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Cystic fibrosis: Management of advanced lung disease

Cystic fibrosis: Management of advanced lung disease
Author:
Richard H Simon, MD
Section Editor:
George B Mallory, MD
Deputy Editor:
Alison G Hoppin, MD
Literature review current through: Dec 2022. | This topic last updated: Oct 18, 2022.

INTRODUCTION — Cystic fibrosis (CF) is a multisystem disorder caused by pathogenic mutations of the CFTR gene (CF transmembrane conductance regulator). Pulmonary disease remains the leading cause of morbidity and mortality in patients with CF. When CF lung disease becomes severe, additional evaluation and treatment are overlaid onto the standard therapies that are applicable to all patients with CF lung disease. This expanded management approach has been published as a consensus guideline by the CF Foundation [1].

Management of advanced lung disease in CF is discussed below. Other aspects of CF-associated lung disease are discussed in the following topic reviews:

(See "Cystic fibrosis: Clinical manifestations of pulmonary disease".)

(See "Cystic fibrosis: Overview of the treatment of lung disease".)

(See "Cystic fibrosis: Treatment of acute pulmonary exacerbations".)

(See "Cystic fibrosis: Antibiotic therapy for chronic pulmonary infection".)

(See "Cystic fibrosis: Treatment with CFTR modulators".)

The diagnosis and pathophysiology of CF and its manifestations in other organ systems are also discussed separately:

(See "Cystic fibrosis: Clinical manifestations and diagnosis".)

(See "Cystic fibrosis: Genetics and pathogenesis".)

(See "Cystic fibrosis-related diabetes mellitus".)

(See "Cystic fibrosis: Overview of gastrointestinal disease".)

(See "Cystic fibrosis: Assessment and management of pancreatic insufficiency".)

(See "Cystic fibrosis: Nutritional issues".)

(See "Cystic fibrosis: Hepatobiliary disease".)

DEFINITION OF ADVANCED CYSTIC FIBROSIS LUNG DISEASE — It is appropriate to use a relatively broad definition to avoid excluding any patient who might benefit from the treatments that are recommended for severely affected patients. Based on a systematic review of the literature, the CF Foundation guidelines committee defined advanced CF lung disease as [1]:

Forced expiratory volume in one second (FEV1) <40% predicted when stable, or

Referred for lung transplantation evaluation, or

One or more of the following clinical characteristics:

Previous intensive care unit (ICU) admission for respiratory failure

Hypercarbia (arterial partial pressure of carbon dioxide [PaCO2] >50 mmHg or tension of carbon dioxide in peripheral venous blood [PvCO2] >56 mmHg)

Daytime resting oxygen requirement

Pulmonary hypertension (on echocardiogram)

Severe functional impairment from respiratory disease (New York Heart Association class IV)

Six-minute walk test distance <400 m

In addition, it was recognized that some patients who do not meet the above definition have clinical characteristics that predict accelerated deterioration and who might benefit from early application of the expanded treatments. These conditions include frequent pulmonary exacerbations, rapid rate of FEV1 decline, supplemental oxygen for exercise or sleep, worsening malnutrition, infection with difficult-to-manage organisms, CF-related diabetes, pneumothorax, and massive hemoptysis requiring ICU or bronchial artery embolization. Children with moderately severe lung disease should also be considered for early implementation because their rate of deterioration must have been relatively rapid for them to have reached severe lung disease at a young age.

ADVANCED CARE DIRECTIVES — When patients progress to having advanced lung disease, discussions should be held regarding prognosis and care options. Family members and friends should be included, if requested by the patient. The clinician should guide the discussion to include:

Detailed information about lung transplantation

End-of-life options, with recording of the patient's preferences in a living will, depending on state or local laws

Decisions about who will serve as the patient's health care proxy/durable power of attorney

CHRONIC INTERVENTIONS TO SUPPORT HEALTH — As a patient's lung disease progresses, the CF clinician should review the treatment program to ensure that all standard evaluations and therapies are being implemented. For patients with advanced lung disease, the following areas should be given special attention:

