The Patient Experience During Noninvasive Respiratory Support

Interface

NIV is applied to the patient via some sort of mask or interface. There are many different types of interfaces available (Fig. 2). It is important to note that interface terminology may be used interchangeably. For example, the mask type that covers the mouth and nose is typically referred to as an oronasal mask, whereas others use the term full face mask or face mask to describe a mask that covers only the mouth and nose (Fig. 2C).^2,17,18 Some authors use the term total face mask to describe a mask that covers the patient's face from above the eyebrows to the chin (Fig. 2F),^19,20 while others use the term full face mask.^19–21

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Fig. 2.

Interfaces for noninvasive ventilation. A: Nasal mask, B: nasal pillows, C: oronasal mask, D: hybrid mask, E: oral mask, F: total face mask, and G: helmet. From Reference 3.

Eliminating leaks associated with the interface is a priority for improving tolerance by eliminating asynchrony. The source of leaks depends on the type of interface utilized. When using a nasal mask (Fig. 2A), the patient's mouth may fall open, particularly during sleep. Regardless of the interface used, a leak could develop at the point where the mask meets the face. Ill-fitting masks, improperly sized masks, and improperly applied masks may result in a gap between the mask and the face, allowing gas to escape. This can result in a large enough leak to affect patient–ventilator synchrony and patient comfort level with the device, which may in turn affect adherence.²⁰

Some researchers have identified that nasal masks produce more leaks than oronasal masks and full or total face masks,^2,20 especially when much higher inspiratory pressures than those traditionally noted with pressure support ventilation (PSV) are used.¹⁸ When this high-intensity NIV is applied with a nasal mask, more pressure is exerted on the patient's cheeks, which provides more opportunity for air leaks. Full or total face masks allow the pressure to be applied over a greater surface area, reducing the amount of pressure in any one area of the mask and decreasing the likelihood of leaks.¹⁸

Clinicians can eliminate air leaks primarily by ensuring the mask is the appropriate size and type for the patient's facial structure. The type of mask may also depend on the NIV settings. As previously mentioned, high-intensity NIV may require oronasal or full face masks due to the higher inspiratory pressure settings.¹⁸ The clinician should also ensure that the straps or securing devices are properly applied and fastened. However, adjusting the straps too tightly will exert excessive pressure on the facial tissues and may result in tissue ischemia and pressure ulcers.^17,22–25 To resolve a mouth leak during nasal mask usage, the clinician can employ a chin strap to close the mouth, although this is not always an effective practice.^16,20 It is important to note that eliminating the leaks completely is an unrealistic expectation. The clinician should strive to select an interface that is appropriate for the patient, fits the patient's facial structure, and can be secured without exerting excessive pressure and risking skin integrity. Modern NIV ventilators employ a leak algorithm to compensate for small leaks within the system.²

The most common interfaces used in the United States are the nasal mask and the oronasal mask (Figs. 2A and 2C). However, many studies have demonstrated that these particular interfaces are less comfortable than a total face mask (Fig. 2F), especially in the presence of leaks.^19,21,26 Popular in Europe is the use of the helmet, which is a hood that fits over the patient's head and is secured at the patient's collar (Fig. 2G).² The placement of the helmet avoids most issues noted with the nasal, oronasal, and total face masks, and while patients report comfort with this device, they also report that this interface is loud due to the high gas flow required. Although the potential for CO₂ rebreathing with most CPAP/NIV interfaces is minimal,² the clinician should be aware of the increased likelihood of this phenomenon with the helmet as well as the increased likelihood of less synchrony compared to other interfaces.^27,28

An HFNC system produces a leak in the presence of high flows or when the patient's mouth is open.²⁹ However, researchers report that leaks with the HFNC are not a significant concern.³⁰ Further research focused on the likelihood and degree of system leaks and its impact is warranted.

