Free
Education  |   September 2012
Home Noninvasive Ventilation: What Does the Anesthesiologist Need to Know?
Author Affiliations & Notes
  • Karen A. Brown, M.D.
    *
  • Gianluca Bertolizio, M.D.
  • Marisa Leone, R.R.T.
  • Steven L. Dain, M.D.
    §
  • *Professor, Division of Pediatric Anesthesia, McGill University Health Center Research Institute, Montreal Children's Hospital, Montreal, Quebec, Canada, and Vice-Chair, Canadian Advisory Committee for the International Organization for Standardization, Technical Committee 121, Subcommittee 3 Breathing Machines. Clinical Fellow, Shriners Hospital for Children Pediatric Anesthesia Fellowship, McGill University, Montreal, Quebec, Canada. Assistant Chief Respiratory Therapist, Department of Pediatric Respiratory Therapy, Montreal Children's Hospital of the McGill University Health Center, Montreal, Quebec, Canada. §Associate Professor, Department of Anesthesia and Perioperative Medicine, Schulich Medicine and Dentistry, University of Western Ontario, London, Ontario, Canada, and Chair, Canadian Advisory Committee for the International Organization for Standardization, Technical Committee 121, Subcommittee 3 Breathing Machines.
Article Information
Education / Airway Management / Pediatric Anesthesia / Respiratory System
Education   |   September 2012
Home Noninvasive Ventilation: What Does the Anesthesiologist Need to Know?
Anesthesiology 9 2012, Vol.117, 657-668. doi:10.1097/ALN.0b013e318263bccc
Anesthesiology 9 2012, Vol.117, 657-668. doi:10.1097/ALN.0b013e318263bccc
NONINVASIVE ventilation (NIV) refers to a technique of augmenting alveolar ventilation without the requirement for an invasive artificial airway. The use of NIV in the home was introduced in the 1980s for the long-term treatment of sleep apnea, and has more recently been used for the management of chronic hypercapnic respiratory failure. Management of acute respiratory failure may also include NIV, both to avoid invasive ventilation and to facilitate weaning from mechanical ventilation. Interested readers are referred to a recent review in Lancet.1 This review focuses on the use of NIV in the home for the management of chronic stable respiratory failure and/or obstructive sleep apnea.
Children with Duchenne muscular dystrophy were among the first patients to be managed with domiciliary NIV therapy. Children currently represent 10% of patients managed in home ventilation programs.2 Children on home NIV therapy are now presenting to anesthesiologists for diagnostic and surgical procedures. There are substantial questions concerning the optimal management of these children: Should they be permitted the use of their own domiciliary NIV medical devices? Are they eligible for ambulatory surgical programs? With respect to their own NIV medical devices, the ECRI Institute (formerly Emergency Care Research Institute) has cautioned hospitals against the use of patient-supplied medical equipment.3,4 The answers to the above require a working understanding of the indications for home NIV therapy, the medical devices used to deliver it, and the impact of sedative and analgesic medications on NIV therapy. This review provides an overview of the indications for NIV therapy, an overview of the medical devices available to deliver NIV therapy, and a specific discussion of management conundrums facing anesthesiologists. The discussion focuses on children, because the use of NIV therapy in the pediatric patient exposes the limitations of NIV systems. However, these pediatric concerns may also be relevant to small adults and patients with poor respiratory muscle strength and reduced respiratory neural drive.
The technique of noninvasive ventilation has two unique features that distinguish it from invasive ventilation with a endotracheal tube. First, noninvasive ventilation employs a nonhermetic technique, and the mask interface is deliberately designed to leak. Second, whereas invasive ventilation bypasses the upper airway with a endotracheal tube, the noninvasive ventilation system incorporates the upper airway into the breathing pathway.5 NIV modalities include continuous positive airway pressure (CPAP) and noninvasive positive airway pressure ventilation (NIPPV), both of which deliver a therapeutic positive airway pressure. NIPPV is also referred to by the acronym NPPV (noninvasive positive pressure ventilation) and BiPAP (bilevel positive airway pressure), and BiPAP®is also the name of a NIV medical device manufactured by Philips Respironics (Murrysville, PA).
An Overview of the Indications for Domiciliary NIV
Medical Indications for Home CPAP Therapy.
In 1981, Colin Sullivan introduced CPAP therapy as a modality to reverse the symptoms of obstructive sleep apnea (OSA).6 CPAP therapy is currently widely prescribed for the management of OSA in adults and in children with OSA refractory to adenotonsillectomy.7,8 During CPAP therapy, the positive airway pressure acts as a pneumatic splint for the pharyngeal airway.9 It also increases lung volume (i.e.  , functional residual capacity).10 Both actions act to decrease the collapsibility of the upper airway and thereby mitigate obstruction of the pharyngeal airway, offset auto-positive end-expiratory pressure, reduce the load on respiratory muscles, and decrease the work of breathing. In adult patients, CPAP levels of 5 and 10 cm H2O may increase tidal volume by 80 ml and 150 ml, respectively. CPAP therapy may also improve gas exchange.11 In patients with coexistent pulmonary disease and OSA, CPAP therapy may also improve lung function. In patients with coexistent heart failure and OSA, CPAP therapy may improve cardiac function.12 
Prescription of home CPAP therapy in children is reserved for those with OSA refractory to adenotonsillectomy. Initiation of CPAP therapy usually involves a CPAP titration study in a sleep laboratory. Once discharged home on CPAP devices, children are followed in outpatient clinics, and their management requires periodic review with overnight polysomnography. Preoperative consultation with the sleep physician or respirologist is important.
Medical Indications for Home NIPPV Therapy.
In chronic respiratory failure associated with neuromuscular disease and morbid obesity, respiratory muscle weakness may lead to hypoventilation during both sleep and wakefulness. Hallmarks of hypoventilation during wakefulness are a chronic compensated respiratory acidosis, i.e.  , daytime hypercapnia with an increased serum bicarbonate level, and a low oxygen saturation on room air during wakefulness. Management of chronic hypercapnic respiratory failure with domiciliary NIPPV in children with neuromuscular and chest wall disease is now standard practice.12  19 
NIPPV therapy aims to deliver a therapeutic pressure during inspiration – the inspiratory positive airway pressure (IPAP) – and hold a positive pressure on exhalation – the expiratory positive airway pressure (EPAP). Like CPAP therapy, bilevel airway pressure therapy aims to splint the pharyngeal airway and preserve lung volume.18 During inspiration, NIPPV therapy further augments airway pressure by increasing inspiratory airflow in order to provide an inspiratory assist to the muscles of respiration. Indeed, NIPPV therapy in adult patients has been shown to improve tidal volume and minute ventilation by 33% and 17%, respectively.18 The use of NIPPV therapy during sleep enhances gas exchange and decreases the work of breathing.13,20 Both exercise tolerance and quality of life improve.21 
As pulmonary function declines, respiratory support during wakefulness may also be indicated. In the past, children with deteriorating respiratory status were supported with a succession of increasingly complex medical devices, culminating in tracheostomy and invasive ventilation. Parents and children currently may prefer to continue with NIPPV therapy, in order to avoid tracheostomy and thereby preserve phonation and swallowing functions important to their quality of life. Children who require both nocturnal and diurnal NIPPV are at very high risk for respiratory complications, because their vital capacity is usually less than 25% predicted, and they have difficulty handling secretions.13 Failure of home NIV therapy occurs more often in these children.2 
Children requiring domiciliary NIPPV therapy are supported and managed in comprehensive home ventilation programs. Medical supervision is provided by sleep physicians and respirologists who provide periodic review, including scheduled overnight polysomnography studies. Therefore, preoperative consultation with these physicians is important, because they form the liaison with the home ventilation program.
