Surfactant Protein B Deficiency Research Articles

A promoterless AAV6.2FF-based lung gene editing platform for the correction of surfactant protein B deficiency

Surfactant protein B (SP-B) deficiency is a rare genetic disease that causes fatal respiratory failure within the first year of life. Currently, the only corrective treatment is lung transplantation. Here, we co-transduced the murine lung with adeno-associated virus 6.2FF (AAV6.2FF) vectors encoding a SaCas9-guide RNA nuclease or donor template to mediate insertion of promoterless reporter genes or the (murine) Sftpb gene in frame with the endogenous surfactant protein C (SP-C) gene, without disrupting SP-C expression. Intranasal administration of 3×1011 vg donor template and 1×1011 vg nuclease consistently edited approximately 6% of lung epithelial cells. Frequency of gene insertion increased in a dose-dependent manner, reaching 20%-25% editing efficiency with the highest donor template and nuclease doses tested. We next evaluated whether this promoterless gene editing platform could extend survival in the conditional SP-B knockout mouse model. Administration of 1×1012 vg SP-B-donor template and 5×1011 vg nuclease significantly extended median survival (p= 0.0034) from 5days in the untreated off doxycycline group to 16days in the donor AAV and nuclease group, with one gene-edited mouse living 243days off doxycycline. This AAV6.2FF-based gene editing platform has the potential to correct SP-B deficiency, as well as other disorders of alveolar type II cells.

A human surfactant B deficiency air-liquid interface cell culture model suitable for gene therapy applications

Surfactant protein B (SPB) deficiency is a severe monogenic interstitial lung disorder that leads to loss of life in infants as a result of alveolar collapse and respiratory distress syndrome. The development and assessment of curative therapies for the deficiency are limited by the general lack of well-characterized and physiologically relevant in vitro models of human lung parenchyma. Here, we describe a new human surfactant air-liquid interface (SALI) culture model based on H441 cells, which successfully recapitulates the key characteristics of human alveolar cells in primary culture as evidenced by RNA and protein expression of alveolar cell markers. SALI cultures were able to develop stratified cellular layers with functional barrier properties that are stable for at least 28 days after air-lift. A SFTPB knockout model of SPB deficiency was generated via gene editing of SALI cultures. The SFTPB-edited SALI cultures lost expression of SPB completely and showed weaker functional barrier properties. We were able to correct this phenotype via delivery of a lentiviral vector pseudotyped with Sendai virus glycoproteins F/HN expressing SPB. We believe that SALI cultures can serve as an important in vitro research tool to study human alveolar epithelium, especially for the development of advanced therapy medicinal products targeting monogenic disorders.

Surfactant Protein B Deficiency Induced High Surface Tension: Relationship between Alveolar Micromechanics, Alveolar Fluid Properties and Alveolar Epithelial Cell Injury

High surface tension at the alveolar air-liquid interface is a typical feature of acute and chronic lung injury. However, the manner in which high surface tension contributes to lung injury is not well understood. This study investigated the relationship between abnormal alveolar micromechanics, alveolar epithelial injury, intra-alveolar fluid properties and remodeling in the conditional surfactant protein B (SP-B) knockout mouse model. Measurements of pulmonary mechanics, broncho-alveolar lavage fluid (BAL), and design-based stereology were performed as a function of time of SP-B deficiency. After one day of SP-B deficiency the volume of alveolar fluid V(alvfluid,par) as well as BAL protein and albumin levels were normal while the surface area of injured alveolar epithelium S(AEinjure,sep) was significantly increased. Alveoli and alveolar surface area could be recruited by increasing the air inflation pressure. Quasi-static pressure-volume loops were characterized by an increased hysteresis while the inspiratory capacity was reduced. After 3 days, an increase in V(alvfluid,par) as well as BAL protein and albumin levels were linked with a failure of both alveolar recruitment and airway pressure-dependent redistribution of alveolar fluid. Over time, V(alvfluid,par) increased exponentially with S(AEinjure,sep). In conclusion, high surface tension induces alveolar epithelial injury prior to edema formation. After passing a threshold, epithelial injury results in vascular leakage and exponential accumulation of alveolar fluid critically hampering alveolar recruitability.

