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MECHANICAL VENTILATION IN PEDIATRICS

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MECHANICAL VENTILATION IN PEDIATRICS PRESENTED BY DR.MAYSA ABDULHAQ Moderator DR.NADWA AL-ZOHLOF Contents Basics of ventilators/ control pattern and modes. – PowerPoint PPT presentation

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Title: MECHANICAL VENTILATION IN PEDIATRICS


1
MECHANICAL VENTILATION IN PEDIATRICS
  • PRESENTED BY DR.MAYSA ABDULHAQ
  • Moderator DR.NADWA AL-ZOHLOF

2
Contents
  • Basics of ventilators/ control pattern and modes.
  • Indications /aims .
  • Initial settings/adjusting of ventilator
    settings
  • Problems during ventilation and complications
  • Weaning stratigies

3
The Basics of Mechanical Ventilation
4
  • Depending on connecting prosthesis, mechanical
    ventilation is defined
  • non-invasive ventilation when inferior airways
    are not invaded to introduce external gases into
    lungs. Prostheses largely used are nasal and
    facial masks to perform non-invasive.
  • invasive ventilation when tracheal intubation or
    tracheostomy are used to connect patient to
    ventilator.

5
(No Transcript)
6
There are two ways to give a breath
Volume Controlled
Pressure Controlled
7
Ventilators Modes control variables
  • Control Variables
  • The control variables\independent variables,
    determined by the clinicians and include
    pressure, flow, or volume.
  • must overcome the elastic and resistive forces to
    allow gas delivery to the patient.
  • During expiration, the elastic and resistive
    elements of the respiratory system are passive,
    and expiratory waveforms are not directly
    affected by the modes of ventilation or the
    controller.

8
volume controller
  • When the clinician presets a volume pattern, it
    operates as a volume controller Volume is an
    independent variable and pressure is a dependent
    variable. pressure then varies with compliance.
    Expiration is passive, and the expiratory profile
    is not directly affected by the mode of
    ventilation but rather by compliance and
    resistance

9
Volume Control
  • The patient is given a specific volume of air
    during inspiration.
  • The PIP observed is a product of the lung
    compliance, airway resistance and flow rate. The
    ventilator does not react to the PIP unless the
    alarm limits are violated.
  • The PIP tends to be higher than during pressure
    control ventilation to deliver the same volume of
    air.

10
What do you set?
Volume Controlled
You set Tidal volume Peak flow Rate FiO2 PEEP
11
Volum Control Ventilation
  • Controlling pH and pCO2 is done by controlling
    minute ventilation. You can set both the
    respiratory rate and the tidal volume.
  • Controlling pO2 you can adjust the FiO2, the PEEP
    and, indirectly, the PIP by adjusting the tidal
    volume (bigger TV yields bigger Pmax) although we
    dont do this so much in practice

12
Pressure Controller
  • when the clinician presets the pressure pattern,
    the ventilator operates as a pressure controller
    Pressure is the independent variable, and volume
    is the dependent variable determined by the level
    of pressure.and is the function of lung
    compliance and airways resistance.

13
Pressure Control
  • The pressure is constant throughout inspiration.
  • The ventilator adjusts the flow to maintain the
    pressure.
  • Flow decreases throughout the inspiratory cycle.
  • Volume delivered depends upon the inspiratory
    pressure, I-time, pulmonary compliance and airway
    resistance.
  • The delivered volume can vary from
    breath-to-breath depending upon the above
    factors. MV not assured.
  • Good mode to use if patient has large air leak,
    because the ventilator will increase the flow to
    compensate it.

14
What do you set in PC?
Pressure Controlled
You set Pressure limit Time spent in inspiration
(Itime) Rate
You set FiO2 PEEP
15
Pressure Control Ventilation
  • Controlling the pH and pCO2 is done by
    controlling the minute ventilation. You can set
    the RR, but the TV is managed indirectly.
  • Controlling the pO2, again you can adjust the
    FiO2 and the PEEP, in addition you control the
    PIP.