An Overview of the Medical Devices Available to Deliver Domiciliary NIV Therapy
The acronym NIV is frequently applied to both the therapy and the device that delivers the therapy. There are presently more than two dozen brands of medical devices to deliver NIV therapy,5 varying in biomedical design complexity from simple sleep apnea equipment to sophisticated home and critical care ventilators with NIV capabilities.
Regulatory bodies classify medical devices by risk1. Class I medical devices are not intended for use in sustaining or supporting life and do not present a risk for injury. Examples of Class I medical devices are stethoscopes, hearing aids and wheelchairs. Class II medical devices are intended to support life, are required to meet mandatory performance standards, are designed to perform without causing injury, and are subject to postmarket surveillance. Examples of Class II medical devices are infusion pumps and ventilators. Medical devices to deliver NIV therapy include both Class I and Class II medical devices. (table 1) Class I medical devices are less expensive than Class II ventilators, a reality that renders them cost-effective for home use.
Table 1. Design Features of Class I and Class II Medical Devices Available for Home Noninvasive Ventilation
Image not available
Table 1. Design Features of Class I and Class II Medical Devices Available for Home Noninvasive Ventilation
×
The Organization for International Standards (ISO) and the International Electrotechnical Commission, both worldwide networks of national standards institutes, develop international standards that provide the requirements for basic safety and performance of medical equipment. These design requirements provide a framework to compare the available medical devices with those that deliver home NIV therapy (table 1). Class I NIV devices comply with the standard, ISO 17510 Part 1.22 Class II ventilators with NIV capabilities comply with ISO 10651–623 or ISO 10651–2.24 For the purpose of this discussion, NIV systems complying with ISO 17510 Part 1 will be referred to as NIV devices. NIV systems complying with ISO 10651–6 or ISO 10651–2 will be referred to as ventilators with NIV capabilities. The same ventilator may be equipped with both noninvasive and invasive ventilation modalities.
The essential components of NIV systems are the flow generator, the breathing circuit, and the NIV mask. (fig. 1) All NIV systems are designed to deliver a therapeutic airway pressure and achieve a positive airway pressure by directing airflow into a mask equipped with a high-resistance exhaust port or expiratory valve. Whereas the driving pressure for the flow generator in critical care ventilators is supplied from either pipelines, compressed gas, or air compressors, in home NIV systems, it is supplied by a servo-controlled air compressor.
Fig. 1. Components of a single-limb circuit noninvasive ventilation system. The exhaust port may be located in the noninvasive ventilation mask or mask connection. Pressure and flow sensors are housed in the flow generator, which also contains a pressure regulation valve. NIV = noninvasive ventilation.
Fig. 1. Components of a single-limb circuit noninvasive ventilation system. The exhaust port may be located in the noninvasive ventilation mask or mask connection. Pressure and flow sensors are housed in the flow generator, which also contains a pressure regulation valve. NIV = noninvasive ventilation.
Fig. 1. Components of a single-limb circuit noninvasive ventilation system. The exhaust port may be located in the noninvasive ventilation mask or mask connection. Pressure and flow sensors are housed in the flow generator, which also contains a pressure regulation valve. NIV = noninvasive ventilation.
×
Two different circuits – double- and single-limb circuits – are available for use in NIV systems, as illustrated in figure 2.5 In double-limb circuits, there are separate inspiratory and expiratory breathing pathways and an expiratory valve (fig. 2A). In single-limb circuits, the inspiratory and expiratory breathing pathway share a common conduit. Single-limb circuits lack an expiratory valve (figs. 2BC, BD), and in single-limb circuits, the expiratory flow cannot be directly measured. In double-limb circuits, the expiratory flow can only be measured directly if the spirometer is interposed between the expiratory valve and the patient (fig. 2A2). Single-limb circuits are the usual circuit used to deliver home NIV therapy.
Fig. 2. Essential components of noninvasive ventilation (NIV) systems using double (AA, AB  ) and single (BD  , BC  ) circuits. In all systems, the flow generator directs a high rate of gas flow through the inspiratory pathway to a NIV mask equipped with an expiratory valve interposed in the circuit (AA  , AB  ) or exhaust port (BC  , BD  ). When applied to the face, this results in an intentional leak and pressurizes the NIV system. Expiratory airflow is only measurable when the flow meter is located between the patient and the expiratory valve (A2  ). In the three other configurations, expiratory airflow cannot be measured directly. NIV = noninvasive ventilation. Reproduced with permission from Rabec et al.  ,5 modified from Perrin C, Jullien V, Lemoigne F: Aspects pratiques et techniques de la ventilation non invasive. Rev Mal Respi 2004;21(3):556–66.
Fig. 2. Essential components of noninvasive ventilation (NIV) systems using double (AA, AB 
	) and single (BD 
	, BC 
	) circuits. In all systems, the flow generator directs a high rate of gas flow through the inspiratory pathway to a NIV mask equipped with an expiratory valve interposed in the circuit (AA 
	, AB 
	) or exhaust port (BC 
	, BD 
	). When applied to the face, this results in an intentional leak and pressurizes the NIV system. Expiratory airflow is only measurable when the flow meter is located between the patient and the expiratory valve (A2 
	). In the three other configurations, expiratory airflow cannot be measured directly. NIV = noninvasive ventilation. Reproduced with permission from Rabec et al. 
	,5modified from Perrin C, Jullien V, Lemoigne F: Aspects pratiques et techniques de la ventilation non invasive. Rev Mal Respi 2004;21(3):556–66.
Fig. 2. Essential components of noninvasive ventilation (NIV) systems using double (AA, AB  ) and single (BD  , BC  ) circuits. In all systems, the flow generator directs a high rate of gas flow through the inspiratory pathway to a NIV mask equipped with an expiratory valve interposed in the circuit (AA  , AB  ) or exhaust port (BC  , BD  ). When applied to the face, this results in an intentional leak and pressurizes the NIV system. Expiratory airflow is only measurable when the flow meter is located between the patient and the expiratory valve (A2  ). In the three other configurations, expiratory airflow cannot be measured directly. NIV = noninvasive ventilation. Reproduced with permission from Rabec et al.  ,5 modified from Perrin C, Jullien V, Lemoigne F: Aspects pratiques et techniques de la ventilation non invasive. Rev Mal Respi 2004;21(3):556–66.
×
NIV systems lack a reservoir bag, a design feature that facilitates the delivery of a constant positive airway pressure throughout the phases of the respiration. However, the absence of a reservoir bag requires a design that ensures an adequate peak inspiratory flow rate. These design features include a high rate of gas flow and/or an alternate inspiratory pathway. In normal operation, the level of inspiratory gas flow delivered through the breathing tube ranges from 20 to 60 l/min.
The NIV mask complies with ISO 17510–2.25 The NIV mask is used interchangeably with Class I NIV devices and Class II ventilators with NIV capabilities. Delivery of NIV therapy relies on a nonhermetic technique and requires a high-resistance exhaust port/expiratory valve located on the mask or mask connection. The exhaust port discharges a continuous intentional leak during normal operating conditions. In addition, the imperfect seal of the mask to the face is an additional source of leakage: the unintentional leak. The magnitude of the unintentional leak varies with the phase of respiration, with shifts in the mask position and with changes in the compliance and resistance of the upper airway and respiratory system. Modern NIV devices are equipped with microprocessors and sophisticated proprietary algorithms that adjust the rate of gas flow to compensate for the variable unintentional leak.