Featured Article: Electroporation-mediated gene delivery of surfactant protein B (SP-B) restores expression and improves survival in mouse model of SP-B deficiency.

Surfactant Protein B Deficiency is a rare but lethal monogenetic, congenital lung disease of the neonate that is unresponsive to any treatment except lung transplantation. Based on the potential that gene therapy offers to treat such intractable diseases, our objective was to test whether an electroporation-based gene delivery approach could restore surfactant protein B expression and improve survival in a compound knockout mouse model of surfactant protein B deficiency. Surfactant protein B expression can be shut off in these mice upon withdrawl of doxycycline, resulting in decreased levels of surfactant protein B within four days and death due to lung dysfunction within four to seven days. Control or one of several different human surfactant protein B-expressing plasmids was delivered to the lung by aspiration and electroporation at the time of doxycycline removal or four days later. Plasmids expressing human surfactant protein B from either the UbC or CMV promoter expressed surfactant protein B in these transgenic mice at times when endogenous surfactant protein B expression was silenced. Mean survival was increased 2- to 5-fold following treatment with the UbC or CMV promoter-driven plasmids, respectively. Histology of all surfactant protein B treated groups exhibited fewer neutrophils and less alveolar wall thickening compared to the control groups, and electron microscopy revealed that gene transfer of surfactant protein B resulted in lamellar bodies that were similar in the presence of electron-dense, concentric material to those in surfactant protein B-expressing mice. Taken together, our results show that electroporation-mediated gene delivery of surfactant protein B-expressing plasmids improves survival, lung function, and lung histology in a mouse model of surfactant protein B deficiency and suggest that this may be a useful approach for the treatment of this otherwise deadly disease. Impact statement Surfactant protein B (SP-B) deficiency is a rare but lethal genetic disease of neonates that results in severe respiratory distress with no available treatments other than lung transplantation. The present study describes a novel treatment for this disease by transferring the SP-B gene to the lungs using electric fields in a mouse model. The procedure is safe and results in enough expression of exogenous SP-B to improve lung histology, lamellar body structure, and survival. If extended to humans, this approach could be used to bridge the time between diagnosis and lung transplantation and could greatly increase the likelihood of affected neonates surviving to transplantation and beyond.

Outcomes of Lung Transplantation for Infants and Children with Genetic Disorders of Surfactant Metabolism

To compare outcomes of infants and children who underwent lung transplantation for genetic disorders of surfactant metabolism (SFTPB, SFTPC, ABCA3, and NKX2-1) over 2 epochs (1993-2003 and 2004-2015) at St Louis Children's Hospital. We retrospectively reviewed clinical characteristics, mortality, and short- and long-term morbidities of infants (transplanted at <1 year; n = 28) and children (transplanted >1 year; n = 16) and compared outcomes by age at transplantation (infants vs children) and by epoch of transplantation. Infants underwent transplantation more frequently for surfactant protein-B deficiency, whereas children underwent transplantation more frequently for SFTPC mutations. Both infants and children underwent transplantation for ABCA3 deficiency. Compared with children, infants experienced shorter times from listing to transplantation (P = .014), were more likely to be mechanically ventilated at the time of transplantation (P < .0001), were less likely to develop bronchiolitis obliterans post-transplantation (P = .021), and were more likely to have speech and motor delays (P ≤ .0001). Despite advances in genetic diagnosis, immunosuppressive therapies, and supportive respiratory and nutritional therapies, mortality did not differ between infants and children (P = .076) or between epochs. Kaplan-Meier analyses demonstrated that children transplanted in epoch 1 (1993-2003) were more likely to develop systemic hypertension (P = .049) and less likely to develop post-transplantation lymphoproliferative disorder compared with children transplanted in epoch 2 (2004-2015) (P = .051). Post-lung transplantation morbidities and mortality remain substantial for infants and children with genetic disorders of surfactant metabolism.