Key therapies

CF transmembrane conductance regulator (CFTR) modulators – Therapy with a CFTR modulator therapy is appropriate for most patients with advanced lung disease. Selection of therapy depends on the patient's genotype (algorithm 1). Although patients with advanced lung disease were poorly represented in the early clinical trials of CFTR modulators [2], accumulating evidence supports the use of modulators in these patients. In a prospective study in 245 patients with severe lung disease, treatment with elexacaftor-tezacaftor-ivacaftor for three months was associated with significant improvements in percent predicted forced expiratory volume in one second (FEV1) and body weight and decreased need for supplemental oxygen or referral for lung transplantation [3]. Additional information regarding CFTR modulator therapy in patients with advanced lung disease is available in a separate topic review. (See "Cystic fibrosis: Treatment with CFTR modulators", section on 'Patients with advanced lung disease' and "Cystic fibrosis: Treatment with CFTR modulators", section on 'Pulmonary outcomes'.)

Data regarding the use of CFTR modulators after lung transplantation are limited to small retrospective case series [4]. The decision to prescribe them will need to balance the extrapulmonary benefits with side effects, drug-drug interactions, and cost [5]. (See "Cystic fibrosis: Treatment with CFTR modulators", section on 'Post-transplant'.)

Pulmonary rehabilitation – All patients with CF who have limited functional activity due to pulmonary disease should have a prescribed pulmonary exercise/rehabilitation program. This is particularly important for those with advanced lung disease whose activities of daily living are becoming impaired and in preparation for lung transplantation. (See "Pulmonary rehabilitation".)

Nutritional status – As lung disease progresses, many patients with CF develop nutritional failure. Because of the tight link between pulmonary and nutritional status, treating advanced lung disease requires attention to nutrition. Enteral tube feeding is recommended when oral intake is insufficient to achieve adequate weight. The CF Foundation's enteral feeding guidelines state that low FEV1 is not an absolute contraindication for percutaneous insertion of a feeding tube, but the risk of tube insertion needs to be considered [6]. (See "Cystic fibrosis: Nutritional issues".)

CF-related diabetes – Patients should be rigorously screened for CF-related diabetes, which is common in CF and is associated with worse lung function, poorer nutritional status, and more chest infections. For patients with CF-related diabetes, insulin therapy has beneficial effects on nutrition and probably improves pulmonary function and survival. (See "Cystic fibrosis-related diabetes mellitus".)

Inhaled antibiotics – For patients with chronic Pseudomonas aeruginosa infection and advanced lung disease, many experts recommend continuous alternating inhaled antibiotics. This practice is based primarily on clinical experience and observational evidence. A randomized clinical trial to evaluate the benefits of this approach failed to enroll the targeted number of patients due in part to the widespread adoption of continuous altering antibiotics in clinical practice for patients with frequent pulmonary exacerbations [7]. (See "Cystic fibrosis: Antibiotic therapy for chronic pulmonary infection", section on 'Inhaled antibiotics'.)

Psychosocial support

Adherence – Standard pulmonary treatments prescribed for CF patients are complex and time-consuming. The problem is compounded in patients with advanced lung disease who have difficulties performing their activities of daily living. Consistently obtaining medications and equipment is made more difficult by shifting insurance coverage and prior approval rules, changes in preferred formularies, and the need to use multiple pharmacies [8]. Special efforts need to be made to assist patients in navigating these challenges. (See "Cystic fibrosis: Overview of the treatment of lung disease", section on 'Chronic measures to promote lung health' and "Cystic fibrosis: Antibiotic therapy for chronic pulmonary infection".)

Palliative care – The high symptom burden caused by advanced CF lung disease should be addressed by early inclusion of palliative care approaches by the patient's management team [9,10]. Introduction of palliative care does not preclude continuing aggressive pulmonary care, including intensive care unit (ICU) admission, mechanical ventilation in the event of respiratory failure, or movement toward lung transplantation. Consensus guidelines from the CF Foundation encourage providing palliative care services to patients with CF and provide models for their implementation [10]. (See "Benefits, services, and models of subspecialty palliative care" and "Pediatric palliative care".)

Psychosocial support – Deteriorating pulmonary status generates increasing levels of depression and anxiety, and these may be exacerbated by financial challenges due to threats to employment and medical costs [11]. When the severity of a patient's pulmonary disease becomes advanced, mental health should be assessed more frequently using tools such as PHQ-9 and GAD-7 and by interview during clinic visits. Mental health counseling should be offered early in the course of disease, with addition of psychotherapeutic medications if needed. The CF care team should assess the patient's financial status regularly, including access to adequate food, with referrals to support programs when needed.