Modes

Patient-ventilator asynchrony may be caused by excessive system leaks, ineffective triggering, double-triggering, auto-triggering, premature cycling, delayed cycling, and patient agitation.^2,3,31 Visual assessment of the patient and assessment of ventilator waveforms are methods to identify patient–ventilator asynchrony, although observation of ventilator waveforms alone is not sufficient.³¹ The first step to ensuring effective patient–ventilator synchrony is to assure proper interface fit and application. Minimizing leaks at the interface level may eliminate the issues related to triggering and cycling. Other solutions include ensuring trigger sensitivity is set appropriately for the patient and the disease process, and considering an increased level of PEEP. If those solutions are exhausted to no avail, the clinician can consider changing modes.⁷

Sedation

Most patients receiving invasive mechanical ventilation will also require some level of sedation to maintain comfort and synchrony. In contrast, sedation is not necessary for the successful application of NIV, although some suggest that using sedation during NIV could improve asynchrony and comfort, leading to overall NIV success. Ni et al⁴² performed a retrospective review of 80 adult subjects receiving NIV after extubation who experienced interface intolerance. Forty-one of the 80 studied subjects used some sort of sedation (propofol or dexmedetomidine), analgesia (fentanyl or sufentanil), or both. The researchers identified that those subjects had decreased ICU stay, decreased mortality, and improved NIV success compared to those who did not receive sedation or analgesia. It is worth noting that the researchers excluded patients ≥65 y old and those with a host of comorbidities, including moderate to severe COPD, elevated APACHE II scores, body mass index >30 kg/m², prolonged mechanical ventilation, inability to clear secretions, and >2 comorbidities, among others. Therefore, the sample is likely not representative of the general population of critically ill patients.

Muriel et al⁴³ completed a prospective observational study to identify what association, if any, exists between the use of analgesia (morphine, fentanyl, remifentanil, sufentanil) or sedation (midazolam, propofol, lorazepam, or dexmedetomidine) and NIV failure, defined as the need for invasive mechanical ventilation after NIV was attempted. Of those included, 51% received analgesia or sedation during NIV. In contrast to the results from the study by Ni et al,⁴² the researchers found that ICU stay was longer in those who received sedation with or without the added analgesia. Subjects who received analgesia only had an ICU stay similar to those subjects who had neither sedation nor analgesia. In addition, 28-d mortality was higher in subjects who received sedation or analgesia compared to subjects who received neither. Although the study did not show an association between the use of sedation or analgesia and NIV failure, it did demonstrate a potentially deleterious effect of the combined use of sedatives and analgesics on NIV success.

Devlin et al⁴⁴ studied the effect of routine early use of dexmedetomidine on NIV success in subjects with acute respiratory failure. In a prospective, randomized, double-blind, placebo-controlled study, participants diagnosed with acute respiratory failure receiving NIV were randomized to receive dexmedetomidine or placebo. The study identified that there was no statistically significant difference between the group that received sedation and the placebo group with regards to NIV tolerance, NIV failure, mortality, or ICU stay.

Others have stated that sedation should not be initiated for patients receiving NIV until all other avenues to improve comfort and tolerance have been exhausted. The potential adverse effects of sedation, including tolerance, sensitivities, respiratory depression, and addiction, should not be minimized and, if sedation is identified as a necessary therapeutic intervention for the patient receiving NIV, the minimum dose should be administered to avoid oversedation.^7,45

Humidification

Traditionally, humidification has not been applied during acute care CPAP or NIV. However, patients may experience nasal congestion, dry nasal mucosa, dry mouth, and dry throat.^3,34,46 Interestingly, research has demonstrated that these symptoms do not differ with settings of flow and pressure.⁴⁶ Adding humidification to the CPAP or NIV system may alleviate these symptoms.

Humidification can be added via a passive system, such as a heat-moisture exchanger (HME), or via heated humidification. Research indicates that there is no difference in NIV duration, ICU stay, hospital stay, ICU mortality, or intubation rates between the use of an HME and heated humidification.^2,47 However, use of an HME can add to the circuit dead space, increasing the patient's work of breathing, and the effectiveness of an HME is compromised in the presence of a leak.^16,20,34 Although the use of an HME is not generally recommended,¹³ benefits of using heated humidification include decreased nasal resistance, improved comfort, no additional circuit dead space, and improved adherence.^3,16,20,34 It is important to note that the choice of humidification device will depend on the type of circuit used for CPAP or NIV and the available equipment.