Late administration of surfactant replacement therapy increases surfactant protein-B content: a randomized pilot study

Background:Surfactant dysfunction may contribute to the development of bronchopulmonary dysplasia (BPD) in persistently ventilated preterm infants. We conducted a multicenter randomized, blinded, pilot study to assess the safety and efficacy of late administration of doses of a surfactant protein-B (SP-B)-containing surfactant (calfactant) in combination with prolonged inhaled nitric oxide (iNO) in infants ≤1,000 g birth weight (BW).Methods:We randomized 85 preterm infants ventilated at 7–14 d after birth to receive either late administration of surfactant (up to 5 doses) plus prolonged iNO or iNO alone. Large aggregate surfactant was isolated from daily tracheal aspirates (TAs) for measurement of SP-B content, total protein, and phospholipid (PL).Results:Late administration of surfactant had minimal acute adverse effects. Clinical status as well as surfactant recovery and SP-B content in tracheal aspirate were transiently improved as compared to the controls; these effects waned after 1 d. The change in SP-B content with surfactant dosing was positively correlated with SP-B levels during treatment (r = 0.50, P = 0.02).Conclusion:Low SP-B values increased with calfactant administration, but the relationship of this response to SP-B levels suggests that degradation is a contributing mechanism for SP-B deficiency and surfactant dysfunction. We conclude that late therapy with surfactant in combination with iNO is safe and transiently increases surfactant SP-B content, possibly leading to improved short- and long-term respiratory outcomes.

Mice With Targeted Deletion of Receptor for Hyaluronan‐Mediated Motility (RHAMM, CD168) Are Protected From Bleomycin‐Induced Lung Injury

Acute lung injury results in inflammation, Surfactant Protein B (SPB) deficiency and respiratory distress. Hyaluronan (HA) and its receptor RHAMM have been implicated in the inflammatory response to lung injury. We hypothesized that RHAMM KO mice would be protected from bleomycin‐induced lung injury. Littermate wild type (WT) and RHAMM KO mice were treated with IT 1U/kg bleomycin in 25μl saline or with 25μl saline alone. IT bleomycin in WT controls resulted in decreased body weight, and increased respiratory rate by d7‐10. RHAMM KO mice given IT bleomycin had significantly less weight loss and respiratory distress than WT mice. Compared to injured WT animals, RHAMM KO mice had lower lavage concentrations of HA, as well as lower neutrophil and macrophage enzyme activities. In injured WT mice on d7, western blot for SPB showed decreased expression of the mature 16‐kDa dimer, but no change in SPB expression was seen in injured RHAMM KO mice. We conclude that RHAMM KO mice have less inflammation, SPB deficiency and respiratory distress after acute lung injury. We speculate that these data are important for future development of novel therapeutic approaches to limit the severity of lung disease.

Surfactant Protein-B 121ins2 Heterozygosity, Reduced Pulmonary Function, and Chronic Obstructive Pulmonary Disease in Smokers