Although NIV systems will fit a 15 mm/22 mm connector, they are not intended for use with tracheal tubes. The leak around an invasive uncuffed tracheostomy tube is insufficient to adequately discharge the high rate of inspiratory gas flow, in excess of 20 l/min, without injury. Home ventilators for invasive ventilation are indicated in tracheostomized patients.23 
NIV systems have three additional design features. First, all NIV devices are equipped with a pressure sensor located in the flow generator to detect high airway pressure. Second, all NIV systems are equipped with a pressure regulation valve in the flow generator and design features to limit the maximum pressure to 40 cm H2O in Class 1 NIV devices and to 60 cm H2O in Class II ventilators with NIV capabilities (table 1). And third, home NIV devices are intended for dedicated use in single patient and are not designed to function with in-line filters.
CPAP Devices.
CPAP devices are designed to deliver a continuous distending pressure throughout the patient's respiratory cycle.26 The minimum performance for the delivery of positive airway pressure is ± 1.5 cm H2O of the set pressure.22,27 
NIPPV Systems.
NIPPV devices are designed to deliver a cyclical application of two levels of positive pressure: IPAP and EPAP. This requires design features that sense the phase of respiration8,26 and trigger the transitions between IPAP and EPAP.
The Inspiratory Trigger between EPAP and IPAP
The trigger for IPAP is initiated by the patient's inspiratory effort and is detected by a change in airway pressure or gas flow within the NIV system.5 Most modern NIV systems achieve the transitions between IPAP and EPAP with flow-based triggers. Sophisticated proprietary algorithms have been developed to detect phasic changes in gas flow, gas waveforms, and flow reversal(s). Asynchrony between the child and NIV system during the inspiratory trigger is common especially during sleep, and therefore some homecare NIV protocols require a backup ventilation rate. The selected backup rate is often set at a rate higher than the child's spontaneous rate during sleep, effectively instituting a controlled mode of ventilator support.8 NIV devices, however, are not intended for use in apneic patients (table 1).
The Expiratory Trigger between IPAP and EPAP
The trigger for expiration may be either a function of time or a threshold decline in inspiratory flow.8 In children, a maximum inspiratory time of 0.3–0.5 s is often used.
The sensitivity of the trigger function represents an important limit to the use of NIPPV in small children, particularly those with poor respiratory muscle strength,18,26,28 because their low rates of inspiratory flow may be insufficient to initiate the inspiratory trigger.8 This is one of the reasons NIV devices are not intended for use in patients weighing less than 30 kg. For these children, ventilators with NIV capabilities offer a better option.
Pressure-targeted NIPPV Systems
Most bilevel pressure NIV systems achieve the IPAP level by increasing the rate of gas flow during inspiration, until the predefined positive airway pressure target is attained. It is beyond the scope of this review to discuss all NIV modalities, and readers are directed to a comprehensive review in Thorax.5 The two basic NIV modalities are pressure-targeted NIPPV and volume-targeted NIPPV. The majority of home NIV systems use pressure-targeted modalities.
The EPAP is titrated to eliminate obstructive airway events, and IPAP is titrated to attenuate hypercarbia during sleep. The usual levels of IPAP and EPAP range from 10 to 16 cm H2O and from 4 to 5 cm H2O, respectively. NIPPV devices have less pressure-generating capacity than ventilators.7 The magnitude of inspiratory assist depends on the difference between IPAP and EPAP.18 However, the NIV system–lung assembly does not behave as a single compartment model, because the upper airway presents a variable resistance. Increasing the airway pressure may not increase the effective ventilation to the patient.5 
Volume-targeted Devices
Volume-targeted NIPPV devices deliver a set flow to the airway for a defined time interval or until a preset volume is obtained. The presence of leaks at the mask interface requires a design feature capable of delivering very large gas flows during the inspiratory phase of the respiratory cycle.8 These gas flow rates may exceed 150 l/min.
The Interface and the NIV Mask
NIV therapy is delivered with a nasal or full-face mask. The NIV mask design is deliberately nonhermetic, allowing the mask to be adjusted to comfort. The mask must be soft and secure and yet allow for sweating. Velcro straps applied too tightly to a full-face mask may displace the mandible backward, allowing the tongue to obstruct the upper airway.8 In addition, a tight, ill-fitted mask risks skin injury and ulceration. Too tight a mask, worn over many years, may adversely affect the growth and development of facial bones.1 Although the patient connection port may be a 15 mm/22 mm connector,22,25 NIV systems are not designed for use with a endotracheal tube, tracheostomy tube, laryngeal mask, or anesthesia mask. If the expiratory trigger failed and the high inspiratory gas flow continued during expiration, the patient could become hyperinflated, risking barotrauma and injury.
For children, nasal masks are preferred, in part to minimize the apparatus dead space and facilitate the trigger functions of the NIV systems. During normal operation, mouth breathing increases the gas leakage, and parents may devise ways and means to ensure the mouth remains closed during sleep (i.e.  , chin straps).
In pressure-targeted NIV systems, the magnitude of the inspiratory assist decreases during perturbations such as increased upper airway resistance, decreased lung compliance, or increased unintentional leak. Modern NIV systems offer a “volume guarantee” mode that will deliver a minimum level of ventilation when such perturbations occur. The efficacy of the “volume guarantee” mode was recently tested in six NIV systems.29 Perturbations sufficient to decrease tidal volume (VT) were determined. The ventilators were set in the “volume guarantee” mode to deliver a minimum VT. The response to a perturbation was to increase IPAP (fig. 3). With perturbations in airway resistance or lung compliance, five of six NIV systems achieved the guaranteed minimum VT. However, when the unintentional leak increased, only one NIV system achieved it. Auto-triggering, or the delivery of a breath cycle without the patient triggering a breath, occurred frequently during large unintentional leaks. In addition, a large unintentional leak may preclude attainment of the preset IPAP, and the NIV system may not cycle to EPAP,8,18 allowing the high rate of gas flow to continue even if the patient ceases to inhale. This high gas flow rate will impede exhalation, increasing the work of breathing and risking barotraumas, gastric insufflation, and aspiration of stomach contents. Large unintentional leaks at the mask interface are particularly common in children.
Fig. 3. Representative tracing showing the response to a noninvasive ventilation system with a “minimum guarantee” mode to a perturbation. The inspiratory positive airway pressure increased in order to achieve the minimum guaranteed tidal volume. The onset and offset response times ranged from 1 to 51 breaths. The tidal volume decreased transiently during the onset and increased transiently during the offset. The specific responses to three types of perturbations are shown in the accompanying table. IPAP = inspiratory positive airway pressure; NIV = noninvasive ventilation; VT= tidal volume. Adapted from Fauroux et al.  29 and reprinted with permission.
Fig. 3. Representative tracing showing the response to a noninvasive ventilation system with a “minimum guarantee” mode to a perturbation. The inspiratory positive airway pressure increased in order to achieve the minimum guaranteed tidal volume. The onset and offset response times ranged from 1 to 51 breaths. The tidal volume decreased transiently during the onset and increased transiently during the offset. The specific responses to three types of perturbations are shown in the accompanying table. IPAP = inspiratory positive airway pressure; NIV = noninvasive ventilation; VT= tidal volume. Adapted from Fauroux et al.  29and reprinted with permission.
Fig. 3. Representative tracing showing the response to a noninvasive ventilation system with a “minimum guarantee” mode to a perturbation. The inspiratory positive airway pressure increased in order to achieve the minimum guaranteed tidal volume. The onset and offset response times ranged from 1 to 51 breaths. The tidal volume decreased transiently during the onset and increased transiently during the offset. The specific responses to three types of perturbations are shown in the accompanying table. IPAP = inspiratory positive airway pressure; NIV = noninvasive ventilation; VT= tidal volume. Adapted from Fauroux et al.  29 and reprinted with permission.