16
Volume vs. Pressure
17
Modes of Ventilation
  • the mode of ventilation is a description of the
    way a mechanical breath is delivered.
  • In general we are trying to accomplish one of two
    things for a patient using mechanical
    ventilation either to control their ventilation
    and oxygenation, which they are unable to do, or
    to support them as they wean from ventilatory
    support. Hence, we can look at ventilator modes
    as either Control Modes, or Support Modes.

18
Modes of Ventilation
  • Mechanical ventilation can be applied both
    invasively or non-invasively in the following
    ways
  • Controlled mechanical ventilation Pressure
    controlled Ventilation PC, Volume Controlled
    Ventilation VC, , Pressure Regulated Volume    
    Controlled Ventilation PRVC , High Frequency
    Ventilation ,CMV and IMV.(which are rarely , if
    ever, used today),
  • Supported spontaneous breathing Pressure Support
    Ventilation and     Volume Support Ventilation
  • Mixed respiratory support (SIMV)Synchronized
    Intermittent Mandatory Ventilation .SIMV/PS
  • Assisted spontaneous breathing Continuous
    Positive Airway Pressure (CPAP

19
AC (assist control) or VC (Volume Control)
  • Characteristics preset rate and tidal volume
    (sometimes PIP), full mechanical breath is
    delivered either triggered by patients
    respiratory efforts, or if not sufficient- the
    preset mechanical rate is maintained
    automatically.
  • Uses for patients who have a very weak
    respiratory effort, allows synchrony with the
    patient but maximal support. Not a weaning mode,
    as at any rate they are getting complete
    mechanical support.
  • Advantages a fairly comfortable mode, providing
    a lot of support.
  • Disadvantages can lead to hyperventilation if
    not closely monitored, not able to wean in this
    mode.

20
Assist Control (A/C)
21
PRVC (Pressure Regulated Volume Control)
  • Characteristics a volume control assist control
    mode, In this mode, a target minute ventilation
    is set.
  • The ventilator will adjust the flow to deliver
    the volume without exceeding a target inspiratory
    pressure.
  • Uses in patients with high airway pressures,
    although it can be used in any patient.
  • Contraindications none in particular
  • Advantages No change in minute ventilation if
    pulmonary conditions change. The desired TV can
    be guaranteed at the lowest PIP necessary to
    achieve it thus minimizing the barotrauma.
    Disadvantages new, Hard to use on a
    spontaneously breathing patient or one with a
    large air leak. Not a weaning mode.

22
IMV (Intermittent Mandatory Ventilation)
  • Characteristics set breath delivered at a fixed
    interval. No patient interaction, but allow the
    patient to breath through the ventilator circuit
    by providing gas flow( unlike CMV). pressure or
    volume control,
  • Contraindications none really, unfriendly to
    older patients
  • Advantages regular guaranteed breath
  • Disadvantages does not allow patient to breath
    with the ventilator except by chance..Does not
    work with the patient

23
Intermittent Mandatory Ventilation (IMV)
Ventilator lets patient breathe spontaneously BUT
does not change its plan of ventilation.
24
PS /Pressure Support
  • Characteristics supports each spontaneous breath
    with supplemental flow to achieve a preset
    pressure.
  • All the breaths are triggered by the patient
  • Prest value PIP, PEEP, FiO2.
  • the patint determine rate, Ti, IE ratio, TVi.
  • Needs intact resp. drive.
  • Uses In the spontaneously breathing patient this
    helps overcome the airway resistance of the
    endotracheal tube. Can be very helpful for
    weaning.
  • Contraindications patient who is not
    spontaneously breathing, i.e. on muscle relaxants
  • Advantages helps overcome resistance of tube,
    making spontaneous breathing easier