When utilizing a helmet interface, the clinician should be cautious about adding heated humidification. Nava et al²⁰ caution that the application of heated humidification could increase condensation inside the helmet, decreasing the visibility of and for the patient. Ueta et al²⁷ studied the response of 28 healthy volunteers wearing the helmet interface for the delivery of CPAP via mechanical ventilator in 3 situations: no humidification at ambient temperature, humidification at ambient temperature, and heated humidification. They observed that heated humidification resulted in excessive condensation on the inside of the helmet, and subjects reported feeling feverish. They concluded that the optimal humidity and comfort setting was to provide humidification at room temperature. Chiumello et al⁴⁸ also studied humidity via helmet during CPAP, both via mechanical ventilator and via continuous-flow CPAP at 2 different flow levels. They found that comfort did not differ among the 3 settings, and they noted that additional humidity is not likely to be necessary when using the mechanical ventilator to deliver CPAP, but it was required to maintain absolute humidity with continuous-flow CPAP.

HFNC utilizes oxygen flows above that of the patient's inspiratory demand with heated humidification.³⁰ Typical heated humidification settings include 100% humidity at 37°C,⁴⁹ although ambient temperature and breathing pattern may alter the delivered humidity.³⁰ Mauri et al⁵⁰ studied the relationship between HFNC temperature and patient comfort, reporting that patients may be more comfortable at a lower temperature. It is reasonable for the clinician to adjust the temperature of the device to ensure absolute humidity and patient comfort is achieved.

Skin Integrity

The application of an interface to deliver NIV may cause skin breakdown. The amount of pressure used to secure the device can cause decreased blood flow to the area and, ultimately, tissue necrosis. Damage to the patient's skin can occur within 2 h of the initial ischemia. In the presence of hypoxemia, hypotension, various medications, and increased duration of pressure, the pressure ulcers can become more severe. The most common place for pressure ulcers caused by the application of NIV is the bridge of the nose.^20,22 Pressure exerted on the bridge of the nose differs by mask type.²⁵

Yamaguti et al²⁴ studied the frequency of pressure ulcers as a result of NIV or CPAP in adult subjects with acute respiratory failure. In this study, 14.4% of the participants developed a stage I or stage II pressure ulcer. The researchers identified that participants who developed pressure ulcers were more likely to have utilized an oronasal mask versus a total face mask.

Schallom et al²² compared oronasal masks and full-face masks in subjects receiving NIV. Skin integrity was assessed daily for the duration of the NIV application. Of the subjects utilizing an oronasal mask in the study, 20% developed a pressure ulcer, whereas 1% of those utilizing a full-face mask developed a pressure ulcer. The researchers identified that pressure ulcer development occurred as early as 1.25 h after placement of the oronasal mask and the most common site for ulcer development was on the nasal bridge.

Although most concerns regarding facial skin integrity are related to pressure ulcers, some researchers have considered the role of added humidification to loss of skin integrity. Alqahtani et al⁵¹ studied the effect of humidified NIV via oronasal mask versus non-humidified NIV via oronasal mask in healthy subjects. They found that, although humidification eliminated subject-reported discomfort from nasal dryness, the added moisture increased local humidity at the skin surface within the mask, producing higher levels of transepidermal water loss. Visscher et al²³ discovered an association of erythema with higher skin hydration and recommend strategies to normalize skin hydration to avoid the development of skin breakdown.

The dilemma is to eliminate leaks without using a device that creates undue pressure on the surrounding skin, thus avoiding skin breakdown and pressure ulcers. Skin breakdown has been infrequently reported in trials of HFNC.^52,53 It is logical, then, to suggest that, for patients who have developed pressure ulcers due to NIV or are at increased risk of developing pressure ulcers, and if therapeutic goals can be met with HFNC, a trial of HFNC only or a trial of sequential NIV/HFNC could be a viable solution.

Nutrition

Typically, critically ill patients are intubated, making them unable to ingest foods. Their energy requirements have changed, and the body now has to spend energy healing and likely fighting infections. Because the patient is not consuming food in a traditional fashion, the gastrointestinal tract motility changes and may not process nutritional substances properly. In addition, work of breathing, acid/base status, and electrolyte balance can change nutritional requirements necessary to avoid malnutrition.

Oral feeding during NIV has not been sufficiently addressed. Whether via naso/orogastric tube or through traditional intake, feeding during NIV is controversial. For patients who are able to consume an oral diet, there are two options for eating. One option involves removing the interface during eating, which carries the risk of deterioration of the respiratory status based on the level of dependence upon the interface. A second option includes the use of a nasal mask and eating while the device is on. This puts the patient at risk for aspiration due to the gas flow during eating. If the patient is unable to consume foods orally, a nasogastric or orogastric tube can be placed for enteral feeds. While this facilitates enteral nutrition, the tube itself establishes a leak between the skin and the interface, establishes a new pressure point on the skin, and includes a risk of aspiration.