Hereditary surfactant protein-B deficiency is an autosomal recessive disorder that causes fatal respiratory distress syndrome in newborns. Seventy percent of the cases of hereditary surfactant protein-B deficiency are caused by homozygosity for the 121ins2 mutation in the surfactant protein-B gene. Individuals heterozygous for this mutation have partial absence of surfactant protein-B and could be at risk of lung disease when exposed to additional risk factors for impaired surfactant function such as tobacco smoking. To test whether individuals heterozygous for the 121ins2 mutation have reduced lung function and increased risk for chronic obstructive pulmonary disease (COPD) among smokers. We genotyped 47,600 individuals from the adult Danish general population and recorded smoking habits, spirometry, and hospital admissions due to COPD. The study and findings are limited to Danes/Europeans. We identified 85 individuals heterozygous for the 121ins2 mutation. Smoking interacted statistically with the 121ins2 genotype in predicting FEV(1) % predicted (P = 0.006), FVC % predicted (P = 0.02) and FEV(1)/FVC (P = 0.002), indicating that the effect of genotype differ by smoking status. Among smokers, 121ins2 heterozygous individuals had 9% reduced FEV(1)% predicted (P = 0.0008), 6% reduced FVC % predicted (P = 0.01) and 6% reduced FEV(1)/FVC (P = 0.00007), compared with wild-types. Also among smokers, 121ins2 heterozygous individuals had odds ratios of 2.4 (95% CI, 1.2-4.8) for spirometry-defined COPD and 2.2 (1.0-5.1) for hospitalization due to COPD. Among never-smokers, 121ins2 heterozygous individuals did not differ from wild-types in lung function or risk of COPD. Surfactant protein-B 121ins2 heterozygosity is associated with reduced lung function and increased risk for COPD among smokers.

Ultrastructural and molecular analysis in fatal neonatal interstitial pneumonia caused by a novel ABCA3 mutation

Pulmonary surfactant is essential to maintain alveolar patency, and invariably fatal neonatal lung disease has been recognized to involve mutations in the genes encoding surfactant protein-B or ATP-binding cassette transporter family member ABCA3. The lipid transporter ABCA3 targets surfactant phospholipids to lamellar bodies that are lysosomal-derived organelles of alveolar type II cells. ABCA3−/− mice have grossly reduced surfactant phosphatidyl glycerol levels and die of respiratory failure soon after birth. We studied lung biopsy samples of two siblings with a novel homozygous ABCA3 mutation at nucleotide position 578 (c.578C>G), leading to a Pro193Arg amino-acid exchange, who died at 55 and 105 days of age. Light microscopy revealed thickened alveolar septa with abundant myxoid interstitial matrix, marked hyperplasia of type II pneumocytes, desquamation of alveolar macrophages and focal alveolar proteinosis. Surfactant protein-B was detected by immunohistochemistry after antigen retrieval. Transmission electron microscopy showed rare cytoplasmic inclusions with concentric membranes and eccentrically placed electron-dense aggregates. These ‘fried-egg'-appearing lamellar bodies differed both from normal lamellar bodies and the larger, poorly formed composite bodies with multiple vesicular inclusions observed in surfactant protein-B deficiency. In conclusion, our findings underscore that the implications of interstitial lung disease in infant lungs differ from those in adults. In infants with a desquamative interstitial pneumonitis pattern, surfactant or ABCA3 mutations should be evaluated. Importantly, these findings support the notion that electron microscopy is useful in distinguishing between surfactant protein-B and ABCA3 deficiency, and has an important role in evaluating biopsies or autopsies of term infants with unexplained severe respiratory failure and interstitial lung disease.

Long-term outcomes after infant lung transplantation for surfactant protein B deficiency related to other causes of respiratory failure

To determine if the outcomes of lung transplantation for infants with surfactant protein-B (SP-B) deficiency are unique. From a prospective analysis to identify infants with genetic causes of surfactant deficiency, we identified 33 SP-B-deficient infants from 1993 to 2005, and, among those undergoing lung transplantation (n = 13), compared their survival, pulmonary function, and developmental progress with infants who underwent transplantation at <1 year of age for parenchymal lung disease (n = 13) or pulmonary vascular disease (n = 11). Five-year survival rates ( approximately 50%, P = .3) and causes of death were similar for all three groups once the infants underwent transplantation. However, significant pretransplantation mortality decreased 5-year survival from listing to approximately 30% (P = .17). Pulmonary function, development of bronchiolitis obliterans, and school readiness were similar among the three groups. We detected anti SP-B antibody in serum of 3 of 7 SP-B-deficient infants and none of 7 SP-B-sufficient infants but could not identify any associated adverse outcomes. Long-term outcomes after infant lung transplantation for SP-B-deficient infants are similar to those of infants transplanted for other indications. These outcomes are important considerations in deciding to pursue lung transplantation for infants with disorders of alveolar homeostasis.