×
Rebreathing Potential in NIV Devices
Although the ECRI Institute considers the patient-supplied NIV mask less hazardous than the NIV device, it is the design of the NIV mask that influences the risk of rebreathing. Washout of carbon dioxide is more efficient if the exhaust port is located within the mask.4,5 
Dual-limb NIV systems mitigate the degree of rebreathing by using an expiratory valve and separating the inspiratory and expiratory pathways.5 In a single-limb NIV system, the inspiratory and expiratory breathing pathway share a common conduit (fig. 4). As the exhaust port purposely offers a high resistance, the expiratory pathway may include the low-resistance breathing tube. A high rate of gas flow is required to prevent rebreathing during normal use.30 The risk of rebreathing decreases with increasing airway pressure (higher gas flows). The NIV systems are designed such that during normal use, the time-weighted average for inspired carbon dioxide is 1%, a limit which harmonizes with that allowed in occupational health exposure.25 A minimum mandatory EPAP level of 3 or 4 cm H2O (gas flow around 20 l/min) is needed to ensure adequate washout of exhaled carbon dioxide.
Fig. 4. Gas pathway in noninvasive ventilation system using a single-limb circuit. During normal use, the flow generator directs air into the breathing tube, which contains an admixture of fresh and exhaled gas. The admixture of fresh and exhaled gas is designed to egress the system via  the exhaust port (intentional leak) and noninvasive ventilation mask interface (unintentional leak).
Fig. 4. Gas pathway in noninvasive ventilation system using a single-limb circuit. During normal use, the flow generator directs air into the breathing tube, which contains an admixture of fresh and exhaled gas. The admixture of fresh and exhaled gas is designed to egress the system via 
	the exhaust port (intentional leak) and noninvasive ventilation mask interface (unintentional leak).
Fig. 4. Gas pathway in noninvasive ventilation system using a single-limb circuit. During normal use, the flow generator directs air into the breathing tube, which contains an admixture of fresh and exhaled gas. The admixture of fresh and exhaled gas is designed to egress the system via  the exhaust port (intentional leak) and noninvasive ventilation mask interface (unintentional leak).
×
The risk of rebreathing is maximal when inspiratory gas flow ceases. In the event of a power failure, the inspired carbon dioxide level will rise precipitously, coincident with a fall in inspired oxygen (fig. 5). Although a battery reserve should protect from electrical power failure, battery life is difficult to predict and often brief. Class I medical devices may not be equipped with a battery backup. Therefore, the design of NIV equipment incorporates a means to allow spontaneous breathing in the event of a device failure. This may be accomplished by including an antiasphyxiation valve in the NIV mask. A nasal NIV mask should have less risk of asphyxiation because the child can initiate mouth breathing. However, mouth breathing may not be possible if chin straps are used. In NIV systems, the short-term exposure limit for inhaled carbon dioxide is 3% (about 22 mmHg), a limit that assumes that the physiologic arousal response will be sufficient to rouse the patient.22,25 
Fig. 5. Rebreathing potential in noninvasive ventilation systems. During normal use, elimination of exhaled carbon dioxide depends on a high rate of gas flow. In the conventional continuous positive airway pressure system (A  ), an electrical power-off scenario results in rebreathing of exhaled gas. There is a rapid rise in inspired carbon dioxide and fall in inspired oxygen concentration. Design features that include nonrebreathing valves (B  ) mitigate the risk for rebreathing. NIV = noninvasive ventilation. Reproduced with permission from Farréet al.  30 
Fig. 5. Rebreathing potential in noninvasive ventilation systems. During normal use, elimination of exhaled carbon dioxide depends on a high rate of gas flow. In the conventional continuous positive airway pressure system (A 
	), an electrical power-off scenario results in rebreathing of exhaled gas. There is a rapid rise in inspired carbon dioxide and fall in inspired oxygen concentration. Design features that include nonrebreathing valves (B 
	) mitigate the risk for rebreathing. NIV = noninvasive ventilation. Reproduced with permission from Farréet al.  30
Fig. 5. Rebreathing potential in noninvasive ventilation systems. During normal use, elimination of exhaled carbon dioxide depends on a high rate of gas flow. In the conventional continuous positive airway pressure system (A  ), an electrical power-off scenario results in rebreathing of exhaled gas. There is a rapid rise in inspired carbon dioxide and fall in inspired oxygen concentration. Design features that include nonrebreathing valves (B  ) mitigate the risk for rebreathing. NIV = noninvasive ventilation. Reproduced with permission from Farréet al.  30 
×
Inspired Oxygen Concentration
During power failure, with cessation of gas flow, the rebreathing of exhaled gases will allow a hypoxic admixture to accumulate in the breathing tube (fig. 5).30 In the event of a power failure, it is expected that the sleeping patient will rouse and remove the NIV mask.
During normal use, supplemental oxygen may be intentionally delivered into the breathing tube or the mask interface. Several factors influence the inspired oxygen concentration, including the NIV modality, the rate of gas flow rate, the minute ventilation, and the location at which oxygen is delivered into the NIV system. In healthy volunteers on NIV therapy, a maximum inspired oxygen concentration of 67% was reported.31 However, the inspiratory oxygen concentration achieved in patients on NIV devices is often less than 50%.
Perioperative Management Conundrums in Patients Supported with Domiciliary NIV
Patient Selection.
The safe use of NIV to support ventilation following surgery requires selection of both appropriate patients and NIV systems, and a recognition that the clinical scenario in the hospital differs from that in the home environment.
In hospitalized patients, eligibility criteria for NIV support are the ability to call for help, to pass 15 min off NIV without respiratory decompensation, and to maintain oxygen saturation with modest inspired oxygen concentrations.1,32 Health Canada advises that patients who have a limited ability to adjust or remove the NIV mask should be attended at all times.2NIV therapy is contraindicated if children are apneic, unable to protect their own airway, unable to maintain the patency of the upper airway, have a reduced level of consciousness, or have an unstable respiratory status.33 
Can Children Supported with Home NIV Systems Be Managed in Ambulatory Surgical Programs?
Class I NIV devices and some Class II ventilators with NIV capabilities are not intended to support life (table 1). These NIV systems rely on the patient's reflex and arousal mechanisms to monitor the function of the NIV system. Sedative and analgesic medication may blunt arousal and reflex defenses. Because the safe use of NIV systems is predicated on an intact physiologic defense system, children on domiciliary NIV systems should not be discharged home until these protective and defense mechanisms have returned13 (fig. 6). Children with continuous home NIPPV therapy have a limited respiratory reserve and are at extreme risk for respiratory complications following anesthesia and surgery. These children are poor candidates for ambulatory programs.13 
Fig. 6. Discharge criteria for patients supported with home continuous positive airway pressure devices.
Fig. 6. Discharge criteria for patients supported with home continuous positive airway pressure devices.
Fig. 6. Discharge criteria for patients supported with home continuous positive airway pressure devices.
×
Which Surgical Procedures?
As NIV systems include the upper airway in the breathing pathway, compromise of nasopharyngeal airway patency may limit the efficacy of NIV therapy. Surgeries associated with upper airway edema, bleeding, nasal congestion, and surgical packings may obstruct the upper airway, and affect the efficacy of NIV therapy. Pulmonary function may be affected in the postoperative period, and supplemental oxygen may be required. In addition, the settings for the NIV system may require adjustment. IPAP levels of 10–16 cm H2O usually provide sufficient support. Children become uncomfortable if IPAP settings exceed 20 cm H2O.18 The maximum IPAP for preadolescent children is 20 cm H2O, and for adolescents the maximum is 30 cm H2O.34 Higher levels of IPAP may increase the gas leak, and the straps securing the NIV mask may require adjustment.