Literature is minimal on this topic. Terzi et al⁵⁴ studied the effect of nutrition administered to subjects receiving NIV. This observational retrospective cohort study included nutrition administered orally, enterally, and parenterally as compared to no nutrition provided. The researchers identified that subjects receiving enteral nutrition had increased mortality, increased incidence of infection, increased number of ventilator days, and fewer ventilator-free days than subjects who received no nutrition.

Kogo et al⁵⁵ studied enteral feedings via nasogastric tube for subjects receiving enteral nutrition while on NIV. Notable is that the enteral feeding group had an increased incidence of mucus plug, aspiration pneumonia, and airway complications in addition to increased NIV days, increased ICU days, and increased hospital days over the group that received no nutrition, though mortality was not different between the groups.

Some researchers advocate adapting respiratory support devices, such as substituting HFNC for NIV, to allow for safer oral feeding in the ICU.⁵⁶ This strategy may alleviate concerns about lung de-recruitment or deflation injury that may occur when the NIV device is removed and the positive expiratory pressure is no longer exerted on the airway. Ultimately, proper nutrition is required in the acutely ill patient, and the clinician's role in facilitating safe nutritional support cannot be overstated.

Comfort

The application of CPAP and NIV are essentially the same: the intervention utilizes a patient interface (ie, a mask) for the application of positive airway pressures. It is logical to assume that HFNC, with its application of a nasal cannula instead of an occlusive mask, is a more comfortable device and inspires higher patient tolerance. A 2017 Cochrane Review⁵⁷ incorporated studies comparing patient comfort with HFNC versus conventional oxygen therapy. The researchers' analysis of the available literature showed no difference in comfort between HFNC and conventional oxygen therapy.

Lee et al¹ also reviewed subject comfort with HFNC. In addition to comparing HFNC to conventional oxygen therapy, HFNC comfort was also compared to that experienced with NIV. The systematic review included 9 studies set either in the emergency department or the ICU. The studies used a variety of flows for HFNC, ranging from 20 L/min and 60 L/min and titrated per institutional protocol for individual comfort and disease. Exposure to HFNC ranged between 15 min and 60 min before outcomes were measured. Of the included studies, 7 of 9 identified that subjects favored HFNC over NIV. Comfort in these studies was measured using a visual analog scale. This measurement method relies on the patient's perception of pain. Considering the settings of the studies, it is logical to assume that the subjects were experiencing some level of pain prior to initiation of HFNC, conventional oxygen therapy, or NIV. Therefore, alleviation of pain could be perceived as comfort when the patient is simply experiencing less pain. While this may seem like semantics, this has implications for potential discharge to home with one of the interventions. What appeared to be comfort in the ICU may not be comfortable in the home environment after the patient has been returned to prior quality of life, which may impact adherence with the intervention in the home.

A meta-analysis performed by Huang et al⁵⁸ indicated that HFNC produced less discomfort due to less mucosal dryness and fewer interface complications than NIV, although others have noted that increased HFNC flows can lead to increased noise levels.^9,12,30 However, to my knowledge, there is no literature reporting comfort of HFNC in the home; this may be a factor in identifying the most appropriate intervention if long-term use is anticipated. Okuda et al⁵⁹ reported that a patient with dementia was weaned from NIV to HFNC and discharged to home with the device. Patients diagnosed with dementia experiencing agitation may be able to tolerate HFNC better than NIV. For patients who are not mobile or who only need the device during sleep, this may be an option for the home. For those who are mobile and require noninvasive respiratory support on a continual basis, portability of the device and its components is a major factor to maximize patient quality of life.

Sequential NIV and HFNC

As previously mentioned, there may be an argument for the use of sequential NIV-HFNC to facilitate weaning from NIV and oral nutrition, and to provide temporary relief from the pressures exerted by the NIV interface. Frat et al⁵³ studied 28 subjects with acute respiratory failure who received application of HFNC for 2-h intervals followed by a 1-h interval of NIV, for a total of 16 h of HFNC and 8 h of NIV in 1 d. The researchers discovered a statistically significant improvement in comfort with HFNC over NIV. Interestingly, none of the subjects developed facial skin breakdown or required sedation or analgesia during the trial, lending credence to the concept of sequential NIV-HFNC for this patient population, though more research is needed.