25
VS/Volume Support
  • Characteristics variable level of pressure
    support is delivered on each spontaneous
    patient-triggered breath in order to achieve
    preset tidal volume.
  • All breaths are triggered by the patient.
  • The clinician pre set iTV, FiO2, PEEP,
  • The patient determine the RR, Ti, IE ratio.
  • Uses a weaning mode. The concept is that as the
    patient becomes stronger, or more awake they will
    make more respiratory effort on their own. The
    more effort they make the less support they will
    need from the ventilator and hence the level of
    pressure delivered will get smaller.
  • Contraindications patient who is not
    spontaneously breathing, as there is no back-up
    rate.
  • Advantages greatly decreases the number of
    interventions needed to wean patient from a
    ventilator versus traditional weaning

26
Weaning by Support Ventilation
Ventilators work of breathing
27
Weaning by Support Ventilation
Ventilators work of breathing
28
Weaning by Support Ventilation
Ventilators work of breathing
29
The following modes fall into both Control and
Support categories in that they have set rates,
but the spontaneous breaths are not controlled,
so they can be used in weaning.
30
SIMV (Synchronous IMV)
  • Characteristics Derived from Intermittent
    mandatory ventilation (IMV)
  • Preset mechanical breath delivered within an
    interval based on the preset respiratory rate.
    Ventilator spends part of the interval waiting
    for spontaneous breath from the patient, which it
    will use as a trigger to deliver a full breath.
    If not sensed it will automatically give a breath
    at the end of the period. Any other breaths
    during the cycle are not supplemented.
  • Patient does ALL work of breathing on the
    spontaneous breaths.
  • Plus some work on the SIMV breaths. (Tries to
    synchronize to patients efforts)
  • TV on the spontaneous breaths depends entirely
    upon patient effort and lung mechanics
  • Can be pressure or volume controlled
  • Uses commonly used in many settings. Can be a
    weaning mode (see also with PS)
  • Contraindications none in particular
  • Advantages allows work with the patient,
    somewhat more friendly.
  • Disadvantages Any other breaths during the cycle
    are not supplemented/ not good for fighting
    patients.

31
SIMV
SIMV divides Tb into Mandatory periods (Tm) and
Spontaneous periods (Ts)
32
SIMV
If patient tries to breathe during Tm, the
ventilator gives a FULLY ASSISTED BREATH
33
SIMV
If patient tries to breathe during Ts, the
ventilator allows the patient to take the
breath. Assistance may or may not be provided
with PRESSURE SUPPORT (coming soon)
34
Triggering the Ventilator
35
SIMV/PS
  • Characteristics combination of the previous two
    modes. Extra breaths in the cycle are
    supplemented with pressure support.
  • Uses useful in most circumstances, including
    weaning.
  • Contraindications none in particular.
  • Advantages allows both synchrony with the
    patient and help in overcoming the resistance in
    the endotracheal tube, to allow easier
    spontaneous breathing
  • Disadvantages none in particular. PS does not
    add anything in the patient who is not
    spontaneously breathing.

36
Assisted Spontaneous Breathing
  • Continuous Positive Airway Pressure CPAP is a
    mode of ventilation, the pressure above the
    atmospheric pressure maintained throught out the
    resp. cycle during spontaneous breathing, thus
    pressure in the airway is always positive

37
CPAP


  • This method presents several advantages because
    of
  • increased lung volume and FRC and improve in
    ventilation/perfusion ratio.
  • preventing and resolving atelectasis.
  • reduced work of breathing and prevention of
    muscle fatigue .
  • Applied by invasive and noninvasive methods

38
CPAP is not advisable in
  • high risk patients. severe respiratory effort to
    maintain ventilation
  • any patient without spontaneous respiratory
    effort.
  • Not a good idea in a patient with obstructive
    pulmonary disease (like asthma).
  • hypercapnia

39
CPAP is indicated in
  • for patients with upper airway soft tissue
    obstruction
  • or tendency for airway collapse.
  • As a final mode prior to extubation in some
    patients.

40
CPAP
  • This is very similar to PEEP, except that the
    inspiratory pressure is also maintained at the
    CPAP level, leading to support on inspiration and
    resistance on exhalation.