Can NIV Be Safely Administered on Hospital Wards?
Expertise of Healthcare Providers.
The challenges of delivering NIPPV therapy on hospital wards are illustrated by two published scenarios in patients with advanced cystic fibrosis. An adolescent on continuous NIPPV was found unresponsive on the floor, having removed the NIPPV system without notifying his nurse. A young adult with chronic respiratory failure developed agitation because of respiratory acidosis. Trigger asynchrony was suspected, and she was treated with intravenous sedation. The respiratory status further deteriorated, requiring invasive ventilation.17 
Because NIV devices are used in a home environment, their use on hospital wards might seem reasonable. However, mishaps during NIV therapy have been reported in hospitalized patients. In one case, the CPAP device was misassembled.35 Another patient died because of NIV system failure, and a third death was linked to NIV system-related infection.3 Health Canada advises that medical staff caring for patients supported by NIV systems should be knowledgeable of the capacities and limitations of NIV systems.2The safe use of NIV therapy on the wards requires the selection of patients with stable respiratory failure, the availability of expert and adequately trained staff throughout a 24-h period, adequate monitoring, and immediate access to invasive ventilation in the event of respiratory deterioration.1,32 
In addition, the settings for NIV systems that are adequate in the home environment may not be therapeutic in the postoperative period, as illustrated in figures from three consecutive nocturnal NIV recordings (figs. 7and 8). Figure 7A is a representative baseline trace of internally logged data from a home NIV system; the set EPAP and IPAP levels of 4 and 15 cm H2O, respectively, were achieved throughout 13 h of use. During the majority of the record, there were no patient-triggered breaths, and ventilation was supported entirely with the NIV system, at a backup rate of 25 breaths/min. The estimated tidal volume was 277 ml and the estimated minute ventilation was 6.8 l/min. Following surgery (fig. 7B), the set EPAP and IPAP levels were identical and achieved throughout 18 h of use. However, patient-triggered breaths are now present throughout the record, likely reflecting a combination of wakefulness and pain. The recorded tidal volume has decreased to 202 ml. During the following night (fig. 8), the set EPAP and IPAP levels were unchanged and achieved throughout the 22 h of use, but the recorded tidal volume has now decreased to 98 ml. The levels of positive airway pressure, which were therapeutic in the home environment, are now inadequate.
Fig. 7. Representative figures illustrating the limitations of a noninvasive positive pressure ventilation system in the hospital environment. In both the home (A  ) and hospital (B  ) use scenarios, the set levels of inspiratory positive airway pressure and expiratory positive airway pressure were identical. However, the efficacy of the ventilatory support differed. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 7. Representative figures illustrating the limitations of a noninvasive positive pressure ventilation system in the hospital environment. In both the home (A 
	) and hospital (B 
	) use scenarios, the set levels of inspiratory positive airway pressure and expiratory positive airway pressure were identical. However, the efficacy of the ventilatory support differed. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 7. Representative figures illustrating the limitations of a noninvasive positive pressure ventilation system in the hospital environment. In both the home (A  ) and hospital (B  ) use scenarios, the set levels of inspiratory positive airway pressure and expiratory positive airway pressure were identical. However, the efficacy of the ventilatory support differed. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
×
Fig. 8. Representative figure in a postoperative scenario showing the limitation of the same noninvasive positive pressure ventilation system illustrated in Fig. 7. The set levels of inspiratory positive airway pressure and expiratory positive airway pressure remain unchanged from those in figs. 7A and 7B; however, the level of ventilatory support is much lower. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 8. Representative figure in a postoperative scenario showing the limitation of the same noninvasive positive pressure ventilation system illustrated in Fig. 7. The set levels of inspiratory positive airway pressure and expiratory positive airway pressure remain unchanged from those in figs. 7A and 7B; however, the level of ventilatory support is much lower. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 8. Representative figure in a postoperative scenario showing the limitation of the same noninvasive positive pressure ventilation system illustrated in Fig. 7. The set levels of inspiratory positive airway pressure and expiratory positive airway pressure remain unchanged from those in figs. 7A and 7B; however, the level of ventilatory support is much lower. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
×
Monitoring and Alarms: Do NIV Systems Monitor Ventilation?
All NIV systems are required to measure airway pressure, and the majority of modern NIV systems log parameters of airway pressure for periodic review. However, a data log is not synonymous with a monitor. Class I medical devices are not designed to monitor patients, and patient well-being is the prime indicator that an NIV device is functioning. A feature that distinguishes the Class II NIV systems from Class I NIV devices is the requirement, in the former, to monitor the ventilation of the patient (table 1). Class II ventilators for ventilator-dependant patients are intended to deliver both positive airway pressure and ventilation and are therefore designed appropriately.24 
Home ventilation programs define ineffective ventilation by the failure to attain the set airway pressures, an excessive unintentional leak, and frequent desaturation indices.36 Capnography is not used in the home environment. Some manufacturers have developed sophisticated proprietary algorithms that assess gas flows and estimate the unintentional leaks of the NIV system. In addition, there are proprietary algorithms that estimate the delivered minute ventilation and VTof the patient. However, the accuracy and clinical relevance of the reported physiologic parameters lack validation. Recent bench studies suggest that VTis underestimated, especially at high IPAP pressures.37 In the home environment, there is no need for bedside reporting of data, because the efficacy of the NIV therapy is assessed by patient well-being and periodic review of the internally logged data. In hospitalized patients it may prove useful to review this internally logged data, but currently this feature is not readily available at the bedside.
If Patients on Domiciliary NIV Are Not Being Monitored at Home, Do They Need to Be Monitored While in the Hospital?
Unless the ventilation is being monitored at the bedside, changes in the ventilatory status may not be obvious. Health Canada advises that hospitalized patients supported with NIV systems must be monitored with oxygen saturation and vital signs.2Arterial or capillary blood gases may also be indicated. Although capnography is available in hospitals, its accuracy in NIV systems may be influenced by dead space, VT, and the high rate of gas flow. Transcutaneus measurement of carbon dioxide may be more useful in the hospital environment.36 
Should Children Be Permitted the Use of Their Own Domiciliary NIV Systems?
Of the task force's consultants charged with developing guidelines for the perioperative management of patients with OSA, 79% strongly agreed that patients should be restarted on their home NIV therapy as soon as feasible after surgery.38 Parents and children often request the use their own NIV system while in the hospital, citing differences among NIV systems in leakage, trigger sensitivities, type of circuit, and position of the exhaust port – all of which may affect the quality of ventilatory support.39  41 In the home environment, the NIV systems are reported to be robust and reliable,8,33,42 and this request may seem reasonable. However, whereas the use of patient-supplied NIV masks is condoned, the ECRI Institute cautions hospitals against the use of patient-supplied NIV systems.3,4 
Most countries lack a centralized database for reporting problems with home NIV systems.2 The lack of reporting is not evidence of safety, as Health Canada cautions that rates for spontaneously reported adverse incidents (with NIV systems) are presumed to underestimate the risk.2A multicenter evaluation of 22 conventional NIV systems reported significant differences between the set parameters and the actual values. In 17% of patients, the index of ventilator error exceeded 20%. In addition, home NIV systems underperform when subjected to high-level requirements similar to those which may occur during the postoperative period.43 
Another major issue with patient-supplied NIV systems is that the alarms have frequently been disabled, because most (i.e.  , low VT) enunciate so frequently they constitute a nuisance and disrupt sleep.33,43 A feature that distinguishes the Class II NIV systems from Class I NIV devices is the requirement, in the former, to enunciate alarm conditions intended to summon help (table 1). Disabling alarms on ventilators with NIV capabilities negates the safety design features that distinguish Class II from Class I medical devices. In the postoperative period, when the patient's clinical state may change rapidly, ventilators with NIPPV capabilities, which are designed for ventilator-dependant patients, may provide more reliable respiratory support. At some point before discharge, transition to a domiciliary NIV system and liaison with the home ventilation program is required (fig. 9).