LUNG TRANSPLANT EVALUATION — Advancements in the treatment of CF lung disease have slowed the rate of disease progression, but premature death from respiratory failure still occurs in the majority of patients. As in other progressive lung diseases, lung transplantation provides a management option (see "Lung transplantation: An overview"). Of note, the frequency of lung transplantation for CF declined precipitously with the introduction of the highly effective CF transmembrane conductance regulator (CFTR) modulator combination elexacaftor-tezacaftor-ivacaftor [12,13]. (See "Cystic fibrosis: Treatment with CFTR modulators", section on 'Pulmonary outcomes'.)

Virtually all lung transplants for patients with CF require replacing both lungs because leaving a native lung in place would present a huge source of infected secretions that would threaten the transplanted lung. A registry compiled by the International Society for Heart and Lung Transplantation (ISHLT) reports that 1220 lung transplants were performed in children with CF from January 1992 through June 2017 [14] and 9428 lung transplants were performed in adults with CF from January 1992 to June 2017 [15].

Indications for referral to a lung transplant center — In 2019, a consensus committee of the CF Foundation published guidelines that emphasize beginning the process of lung transplant referral well before a patient with advanced lung disease reaches end-stage [16]. Of note, these guidelines were written prior to the widespread use of highly effective CFTR modulator therapy that rapidly improves lung function and slows its subsequent progression (see "Cystic fibrosis: Treatment with CFTR modulators"). However, the recommendation for early referral to a transplant center remains valid because a transplant center may be able to identify and address modifiable factors that could delay or prevent future transplant listing or adversely affect outcome.

The guidelines recommend that the CF care team engage the patient and family in routine periodic discussion of the disease trajectory and treatment options including lung transplantation as a therapeutic option when the patient's forced expiratory volume in one second (FEV1) falls to <50 percent predicted. Meanwhile, modifiable barriers to lung transplantation should be addressed to optimize candidacy, including nutritional status, optimal management of CF-related diabetes, physical deconditioning, adherence to the medical regimen, and any psychosocial or mental health challenges.

The CF Foundation has defined a series of indications for referral to a lung transplant center, as listed in the table (table 1) [16]. Key indications for referral are a FEV1 <50 percent predicted for those with a rapidly declining FEV1 (>20 percent relative decline in the previous year), FEV1 <40 percent predicted with markers of shortened survival, and FEV1 <30 percent predicted for all others. Adolescent patients are generally referred at higher FEV1 values than adults because reaching advanced lung disease at an early age implies more aggressive lung disease with shortened survival compared with adults with the same FEV1 percent predicted.

Patients with FEV1 <40 percent predicted should undergo an annual six-minute walk test, assessment of need for supplemental oxygen, and venous blood gas to screen for markers of severe lung disease that may warrant transplant referral. To screen for pulmonary hypertension, a baseline echocardiogram should be performed for adult patients with FEV1 <40 percent predicted or for younger patients with FEV1 <50 percent predicted.

Patients in North America should be referred to a transplant center that is also an accredited Cystic Fibrosis Foundation Care Center [CFFCC], if possible. These centers provide specialized management for problems associated with CF such as malnutrition, sinus disease, bone disease, CF-related diabetes, and less common infections. In a study of more than 2500 patients, those who underwent transplant at a hospital with a CFFCC had a 33 percent reduction in risk of death or re-transplantation compared with those undergoing transplantation at a hospital without a CFFCC [17]. Most (50 of 68) of the lung transplant centers involved in this study did have an affiliated CFFCC. To guide post-transplant management, the CF Foundation has published a consensus statement containing 32 recommendations covering a broad range of post-transplant topics [18].

Pediatric patients with CF require a somewhat more individualized approach [19]. Importantly, there are few pediatric lung transplant centers, so distance and relocation burdens for families of children and adolescents with CF may be more imposing. Furthermore, there is evidence that outcomes after referral of children and adolescents to adult lung transplant programs have been suboptimal [20]. The reasons are multiple but include the drop in adherence to medication that has been described in adolescents receiving solid organ transplants [18].