41
So what is PEEP?
PEEP is the residual pressure above atmospheric
pressure maintained at end of expiration.
PEEP can be added to any mode of mechanical
ventilation A/C PC or VC SIMV PC or VC
42
PEEP
  • Good.
  • Recruits Alveoli
  • ? FRC
  • Redistributes Pulmonary Edema Fluid
  • ?intrapulmonary shunt
  • ? PaO2
  • Bad.
  • ?d Venous Return / C.O.
  • May ? ICP,/ intensify cerebral ischemia
  • Overdestention/?s Risk of Barotrauma
  • May impair oxygenation????

43
  • Figure 6 - Tracheo-bronchial distention due to
    PEEP application leads to a progressive
    recruitment of alveoli. On the left, 2 PEEP on
    the right, 10 cm H2O PEEP.

44
What is Auto-Peep?
INSP
FLOW
EXP
Expiratory flow ends before next breath
Next breath begins before exhalation ends
Obstructive lung disease (pursed lip) Rapid
breathing (breath stacking) Forced exhalation
(anxiety)
45
Conditions associated with auto-PEEP
  • Patients with obstructive lung disease( sever
    Asthma)
  • Kinked or obstructed ETT with secretions.
  • In adequate Te in mechanically ventilated
    patients

46
Signs of air trapping (auto-PEEP)
  • Over expansion of the chest
  • Decreased chest wall expansion.
  • CO2 retention.
  • Cardiovascular dysfunction.

47
Ventilator settings in auto-PEEP
  • Low or Zero PEEP
  • Long Te( as possiple)
  • Low RR
  • Relieve underlying causes( bronchospasm,
    secretions, position of ETT)

48
Who needs a ventilator?
  • If you don't know where you are going, you might
    wind up someplace else.
  • Try to figure out why the patient is requiring
    intubation.

49
Who needs a ventilator?
  • Cant oxygenate (low PaO2/SPO2)
  • Cant ventilate (high PaCO2)
  • Cant participate or protect airway (low GCS)
  • If youre not sure whether or not the patient
    needs a ventilator, the patient needs a
    ventilator.

50
Assessment of the need for mechanical ventilation
  • Symptoms
  • DyspneaOrthopneaIncreased cough or
    wheezeSomnolence
  • Signs
  • StridorTachypneaUse of accessory muscles
    of respirationRetractionsProlonged expiratory
    phaseParadoxical abdominal motion on
    inspirationCyanosis
  • Laboratory tests
  • Arterial blood gas measurementPulse
    oximetric studiesChest radiographMeasurements
    of pulmonary mechanics

51
Aims of mechanical ventilation
  • Always remember assisted ventilation is a
    supporitive technique its NOT a curative

52
Aims of mechanical ventilation
  • Provide ventilation( CO2 removal)
  • Optimal systemic oxygenation
  • Decrease the work of breathing

53
Ventilator Settings
  • There is no optimum mode of ventilation for any
    disease state optimum method of weaning
    patients from mechanical ventilation.
  • Mechanical ventilation is associated with a
    number of diverse consequences include
    volutrauma, barotrauma, oxygen toxicity.
  • To Minimize side effects, the physiologic
    targets need not to be in normal range.

54
Initial Ventilator Settings
  • Rate 20-24 for infants and preschoolers
    16-20 for grade school kids 12-16 for
    adolescents
  • TV 10 -15ml/kg
  • PEEP 3-5cm H2O
  • FiO2 100
  • I-time 0.7 sec for higher rates, 1sec for lower
    rates
  • PIP (for pressure control) about 24cm H2O.

55
Adjusting The Ventilator
  • Obtaining a blood gas early after intubation
    (15-20 minutes after being on the ventilator)
    will help you decide if you are moving in the
    right direction.
  • Its better to accept a certain degree of resp.
    acidosis and possibly even hypoxemia to avoid
    ventilator induced lung injury. (pemisive
    haypercapnia and relative hypoxia)
  • It may be better to risk O2 toxicity than to use
    high pressure.