Fig. 9. Decision tree for the selection of a medical device to deliver noninvasive positive pressure ventilation in the hospitalized postoperative patient. ISO = Organization for International Standardization; NIPPV = noninvasive positive pressure ventilation; NIV = noninvasive ventilation.
Fig. 9. Decision tree for the selection of a medical device to deliver noninvasive positive pressure ventilation in the hospitalized postoperative patient. ISO = Organization for International Standardization; NIPPV = noninvasive positive pressure ventilation; NIV = noninvasive ventilation.
Fig. 9. Decision tree for the selection of a medical device to deliver noninvasive positive pressure ventilation in the hospitalized postoperative patient. ISO = Organization for International Standardization; NIPPV = noninvasive positive pressure ventilation; NIV = noninvasive ventilation.
×
Recommendations
Anesthesiologists increasingly encounter children who are supported on home NIV therapy and are asked for advice on their perioperative management. The optimal transition from sedation and/or general anesthesia to their home NIV system is an area of study, and practice guidelines for the safe management of patients supported with home NIV systems have yet to be developed. Our recommendations are listed in table 2. As the intensive care unit is the only location in our hospital with continuously available expertise in NIV systems, all children requiring NIV therapy in the postoperative period are initially admitted to the intensive care unit following anesthesia. Our caseload of the children on home NIV therapy is small, and this requirement has not proven problematic. Recovery of both defensive and protective reflexes and transition to the home NIV system should occur before discharge from hospital.
Table 2. Recommendations for the Perioperative Management of Children Supported with Home Noninvasive Ventilation Therapy
Image not available
Table 2. Recommendations for the Perioperative Management of Children Supported with Home Noninvasive Ventilation Therapy
×
Summary
Treatment of refractory obstructive sleep apnea and chronic respiratory failure with home NIV is now standard pediatric practice. Anesthetic and analgesic medications induce apnea, depress respiratory drive, decrease compliance of the respiratory system, increase the collapsibility of the upper airway, and alter the sensorium, thereby compromising NIV therapy. Just as knowledge of pharmacology underlies the safe prescription of medication, so too knowledge of biomedical design underlies the safe prescription of NIV medical devices. The medical device design requirements developed by the Organization for International Standardization provide a framework to rationalize our choice of the medical device to support ventilation in the postoperative patient who has been supported with a domiciliary NIV system.
References
Nava S, Hill N: Non-invasive ventilation in acute respiratory failure. Lancet 2009; 374:250–9
Simonds AK: Risk management of the home ventilator dependent patient. Thorax 2006; 61:369–71
ECRI Institute: Hazard report. Using patient-supplied respiratory care equipment in hospitals. Health Devices 2009; 38:417–8
ECRI Institute: Guidance Article. Part 2. Managing the use of patient-supplied medical devices: Should patients be allowed their own medical devices in the hospital. Health Devices 2007; 155–64
Rabec C, Rodenstein D, Leger P, Rouault S, Perrin C, Gonzalez-Bermejo J, SomnoNIV Group: Ventilator modes and settings during non-invasive ventilation: Effects on respiratory events and implications for their identification. Thorax 2011; 66:170–8
Sullivan CE, Issa FG, Berthon-Jones M, Eves L: Reversal of obstructive sleep apnea by continuous positive airway pressure applied through the nares. Lancet 1981; 1:862–5
Mehta S, Hill NS: Noninvasive ventilation. Am J Respir Crit Care Med 2001; 163:540–77
Nørregaard O: Noninvasive ventilation in children. Eur Respir J 2002; 20:1332–42
Hoffstein V, Zamel N, Phillipson EA: Lung volume dependence of pharyngeal cross-sectional area in patients with obstructive sleep apnea. Am Rev Respir Dis 1984; 130:175–8
Isono S, Shimada A, Utsugi M, Konno A, Nishino T: Comparison of static mechanical properties of the passive pharynx between normal children and children with sleep-disordered breathing. Am J Respir Crit Care Med 1998; 157:1204–12
Andersson B, Lundin S, Lindgren S, Stenqvist O, Odenstedt Hergès H: End-expiratory lung volume and ventilation distribution with different continuous positive airway pressure systems in volunteers. Acta Anaesthesiol Scand 2011; 55:157–64
Theerakittikul T, Ricaurte B, Aboussouan LS: Noninvasive positive pressure ventilation for stable outpatients: CPAP and beyond. Cleve Clin J Med 2010; 77:705–14
Ward S, Chatwin M, Heather S, Simonds AK: Randomised controlled trial of non-invasive ventilation (NIV) for nocturnal hypoventilation in neuromuscular and chest wall disease patients with daytime normocapnia. Thorax 2005; 60:1019–24
Laursen SB, Dreijer B, Hemmingsen C, Jacobsen E: Bi-level positive airway pressure treatment of obstructive sleep apnoea syndrome. Respiration 1998; 65:114–9
Guilleminault C, Pelayo R, Clerk A, Leger D, Bocian RC: Home nasal continuous positive airway pressure in infants with sleep-disordered breathing. J Pediatr 1995; 127:905–12
Waters KA, Everett FM, Bruderer JW, Sullivan CE: Obstructive sleep apnea: The use of nasal CPAP in 80 children. Am J Respir Crit Care Med 1995; 152:780–5
Teague WG: Non-invasive positive pressure ventilation: Current status in paediatric patients. Paediatr Respir Rev 2005; 6:52–60
Fauroux B, Pigeot J, Polkey MI, Roger G, Boulé M, Clément A, Lofaso F: Chronic stridor caused by laryngomalacia in children: Work of breathing and effects of noninvasive ventilatory assistance. Am J Respir Crit Care Med 2001; 164:1874–8
Edwards EA, Hsiao K, Nixon GM: Paediatric home ventilatory support: The Auckland experience. J Paediatr Child Health 2005; 41:652–8
Padman R, Lawless ST, Kettrick RG: Noninvasive ventilation via  bilevel positive airway pressure support in pediatric practice. Crit Care Med 1998; 26:169–73
Young AC, Wilson JW, Kotsimbos TC, Naughton MT: Randomised placebo controlled trial of non-invasive ventilation for hypercapnia in cystic fibrosis. Thorax 2008; 63:72–7
International Standard ISO-17510–1: Sleep Apnoea Therapy Part 1. Geneva, Switzerland: International Organization for Standardization; 2007
International Standard ISO-10651–6: Lung ventilators for medical use: Particular requirements for basic safety and essential performance. Part 6: Home-care ventilatory support devices. Geneva, Switzerland: International Organization for Standardization; 2004
International Standard ISO-10651–2: Lung ventilators for medical use: Particular requirements for basic safety and essential performance. Part 2: Home ventilators for ventilator-dependant patients. Geneva, Switzerland: International Organization for Standardization; 2004
International Standard ISO-17510–2: Sleep Apnea Therapy Part 2: Masks and application accessories. Geneva, Switzerland: International Organization for Standardization; 2007
