi. acidosis in
final stages of weaning.
Trigger is ? in mandatory RR when actual MV lt
preset MV.
All mandatory breaths are volume cycled.
Desired min. minute vol. is preset on the vent.
Slightly lesser than that required to normalize
PaCO2.
If distress pt tends to ? RR at expense of ? TV
, leads to significant dead space ventilation

28
Mandatory minute ventilation
ADVANTAGES Backup ventilation ensured, Potential
to speed weaning compared with SIMV.
DISADVANTAGES May not ensure efficient pattern
of breathing, Rapid shallow breathing possible
with MMV.
29
Automatic Tube Compensation

Compensates for the resistance of ETT
Facilitates electronic weaning i.e pt during
ATC mimic their breathing pattern as if extubated
( provided upper airway contorl provided)
OPERATION
As the flow ? / ETT dia ?, the P support needs to
be ?to ?WOB

?P (P support) a (L / r4 ) a flow a WOB
30

Static condition single P support level can
eliminate ETT resistance
Dynamic condition variable flow e.g. tachypnoea
in diff phases of resp.
- P support needs
to be continously altered
to eliminate dynamically changing WOB d/t ETT

Feed resistive coef of ETT
Feed compensation desired
Measures
instantaneous flow

Calculates P support proportional to
resistance throughout respiratory cycle
Limitation resistive coef changes in vivo (
kinks, temp molding, secretions) Under/
overcompensation may result.
31
Proportional Assist Ventilation

Targets fixed portion of patients work during
spontaneous breaths
Automatically adjusts flow, volume and pressure
needed each breath

WOB
Ventilator measures elastance resistance
Clinician sets -Vol. assist reduces work of
elastance
Flow assist reduces
work of resistance's
Increased patient effort (WOB) causes increased
applied pressure (and flow volume)

ELASTANCE (TV)
RESISTANCE (Flow)
33

Limitations
1. Elastance (E) resistance (R) cannot be
measured accurately.
2. E R vary frequently esp in ICU patients.
3. Curves to measure E ( PV curve) R(P-F curve
) are not linear as assumed by ventilator.

34
Noninvasive

ventilation without artificial airway
Nasal , face mask
adv.
Avoid intubation / c/c
Preserve natural airway defences
Comfort
Speech/ swallowing
Less sedation needed
Intermittent use
Disadv
Cooperation
Mask discomfort
Air leaks
Facial ulcers, eye irritation, dry nose
Aerophagia

35
Role of tracheostomy in weaning

Performed in ventilator dependent pts., timing is
controversial.
Beneficial in ?ed sedation requirement,
articulated speech, allowed orally, enhanced
mobility.

36
Role of tracheostomy in weaning

Early tracheostomy ( in 2 days of admission )
reduces mortality, risk of pneumonia, accidental
extubation, ICU length of stay.

Reduces dead space Less airway resistance ?ed
WOB Better suctioning Improved pt comfort
Facilitates weaning
37
Complications

Misplacement
Hemorrhage
Obstruction
Displacement
Impairment of swallowing reflexes
Late tracheal stenosis.

38
Weaning failure

Defined as when pt is returned to mech.
Ventilation after any length of weaning trial or
is reintubated within 48 hrs following
extubation.
Causes 1. ?ed air flow resistance- ET
tube, abdominal distention, tracheal
obstruction. 2. ?ed compliance-
atelectasis, ARDS, tension pneumothorax,
obesity, retained secretions, bronchospasm,
kinking of ETtube. 3. Electrolyte imbalance,
inadequate nutrition.

39
Indicators of weaning failure

Blood gases- ?ing PaCO2 ( gt50 mmhg) ?ing
pH lt 7.30 ?ing PaO2 (lt60 mmhg)
?ing SpO2 (lt90) ?ing PaO2/FiO2
(lt150 mmhg)
Vital signs- ?ing HR ( by gt 20/min. or gt
110/min.) abnormal ECG changing BP ( 20
mmhg SBP or 10 mmhg DBP)

40
Indicators of weaning failure

Respiratory parameters ?ing TV ( lt 250 ml)
?ing RR ( gt 30/min) ?ing f/TV
ratio ( gt 105 cycles/L) ?ing MIP ( lt
-20 cm H2O) ?ing static compliance ( lt 30
ml/cm H2O) ?ing VD/VT ( gt 60)