Lung allocation and wait list — Since 2005, in the United States, the position of each individual lung transplant candidate on the priority list for transplant is determined by a lung allocation score (LAS) formulated by the United Network for Organ Sharing (UNOS). The score is based on lung diagnosis, age, body mass index (BMI), diabetes, supplemental oxygen use, arterial partial pressure of carbon dioxide (PCO2), six-minute walk distance, pulmonary artery systolic pressure, cardiac index, serum creatinine, bilirubin, functional status, and need for assisted ventilation. Details about the scoring system are available from the Organ Procurement and Transplantation Network (OPTN) [21]. The scoring system is adjusted periodically to incorporate new data that improve the estimate of one-year survival with and without transplantation. This is particularly relevant because equations were formulated using survival data collected prior to the widespread availability of elexacaftor-tezacaftor-ivacaftor, which has been associated with a decrease in mortality [22]. A study from a single center found that integrating a health-related quality-of-life measure might improve the estimation of mortality when computing a transplant priority score [23]. As expected, an analysis of UNOS data found that survival of those transplanted with very high LAS was worse than those with lower scores at the time of transplant [24].

There are wide variations in the length of waiting lists among transplant centers, and individual patients may be served by exploring a number of different lung transplant centers. Noninvasive positive-pressure ventilation (NIPPV), endotracheal intubation, and extracorporeal membrane oxygenation (ECMO) have been used to bridge patients to transplantation [25]. (See 'Respiratory support' below.)

Patients with CF rarely become candidates for lung transplantation prior to 12 years of age. According to the policies for lung distribution overseen by the OPTN, the LAS is not used for this age group. Due to limited availability of age-matched lungs for children, particularly for those below the age of 12, UNOS broadened their policy so that lungs from adolescent donors are preferentially allocated to pediatric recipients. Under the prior policy, organs from adolescent donors had been allocated preferentially to adults or adolescents based on LAS scores. Simulation modeling indicated that the new policy should improve organ availability for children [26].

Contraindications — Each transplant center has its own list of relative and absolute contraindications for lung transplantation. In addition to the general contraindications for lung transplantation applicable for all disease indications, there are several CF-specific considerations. Chronic infection with Burkholderia cenocepacia connotes a worse prognosis following transplantation [27-31]. Most, but not all, transplant centers consider infection with this organism to be a contraindication to the procedure [31,32]. Other species of Burkholderia do not appear to have the same adverse effects, with the possible exception of Burkholderia gladioli [27-30]. Patients infected with multidrug-resistant P. aeruginosa have a minor, if any, survival disadvantage following lung transplant [33,34]. Those infected with Mycobacterium abscessus frequently develop post-transplant complications and should be evaluated by centers with experience managing this infection [35]. Similarly, there is increased risk of dissemination of the fungi Scedosporium apiospermum and Lomentospora prolificans post-transplant and patients with these infections should be assessed at transplant centers experienced with their management [32].

Respiratory colonization with Aspergillus is not a contraindication for transplantation but is associated with a substantially increased risk for post-transplant invasive aspergillosis [36]. As a result, many centers employ antifungal prophylaxis after lung transplantation. (See 'Outcomes' below and "Lung transplantation: General guidelines for recipient selection" and "Lung transplantation: Disease-based choice of procedure".)

Most lung transplant centers in the United States will not accept the referral of intubated patients in acute respiratory failure for lung transplant evaluation. The survival of these patients without transplantation is poor, and prolonged intensive care unit (ICU) stays are associated with progressive deconditioning of affected individuals, another strong contraindication to transplantation in many centers. In addition, their poor clinical status prohibits education and informed consent of the patient, who is expected to adhere to a post-transplant regimen that is complex and can be onerous.

Symptomatic osteoporosis is a relative contraindication for lung transplantation in general, but it takes on special significance for patients with CF. The frequency of osteopenia, osteoporosis, or bone fractures in CF increases with age and affects approximately 20 percent of individuals at age 25 years, increasing to 40 percent at age 55 years [22,37]. Thus, presymptomatic diagnosis and treatment of osteopenia/osteoporosis is important to avoid exclusion of a patient from consideration for transplantation.