56
Adjusting The Ventilator
  • pCO2 too high
  • pCO2 too low
  • pO2 too high
  • pO2 too low
  • PIP too high

57
pCO2 Too High
  • Patients minute ventilation is too low.
  • Increase rate or TV or both.
  • If using PC ventilation, increase PIP.
  • If PIP too high, increase the rate instead.
  • If air-trapping is occurring, decrease the rate
    and the I-time and increase the TV to allow
    complete exhalation.
  • Sometimes, you have to live with the high pCO2,
    so use bicarbonate to increase the pH to gt7.20.

58
pCO2 Too Low
  • Minute ventilation is too high.
  • Lower either the rate or TV.
  • Dont need to lower the TV if the PIP is lt20.
  • TV needs to be 8ml/kg or higher to prevent
    progressive atelectasis
  • If patient is spontaneously breathing, consider
    lowering the pressure support if spontaneous TV
    gt7ml/kg.

59
pO2 Too High
  • Decrease the FiO2.
  • When FiO2 is less than 40, decrease the PEEP to
    3-5 cm H2O.
  • Wean the PEEP no faster than about 1 every 8-12
    hours. Sudden decease in PEEP may lead to
    precipitous decrease in oxygenation and FRC.
  • While patient is on ventilator, dont wean FiO2
    to lt25 to give the patient a margin of safety in
    case the ventilator quits.

60
pO2 Too Low
  • Increase either the FiO2 or the mean airway
    pressure (MAP).
  • Try to avoid FiO2 gt70.
  • Increasing the PEEP is the most efficient way of
    increasing the MAP in the PICU.
  • Can also increase the I-time to increase the MAP
    (PC).
  • Can increase the PIP in Pressure Control to
    increase the MAP,
  • May need to increase the PEEP to over 10, but try
    to stay lt15 if possible.

61
PIP Too High
  • Decrease the PIP (PC) or the TV (VC).
  • Increase the I-time (VC).
  • Change to another mode of ventilation.
    Generally, pressure control achieves the same TV
    at a lower PIP than volume control.
  • If the high PIP is due to high airway resistance,
    generally the lung is protected from barotrauma
    unless air-trapping occurs.

62
Permissive Haypercapnia and Relative Hypoxia)
  • Attempts to maintain normal values during
    treatement of acute lung injury expose airways
    to ventilator-induced lung injury
  • Barotrauma
  • Volutrauma
  • Oxygen toxicity

63
Permissive Haypercapnia and Relative Hypoxia)
  • So permissive haypercapnia and relative hypoxia
    are treatment strategies to prevent the
    development of ventilator-induced injury.
  • Used in the acute or recovery phase of acute
    lung injury or ARDS
  • Allows for respiratory acidosis with metabolic
    compensation
  • Progressinve increase in PaCO2 to 60-100 and may
    be higher.
  • Rate of development of hypercapnia is 5-10mmHg/hr
    will allow renal compensation. But rapid increase
    in PCO must be avoided.

64
Permissive Haypercapnia and Relative Hypoxia)
  • To avoid oxygen toxicity
  • Keep FiO2 lt 50
  • Maintain low PaO2 near 50 mm Hg
  • with fairly adequate O2sat gt 85
  • The tow strategies may be used separately to or
    together depending on the clinical conditions.

65
Contraindications for permissive hypercapnia and
hypoxia
  • Suspected intracranial hypertention
  • Cerebrovasculer disease
  • Cardiac arrhythmias
  • Sever pulmonary hypertension
  • Sever systemic hypertension
  • Sever cardiac failure
  • Sickle cell disease

66
Indication for permissive hypercapnia and hypoxia
  • Acute lung injury or ARDS.
  • Weaning from mechanical ventilator.
  • Patients with air leak syndrom
  • Status asthmaticus in resp. failure.
  • Post operative recovery.