Essouri S, Nicot F, Clément A, Garabedian EN, Roger G, Lofaso F, Fauroux B: Noninvasive positive pressure ventilation in infants with upper airway obstruction: Comparison of continuous and bilevel positive pressure. Intensive Care Med 2005; 31:574–80
Antonescu-Turcu A, Parthasarathy S: CPAP and bi-level PAP therapy: New and established roles. Respir Care 2010; 55:1216–29
Stucki P, Perez MH, Scalfaro P, de Halleux Q, Vermeulen F, Cotting J: Feasibility of non-invasive pressure support ventilation in infants with respiratory failure after extubation: A pilot study. Intensive Care Med 2009; 35:1623–7
Fauroux B, Leroux K, Pépin JL, Lofaso F, Louis B: Are home ventilators able to guarantee a minimal tidal volume? Intensive Care Med 2010; 36:1008–14
Farré R, Montserrat JM, Ballester E, Navajas D: Potential rebreathing after continuous positive airway pressure failure during sleep. Chest 2002; 121:196–200
Samolski D, Anton A, Güell R, Sanz F, Giner J, Casan P: Inspired oxygen fraction achieved with a portable ventilator: Determinant factors. Respir Med 2006; 100:1608–13
Elliott MW, Confalonieri M, Nava S: Where to perform noninvasive ventilation? Eur Respir J 2002; 19:1159–66
Samuels M, Bolt P: Non-invasive ventilation in children. Paediatr Child Health 2007; 17:167–73
Kushida CA, Chediak A, Berry RB, Brown LK, Gozal D, Iber C, Parthasarathy S, Quan SF, Rowley JA, Positive Airway Pressure Titration Task Force, American Academy of Sleep Medicine: Clinical guidelines for the manual titration of positive airway pressure in patients with obstructive sleep apnea. J Clin Sleep Med 2008; 4:157–71
Hove LD, Steinmetz J, Christoffersen JK, Møller A, Nielsen J, Schmidt H: Analysis of deaths related to anesthesia in the period 1996–2004 from closed claims registered by the Danish Patient Insurance Association. ANESTHESIOLOGY 2007; 106:675–80
Janssens JP, Borel JC, Pépin JL, SomnoNIV Group: Nocturnal monitoring of home non-invasive ventilation: The contribution of simple tools such as pulse oximetry, capnography, built-in ventilator software and autonomic markers of sleep fragmentation. Thorax 2011; 66:438–45
Contal O, Vignaux L, Combescure C, Pepin JL, Jolliet P, Janssens JP: Monitoring of noninvasive ventilation by built-in software of home bilevel ventilators: A bench study. Chest 2012; 141:469–76
Gross JB, Bachenberg KL, Benumof JL, Caplan RA, Connis RT, Coté CJ, Nickinovich DG, Prachand V, Ward DS, Weaver EM, Ydens L, Yu S, American Society of Anesthesiologists Task Force on Perioperative Management: Practice guidelines for the perioperative management of patients with obstructive sleep apnea: A report by the American Society of Anesthesiologists Task Force on Perioperative Management of patients with obstructive sleep apnea. ANESTHESIOLOGY 2006; 104:1081–93
Schettino GP, Chatmongkolchart S, Hess DR, Kacmarek RM: Position of exhalation port and mask design affect CO2 rebreathing during noninvasive positive pressure ventilation. Crit Care Med 2003; 31:2178–82
Fauroux B, Leroux K, Desmarais G, Isabey D, Clément A, Lofaso F, Louis B: Performance of ventilators for noninvasive positive-pressure ventilation in children. Eur Respir J 2008; 31:1300–7
Bunburaphong T, Imanaka H, Nishimura M, Hess D, Kacmarek RM: Performance characteristics of bilevel pressure ventilators: A lung model study. Chest 1997; 111:1050–60
Reiter K, Pernath N, Pagel P, Hiedi S, Hoffmann F, Schoen C, Nicolai T: Risk factors for morbidity and mortality in pediatric home mechanical ventilation. Clin Pediatr (Phila) 2011; 50:237–43
Farré R, Navajas D, Prats E, Marti S, Guell R, Montserrat JM, Tebe C, Escarrabill J: Performance of mechanical ventilators at the patient's home: A multicentre quality control study. Thorax 2006; 61:400–4
Fig. 1. Components of a single-limb circuit noninvasive ventilation system. The exhaust port may be located in the noninvasive ventilation mask or mask connection. Pressure and flow sensors are housed in the flow generator, which also contains a pressure regulation valve. NIV = noninvasive ventilation.
Fig. 1. Components of a single-limb circuit noninvasive ventilation system. The exhaust port may be located in the noninvasive ventilation mask or mask connection. Pressure and flow sensors are housed in the flow generator, which also contains a pressure regulation valve. NIV = noninvasive ventilation.
Fig. 1. Components of a single-limb circuit noninvasive ventilation system. The exhaust port may be located in the noninvasive ventilation mask or mask connection. Pressure and flow sensors are housed in the flow generator, which also contains a pressure regulation valve. NIV = noninvasive ventilation.
×
Fig. 2. Essential components of noninvasive ventilation (NIV) systems using double (AA, AB  ) and single (BD  , BC  ) circuits. In all systems, the flow generator directs a high rate of gas flow through the inspiratory pathway to a NIV mask equipped with an expiratory valve interposed in the circuit (AA  , AB  ) or exhaust port (BC  , BD  ). When applied to the face, this results in an intentional leak and pressurizes the NIV system. Expiratory airflow is only measurable when the flow meter is located between the patient and the expiratory valve (A2  ). In the three other configurations, expiratory airflow cannot be measured directly. NIV = noninvasive ventilation. Reproduced with permission from Rabec et al.  ,5 modified from Perrin C, Jullien V, Lemoigne F: Aspects pratiques et techniques de la ventilation non invasive. Rev Mal Respi 2004;21(3):556–66.
Fig. 2. Essential components of noninvasive ventilation (NIV) systems using double (AA, AB 
	) and single (BD 
	, BC 
	) circuits. In all systems, the flow generator directs a high rate of gas flow through the inspiratory pathway to a NIV mask equipped with an expiratory valve interposed in the circuit (AA 
	, AB 
	) or exhaust port (BC 
	, BD 
	). When applied to the face, this results in an intentional leak and pressurizes the NIV system. Expiratory airflow is only measurable when the flow meter is located between the patient and the expiratory valve (A2 
	). In the three other configurations, expiratory airflow cannot be measured directly. NIV = noninvasive ventilation. Reproduced with permission from Rabec et al. 
	,5modified from Perrin C, Jullien V, Lemoigne F: Aspects pratiques et techniques de la ventilation non invasive. Rev Mal Respi 2004;21(3):556–66.
Fig. 2. Essential components of noninvasive ventilation (NIV) systems using double (AA, AB  ) and single (BD  , BC  ) circuits. In all systems, the flow generator directs a high rate of gas flow through the inspiratory pathway to a NIV mask equipped with an expiratory valve interposed in the circuit (AA  , AB  ) or exhaust port (BC  , BD  ). When applied to the face, this results in an intentional leak and pressurizes the NIV system. Expiratory airflow is only measurable when the flow meter is located between the patient and the expiratory valve (A2  ). In the three other configurations, expiratory airflow cannot be measured directly. NIV = noninvasive ventilation. Reproduced with permission from Rabec et al.  ,5 modified from Perrin C, Jullien V, Lemoigne F: Aspects pratiques et techniques de la ventilation non invasive. Rev Mal Respi 2004;21(3):556–66.