A consensus document from the ISHLT addressing transplantation for all causes reported that a BMI <17 kg/m2 is a risk factor for an unfavorable outcome [32]. This was confirmed in a CF population in a retrospective study of 2195 transplant recipients, in which the median survival was lower for those with a BMI <17 kg/m2 compared with those with BMI above this threshold (7.0 versus 8.2 years, respectively) [38]. However, it was noted that the low-BMI cohort still had favorable outcomes compared with all patients transplanted for chronic obstructive pulmonary disease (COPD) or idiopathic pulmonary fibrosis. Therefore, a low BMI alone should not be considered a contraindication for referral to a transplant center [39]. The ISHLT consensus document also noted that a BMI >35 kg/m2 is correlated with worse outcome [32]. This observation is becoming more pertinent to CF as the prevalence of obesity in people with CF will likely increase with the use of highly effective CFTR modulators (see "Cystic fibrosis: Treatment with CFTR modulators"). For children, nutrition status is monitored by BMI Z-scores (or percentiles) because normal values for BMI vary during childhood. (See "Cystic fibrosis: Nutritional issues", section on 'Growth'.)

Outcomes — Among adult patients with CF who underwent lung transplantation between 1992 and 2017, the median (50 percent) survival was 9.9 years [15], which is significantly better than the survival for patients who are transplanted for other disease indications (figure 1) (see "Lung transplantation: An overview"). Reports of survival data from single centers restricting the analysis to more recent experience suggest that survival may be improving [31,40,41]. Analysis using UNOS registry data of the 13,040 patients listed for lung transplant between 2005 and 2011 found a clear survival advantage for the 70 percent who underwent transplantation [42]. Using the same registry, a study reported that median survival of those age >30 years was better than those age 18 to 29 years (9.5 and 5.2 years, respectively) [43]. Post-transplant outcomes for CF lung transplant in Canada are better than in the United States, with part of the difference due to more United States patients dying while on the waiting list and better post-transplant survival in Canada [44]. Pediatric patients receiving lung transplants for CF between 1992 and 2017 had a 50 percent survival of 5.6 years, which is similar to the 5.4-year median survival for pediatric patients who were transplanted for other indications [14]. Data from two single-center reports provide a mixed picture of how much of the decreased pediatric survival was attributable to children under age 12 years; adolescents had survival rates similar to adults [31,45]. Outcomes following re-transplantation are significantly worse, with a five-year median survival of 48 percent compared with 59 percent for those undergoing their first transplant [46].

Limitations of transplantation — Many problems remain after lung transplantation for CF. The procedure does not address the nonpulmonary problems associated with CF. Chronic sinusitis, cirrhosis, cholelithiasis, pancreatic insufficiency, CF-associated diabetes mellitus, osteoporosis, and distal intestinal obstruction syndrome remain causes of morbidity and occasionally of mortality. Pancreatic insufficiency and abnormalities in bowel motility can make cyclosporine absorption and dosing difficult; tacrolimus itself is diabetogenic. Glucocorticoid treatment to suppress graft rejection complicates diabetic management and accelerates osteoporosis. Studies examining quality of life after lung transplantation for CF generally show improvement [47-49]. Most children return to school, and many adults return to work.

RESPIRATORY SUPPORT

Supplemental oxygen — For CF patients with intermittent or chronic hypoxemia, we suggest supplemental oxygen, consistent with guidelines from the CF Foundation and American Thoracic Society [1,50]. This approach is extrapolated from the management of patients with chronic obstructive pulmonary disease (COPD), in whom supplemental oxygen delays or ameliorates the complications of chronic hypoxemia [51]. In the absence of studies examining oxygen use in patients with CF, we follow the same recommendations for use as in patients with COPD. (See "Long-term supplemental oxygen therapy".)

Short-term outcomes of supplemental oxygen therapy during exercise and sleep were evaluated in a systematic review of 10 small randomized controlled trials of patients with CF [52]. Supplemental oxygen modestly enhanced exercise duration and capacity, improved attendance at school or work, and caused mild hypercapnia that is probably clinically insignificant. Use of nocturnal oxygen improved time to fall asleep but did not improve qualitative sleep parameters. Only one of the studies in the systematic review examined long-term oxygen therapy [53]. No statistically significant improvement in survival, lung function, or cardiac health was detected. In addition, improvement of oxygenation was accompanied by modest hypercapnia that was probably clinically inconsequential.