67
Inverse ratio ventilation
  • The clinician must increase the Ti to greater
    than Te for IE ratio more than.11
  • Benefit in refractory hypoximic ARDS that not
    responding to other strategies.
  • Can be used in both volume and pressure control
    ventilation, but volume control is not preferred

68
Effects of inverse ratio
  • This maneuver will recruits the alveoli by
  • 1-Prolonged time constant will increase the
    mean airway pressure.
  • 2- increasing the Te will increase the Paw
    by causing auto-PEEP.
  • Alveolar recruitment will improve V/Q and enable
    the clinician to decrease PIP, PEEP, and FiO2

69
During inverse ratio
  • Provide adequate sedation and neuromuscular
    blockade
  • Small tidal volum 5-8 ml/kg
  • PIP lt 35 mmHg
  • PEEPlt 10 cm H2O
  • Side effects
  • decrease cardiac out put/ may need pulmonary
    art. catheter for close haemodynamic monitring .
  • Increase risk of barotrauma and volutrauma

70
Complications of Mechanical Ventilation
  • Pulmonary
  • Barotrauma
  • Ventilator-induced lung injury
  • Nosocomial pneumonia
  • Tracheal stenosis
  • Tracheomalacia
  • Pneumothorax
  • Cardiac
  • Myocardial ischemia
  • Reduced cardiac output
  • Gastrointestinal
  • Ileus
  • Hemorrhage
  • Pneumoperiteneum
  • Renal
  • Fluid retention
  • Nutritional
  • Malnutrition

71
Acute Deterioration
  • DIFFERENTIAL DIAGNOSES
  • Pneumothorax
  • Pneumonia
  • Malposition of the ETT
  • Pulmonary edema
  • Airway occlusion
  • Ventilator malfunction
  • Mucus plugging
  • Air leak

72
Physical Exam
  • Tracheal shift
  • Pneumothorax
  • Wheezing
  • Bronchospasm
  • Mucus plugging
  • Pulmonary edema
  • Pulmonary thromboembolism
  • Asymmetric breath sounds
  • Pneumothorax
  • Mainstem intubation
  • Mucus plugging with atelectasis
  • Decreased breath sounds bilaterally
  • Tube occlusion
  • Ventilator malfunction

73
Weaning from Mechanical Ventilation
  • Weaning from mechanical ventilatory support has
    traditionally been a mix of science and art
  • It requires waiting until the disease process
    that caused the patient to need assisted
    ventilation reverses and then successfully
    decreasing ventilator support to a level that
    allows for extubation.

74
Weaning Priorities
  • Wean PIP to lt35cm H2O
  • Wean FiO2 to lt60
  • Wean I-time to lt50
  • Wean PEEP to lt8cm H2O
  • Wean FiO2 to lt40
  • Wean PEEP, PIP, I-time, and rate towards
    extubation settings.
  • Can consider changing to volume control
    ventilation when PIP lt35cm H2O.

75
Extubation Criteria
  • Neurologic
  • Cardiovascular
  • Pulmonary

76
Neurologic
  • Level of sedation should be low enough that the
    patient doesnt become apneic once the ETT is
    removed.
  • No apnea on the ventilator.
  • Patient must be able to protect his airway, e.g,
    have cough, gag, and swallow reflexes.
  • Must be strong enough to generate a spontaneous
    TV of 5-7ml/kg
  • Being able to follow commands is preferred.

77
Cardiovascular
  • Patient must be able to increase cardiac output
    to meet demands of work of breathing.
  • Patient should have evidence of adequate cardiac
    output without being on significant inotropic
    support.
  • Patient must be hemodynamically stable. includes
    good perfusion ,age-appropriate blood pressure.

78
Pulmonary
  • Patient should have a patent airway.
  • Pulmonary compliance and resistance should be
    near normal.
  • Patient should have normal blood gas and
    work-of-breathing on the following settings
  • CPAP/PS for 1hr for older children and
    adolescents
  • FiO2 lt40
  • PEEP 3-5cm H2O
  • Spontaneous TV of 5-7ml/kg

79
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