×
Fig. 3. Representative tracing showing the response to a noninvasive ventilation system with a “minimum guarantee” mode to a perturbation. The inspiratory positive airway pressure increased in order to achieve the minimum guaranteed tidal volume. The onset and offset response times ranged from 1 to 51 breaths. The tidal volume decreased transiently during the onset and increased transiently during the offset. The specific responses to three types of perturbations are shown in the accompanying table. IPAP = inspiratory positive airway pressure; NIV = noninvasive ventilation; VT= tidal volume. Adapted from Fauroux et al.  29 and reprinted with permission.
Fig. 3. Representative tracing showing the response to a noninvasive ventilation system with a “minimum guarantee” mode to a perturbation. The inspiratory positive airway pressure increased in order to achieve the minimum guaranteed tidal volume. The onset and offset response times ranged from 1 to 51 breaths. The tidal volume decreased transiently during the onset and increased transiently during the offset. The specific responses to three types of perturbations are shown in the accompanying table. IPAP = inspiratory positive airway pressure; NIV = noninvasive ventilation; VT= tidal volume. Adapted from Fauroux et al.  29and reprinted with permission.
Fig. 3. Representative tracing showing the response to a noninvasive ventilation system with a “minimum guarantee” mode to a perturbation. The inspiratory positive airway pressure increased in order to achieve the minimum guaranteed tidal volume. The onset and offset response times ranged from 1 to 51 breaths. The tidal volume decreased transiently during the onset and increased transiently during the offset. The specific responses to three types of perturbations are shown in the accompanying table. IPAP = inspiratory positive airway pressure; NIV = noninvasive ventilation; VT= tidal volume. Adapted from Fauroux et al.  29 and reprinted with permission.
×
Fig. 4. Gas pathway in noninvasive ventilation system using a single-limb circuit. During normal use, the flow generator directs air into the breathing tube, which contains an admixture of fresh and exhaled gas. The admixture of fresh and exhaled gas is designed to egress the system via  the exhaust port (intentional leak) and noninvasive ventilation mask interface (unintentional leak).
Fig. 4. Gas pathway in noninvasive ventilation system using a single-limb circuit. During normal use, the flow generator directs air into the breathing tube, which contains an admixture of fresh and exhaled gas. The admixture of fresh and exhaled gas is designed to egress the system via 
	the exhaust port (intentional leak) and noninvasive ventilation mask interface (unintentional leak).
Fig. 4. Gas pathway in noninvasive ventilation system using a single-limb circuit. During normal use, the flow generator directs air into the breathing tube, which contains an admixture of fresh and exhaled gas. The admixture of fresh and exhaled gas is designed to egress the system via  the exhaust port (intentional leak) and noninvasive ventilation mask interface (unintentional leak).
×
Fig. 5. Rebreathing potential in noninvasive ventilation systems. During normal use, elimination of exhaled carbon dioxide depends on a high rate of gas flow. In the conventional continuous positive airway pressure system (A  ), an electrical power-off scenario results in rebreathing of exhaled gas. There is a rapid rise in inspired carbon dioxide and fall in inspired oxygen concentration. Design features that include nonrebreathing valves (B  ) mitigate the risk for rebreathing. NIV = noninvasive ventilation. Reproduced with permission from Farréet al.  30 
Fig. 5. Rebreathing potential in noninvasive ventilation systems. During normal use, elimination of exhaled carbon dioxide depends on a high rate of gas flow. In the conventional continuous positive airway pressure system (A 
	), an electrical power-off scenario results in rebreathing of exhaled gas. There is a rapid rise in inspired carbon dioxide and fall in inspired oxygen concentration. Design features that include nonrebreathing valves (B 
	) mitigate the risk for rebreathing. NIV = noninvasive ventilation. Reproduced with permission from Farréet al.  30
Fig. 5. Rebreathing potential in noninvasive ventilation systems. During normal use, elimination of exhaled carbon dioxide depends on a high rate of gas flow. In the conventional continuous positive airway pressure system (A  ), an electrical power-off scenario results in rebreathing of exhaled gas. There is a rapid rise in inspired carbon dioxide and fall in inspired oxygen concentration. Design features that include nonrebreathing valves (B  ) mitigate the risk for rebreathing. NIV = noninvasive ventilation. Reproduced with permission from Farréet al.  30 
×
Fig. 6. Discharge criteria for patients supported with home continuous positive airway pressure devices.
Fig. 6. Discharge criteria for patients supported with home continuous positive airway pressure devices.
Fig. 6. Discharge criteria for patients supported with home continuous positive airway pressure devices.
×
Fig. 7. Representative figures illustrating the limitations of a noninvasive positive pressure ventilation system in the hospital environment. In both the home (A  ) and hospital (B  ) use scenarios, the set levels of inspiratory positive airway pressure and expiratory positive airway pressure were identical. However, the efficacy of the ventilatory support differed. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 7. Representative figures illustrating the limitations of a noninvasive positive pressure ventilation system in the hospital environment. In both the home (A 
	) and hospital (B 
	) use scenarios, the set levels of inspiratory positive airway pressure and expiratory positive airway pressure were identical. However, the efficacy of the ventilatory support differed. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 7. Representative figures illustrating the limitations of a noninvasive positive pressure ventilation system in the hospital environment. In both the home (A  ) and hospital (B  ) use scenarios, the set levels of inspiratory positive airway pressure and expiratory positive airway pressure were identical. However, the efficacy of the ventilatory support differed. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
×
Fig. 8. Representative figure in a postoperative scenario showing the limitation of the same noninvasive positive pressure ventilation system illustrated in Fig. 7. The set levels of inspiratory positive airway pressure and expiratory positive airway pressure remain unchanged from those in figs. 7A and 7B; however, the level of ventilatory support is much lower. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 8. Representative figure in a postoperative scenario showing the limitation of the same noninvasive positive pressure ventilation system illustrated in Fig. 7. The set levels of inspiratory positive airway pressure and expiratory positive airway pressure remain unchanged from those in figs. 7A and 7B; however, the level of ventilatory support is much lower. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
Fig. 8. Representative figure in a postoperative scenario showing the limitation of the same noninvasive positive pressure ventilation system illustrated in Fig. 7. The set levels of inspiratory positive airway pressure and expiratory positive airway pressure remain unchanged from those in figs. 7A and 7B; however, the level of ventilatory support is much lower. EPAP = expiratory positive airway pressure; IPAP = inspiratory positive airway pressure; NIPPV = noninvasive positive pressure ventilation.
×
Fig. 9. Decision tree for the selection of a medical device to deliver noninvasive positive pressure ventilation in the hospitalized postoperative patient. ISO = Organization for International Standardization; NIPPV = noninvasive positive pressure ventilation; NIV = noninvasive ventilation.
Fig. 9. Decision tree for the selection of a medical device to deliver noninvasive positive pressure ventilation in the hospitalized postoperative patient. ISO = Organization for International Standardization; NIPPV = noninvasive positive pressure ventilation; NIV = noninvasive ventilation.
Fig. 9. Decision tree for the selection of a medical device to deliver noninvasive positive pressure ventilation in the hospitalized postoperative patient. ISO = Organization for International Standardization; NIPPV = noninvasive positive pressure ventilation; NIV = noninvasive ventilation.
×
Table 1. Design Features of Class I and Class II Medical Devices Available for Home Noninvasive Ventilation
Image not available
Table 1. Design Features of Class I and Class II Medical Devices Available for Home Noninvasive Ventilation
×
Table 2. Recommendations for the Perioperative Management of Children Supported with Home Noninvasive Ventilation Therapy
Image not available
Table 2. Recommendations for the Perioperative Management of Children Supported with Home Noninvasive Ventilation Therapy
×