Nocturnal noninvasive positive-pressure ventilation — We generally offer nocturnal noninvasive bilevel positive airway pressure (BPAP) ventilation to patients whose arterial carbon dioxide level remains elevated (eg, ≥55 mmHg, or ≥50 mmHg with nocturnal desaturation) despite maximizing other treatments. (See "Nocturnal ventilatory support in COPD".)

This approach is supported by a systematic review in which noninvasive positive-pressure ventilation (NIPPV) for patients with advanced CF lung disease and hypercapnia improved gas exchange during sleep [54]. One of the included trials involved eight adults with daytime hypercapnia and compared nocturnal use of BPAP to supplemental oxygen or placebo (air) [55]. Six weeks of BPAP improved self-reported chest symptoms, exertional dyspnea and exercise capacity, nocturnal hypoventilation, and peak exercise capacity, without measurable improvement in lung function, and was tolerated by 90 percent of patients. In another study, 29 patients with nocturnal oxygen desaturations who were randomized to noninvasive ventilation had improved event-free survival at 3 and 12 months compared to those receiving supplemental oxygen alone. Events were defined as an arterial partial pressure of carbon dioxide (PaCO2) >60 mmHg or a partial pressure of carbon dioxide (PCO2) increase of >10 mmHg measured by arterial blood gas or by transcutaneous CO2 monitor [56]. Several case series also reported successful long-term use of NIPPV as a bridge to transplant; the intervention was associated with improved hypercarbia, weight gain, and/or improvement in the trajectory for forced expiratory volume in one second (FEV1) [57-60]. A small crossover trial in adults with advanced CF lung disease reported that NIPPV and high-flow oxygen therapy resulted in similar oxygenation and work of breathing [61].

Intensive care unit treatment — The prognosis following an episode of mechanical ventilation due to acute respiratory failure in advanced CF lung disease has been improving, with 36 to 56 percent surviving until hospital discharge [1,62,63]. Outcomes for children and adolescents who are admitted to intensive care may be somewhat better than for adults. In a large study from a registry of pediatric intensive care units (ICUs; primarily in North America), mortality during the ICU admission was 6.9 percent overall and 19.1 percent for patients who were intubated [64]. However, it is unclear what proportion of this cohort was admitted to the ICU with respiratory failure. Thus, advanced CF lung disease is not a contraindication to ICU care and mechanical ventilation, regardless of the patient's lung transplant status [1]. Interventions may include:

Noninvasive respiratory support – Heated high-flow oxygen or NIPPV.

Endotracheal intubation – Endotracheal intubation with mechanical ventilation is not contraindicated in advanced CF lung disease. It is particularly beneficial when the acute decompensation is caused by pneumothorax or hemoptysis but should be considered for all causes of respiratory failure. If endotracheal intubation is required for more than five to seven days, early tracheostomy should be considered to promote physical mobilization to avoid deconditioning and reduce the need for sedation [1]. (See "Cystic fibrosis: Treatment of acute pulmonary exacerbations", section on 'Respiratory support'.)

Extracorporeal membrane oxygenation support (ECMO) – Venovenous ECMO is sometimes employed as a bridge to lung transplant in CF patients who are approved for transplantation [1,65,66]. In addition, in highly selected patients, ECMO may be considered as a bridge to recovery, based on anecdotal reports as outlined in the CF Foundation guideline [1]. (See "Extracorporeal membrane oxygenation (ECMO) in adults".)

Decisions about ICU admission and each of the above interventions must be individualized, depending on the patient's prognosis for recovery or lung transplantation and on their desires and preferences, as expressed in advanced care directives. (See 'Advanced care directives' above.)

In the past, outcomes for CF patients requiring treatment in an ICU were uniformly poor [67] but have since fortunately improved [68]. There are probably multiple reasons for the improved outcomes, including the use of noninvasive ventilation to sustain the patient until other measures to reverse the respiratory failure take effect [69,70]. In modern series, survival was dependent upon the severity of respiratory failure, with the best outcomes for those who could be managed by noninvasive ventilation and the worst for those requiring endotracheal intubation/ventilation [62,63,70-73]. Patients requiring ICU treatment admission for pneumothorax or hemoptysis had a better prognosis as compared with CF patients admitted to the ICU for other indications [73,74]. (See "Cystic fibrosis: Overview of the treatment of lung disease", section on 'Spontaneous pneumothorax' and "Cystic fibrosis: Overview of the treatment of lung disease", section on 'Hemoptysis'.)