41
Pathophysiology of weaning failure

NONRESPIRATORY PARAMETERS AFFECTING ABILITY TO
WEAN

Nutritional status Fluid balance Metabolic and
acid-base derangements Cardiac Function Renal
function Neuropsychiatric factors
42
Nutritional status

Malnutrition has adverse effects on the
respiratory system
?respiratory muscle strength and function
?diaphragmatic mass and contractility
?endurance

43
Nutritional status

Overnutrition may impede weaning
High CO2
Produced by excessive CHO loading
Other causes of increased CO2 production fever,
sepsis, shivering, seizures, and inefficient
ventilation due to ? dead space, PE

44
Metabolic abnormalities

Hypophosphatemia
Hypocalcemia
Hypothyroidism

45
Sleep Deprivation and Psychological Issues

Twilight awareness -gt nap during the day -gt
shift day-night cycle
Give sedative-hypnotic at bedtime to restore
normal daily cycle
Depression in the long-term ICU patient
TCA at bedtime for sedative effect and to
forestall depression.
Anxiety
Adequate sedation only to minimize detrimental
WOB
Very slow changes in PS level to prevent
anxiety induced by sudden changes to the response
of the lung stretch receptors

46
Ventilator induced diaphragmatic dysfunction

VIDD loss of diaphragmatic force generating
capacity related to use of mech. Ventilation
can ocurr as early as 12 hrs. and reduction
in max force production is of the order of 30
50 after 1 3 days of CMV.
Causes of VIDD msl. atrophy, oxidative stress,
structural injury, msl fiber remodelling.
Management - Minimise use of NM blockers,
steroids Optimize PO4, Mg, nutrition.
Cervical magnetic stimulation of phrenic
nerve Antioxidant supplementation.

47
Critical care illness neuromyopathy

Causes sepsis, malnutrition, paralysing agents,
sedatives, narcotics, steroids.
Affects all msls. Including diaphragm and
intercostals.
B/L proximal msl weakness.
Diagnosis using Medical Research Council Score( lt
48), electrophysiological testing and msl biopsy
if appropriate.
Transdiaphragmatic pressure in response to B/L
phrenic nerve stimulation.
Treatment options Good nutrition
Withdrawal of offending drugs
Inspiratory msl exercises

48
Prolonged mechanical ventilation

Required in 3 to 7 of ventilated pts.
Unless cause is irreversible ( high spinal cord
injury) pt should not be considered permanently
ventilator dependent until 3 mths of weaning
attempts have failed.
Often transferred to regional weaning
centers/long term care facilities.
Goal is to restore pt to highest level of
independent function possible.

49
Complications of PMV

Infection
Bacterial Pneumonia
Line sepsis
Volume Overload
Laryngeal Edema
Pneumothorax
Tracheal Bleeding
Ileus
DVT
Additional Complications if Tracheostomy is
necessary

50
Extubation

Discontinuation of invasive PPV involves 2 steps
separation of pt. from vent. based on
assessment of removal of artificial airway.
airway patency protection

Parameters for airway patency Cuff leak
test Qualitative Quantitative audible
air leaklt 110 ml air leak

Parameters for airway protection Effective
cough Secretion volume Mental status
51
Extubation failure

Defined as need for reinstitution of vent.
Support within 24 72 hrs. of ETT removal.
Occurs in 2 25 of pts.
Predisposing factors advanced age
duration of mech. Vent. anemia use
of cont. IV sedation semirecumbent
positioning after extubation.
Find manage the cause.

52
Terminal weaning

Defined as withdrawal of mechanical ventilation
that results in death of the pt.
3 concerns must be evaluated and discussed
pts informed consent medical futility
reduction of pain and suffering
Carries many ethical and legal implications.

53
References

Egans fundamentals of respiratory care 9th ed.
International Anaesthesiology Clinics Update on
respiratory critical care , vol 37, no 3, 1999.
Anaesthesia newsletter ,Indore city ,June 2009,
vol 10, no 2
David W Chang, Clinical application of mechanical
ventilation 2nd ed
Paul L Marino, The ICU Book, 3rd ed.
Weaning from mech. Ventilation, Eur. Respi. J
2007 29 1033 1056.

54
THANK YOU
55
Ventilator management algorithim