SOCIETY GUIDELINE LINKS — Links to society and government-sponsored guidelines from selected countries and regions around the world are provided separately. (See "Society guideline links: Cystic fibrosis".)

INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.

Here are the patient education articles that are relevant to this topic. We encourage you to print or e-mail these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)

Basics topics (see "Patient education: Cystic fibrosis (The Basics)" and "Patient education: Bronchiectasis in children (The Basics)")

SUMMARY AND RECOMMENDATIONS

Definition – Cystic fibrosis (CF)-related lung disease is considered advanced if the forced expiratory volume in one second (FEV1) is <40 percent predicted or the patient is referred for lung transplantation evaluation, or if the patient has one of several clinical characteristics that are associated with worse pulmonary status, such as chronic hypercarbia. (See 'Definition of advanced cystic fibrosis lung disease' above.)

Key interventions for all patients – When CF-related lung disease progresses to an advanced stage, special attention should be given to optimizing key therapies:

CF transmembrane conductance regulator (CFTR) modulators – Therapy with a CFTR modulator therapy is appropriate for most patients with advanced lung disease, as for other patients with CF. Recommendations for CFTR therapy are summarized in the algorithm (algorithm 1) and discussed separately. (See 'Key therapies' above and "Cystic fibrosis: Treatment with CFTR modulators", section on 'Patients with advanced lung disease'.)

Other key therapies – Other key therapies that should be optimized for this group of patients are pulmonary rehabilitation, nutritional support, screening and management of CF-related diabetes, and continuous alternating inhaled antibiotics (for those with Pseudomonas aeruginosa infection). (See 'Key therapies' above.)

Psychosocial support – The patient's care program should place increased emphasis on maintaining mental health. Levels of anxiety and depression should be measured and treated with counseling and medication, when needed. Discussion of advanced care directives and palliative care strategies should be introduced early and do not preclude aggressive pulmonary care and consideration for lung transplantation. (See 'Advanced care directives' above and 'Psychosocial support' above.)

Additional interventions for selected patients – Decisions about advanced care must be individualized, depending on the patient's desires and preferences as expressed in advanced care directives, as well as their prognosis for recovery or lung transplantation. Strategies may include:

Lung transplantation – Severe CF lung disease is a common indication for lung transplantation, and outcomes are better than those of patients undergoing lung transplantation for other indications. Guidelines emphasize beginning the process of lung transplant referral well before a patient with advanced lung disease reaches end-stage and suggest clinical indications for referral, as outlined in the table (table 1). Chronic infection with Burkholderia cenocepacia connotes a worse prognosis following transplantation and is often considered a contraindication to the procedure. (See 'Lung transplant evaluation' above.)

Palliative care – As symptom burden increases and quality of life deteriorates, palliative care strategies should be introduced without precluding continuation of other therapies or eligibility for lung transplantation.

Supplemental oxygen – For patients with chronic hypoxemia due to advanced CF lung disease, we suggest supplemental oxygen therapy (Grade 2C), using the same indications as for patients with chronic obstructive pulmonary disease (COPD). Supplemental oxygen may improve exercise capacity and attendance at school or work and causes mild hypercapnia that is probably clinically insignificant. The possibility of long-term benefits is extrapolated from studies in patients with COPD and has not been demonstrated in patients with CF. (See 'Supplemental oxygen' above.)

Nocturnal noninvasive positive-pressure ventilation (NIPPV) – For patients with persistent hypercarbia (arterial carbon dioxide level ≥55 mmHg, or ≥50 mmHg with nocturnal desaturation) despite maximizing other treatments, we suggest nocturnal NIPPV (Grade 2B). NIPPV is tolerated by most patients and improves self-reported chest symptoms, exertional dyspnea and exercise capacity, nocturnal hypoventilation, and peak exercise capacity. (See 'Nocturnal noninvasive positive-pressure ventilation' above.)

Intensive care – Improved outcomes support use of intensive care unit (ICU) care for CF patients with respiratory failure. Interventions may include heated high-flow oxygen and NIPPV. Similarly, having advanced CF should not preclude endotracheal intubation with mechanical ventilation, tracheostomy, and extracorporeal membrane oxygenation (ECMO) for select patients. (See 'Intensive care unit treatment' above.)

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