Surfactant Composition and Function in Patients with ABCA3 Mutations

Mutations in the gene encoding the ATP binding cassette transporter member A3 (ABCA3) are associated with fatal surfactant deficiency. ABCA3 lines the limiting membrane of lamellar bodies within alveolar type-II cells, suggesting a role in surfactant metabolism. The objective of this study was to determine the surfactant phospholipid composition and function in patients with mutations in the ABCA3 gene. Bronchoalveolar lavage (BAL) fluid was analyzed from three groups of infants: 1) Infants with ABCA3 mutations, 2) infants with inherited surfactant protein-B deficiency (SP-B), and 3) patients without parenchymal lung disease (CON). Surfactant phospholipid profile was determined using two-dimensional thin-layer chromatography, and surface tension was measured with a pulsating bubble surfactometer. Phosphatidylcholine comprised 41 +/- 19% of the total phospholipid in the BAL fluid of the ABCA3 group compared with 78 +/- 3% and 68 +/- 18%, p = 0.008 and 0.05, of the CON and SP-B groups, respectively. Surface tension was 31.5 +/- 9.3 mN/m and was significantly greater than CON but no different from SP-B. We conclude that mutations in ABCA3 are associated with surfactant that is deficient in phosphatidylcholine and has decreased function, suggesting that ABCA3 plays an important role in pulmonary surfactant phospholipid homeostasis.

Surfactant protein B deficiency: a rare cause of respiratory failure in a Lebanese newborn

Surfactant protein B deficiency: a rare cause of respiratory failure in a Lebanese newborn

Partial SP-B deficiency perturbs lung function and causes air space abnormalities

Surfactant protein B (SP-B) is required for function of newborn and adult lung, and partial deficiency has been associated with susceptibility to lung injury. In the present study, transgenic mice were produced in which expression of SP-B in type II epithelial cells was conditionally regulated. Concentrations of SP-B were maintained at 60-70% of that normally present in control. Immunostaining for SP-B demonstrated cellular heterogeneity in expression of the protein. In subsets of type II cells in which SP-B staining was decreased, immunostaining for pro-SP-C was increased and lamellar body ultrastructure was disrupted, consistent with focal SP-B deficiency. Fluorescence-activated cell sorting analyses of freshly isolated type II cells identified a population of cells with low SP-B content and a smaller population with increased SP-B content, confirming nonuniform expression of the SP-B transgene. Focal air space enlargement, without cellular infiltration or inflammation, was observed. Pressure-volume curves indicated that maximal tidal volume was unchanged; however, hysteresis was modestly altered and residual volumes were significantly decreased in the SP-B-deficient mice. Chronic, nonuniform SP-B deficiency perturbed pulmonary function and caused air space enlargement.

Primary alveolar capillary dysplasia (acinar dysplasia) and surfactant protein B deficiency: a clinical, radiological and pathological study

Full-term infants with severe and prolonged respiratory distress represent a diagnostic challenge. Plain radiographic findings may be nonspecific or similar to classic surfactant deficiency disease for infants with surfactant protein B deficiency and acinar dysplasia. To describe the similar clinical-radiolgical patterns of two rare neonatal conditions. Six newborn babies with severe respiratory distress at birth demonstrated clinical and radiographically prolonged and progressive diffuse pulmonary opacification. All infants demonstrated hyperinflation of the lungs. The diffuse hazy opacification, which varied from mild (n=3) to moderate (n=3), progressed to severe diffuse opacification preceding death, which occurred at 12-36 days of life. Open lung biopsy confirmed the diagnosis of primary alveolar acinar dysplasia (AD) in four infants and surfactant protein B deficiency (SPBD) in two infants. In full-term babies with unexplained progressive respiratory distress from birth and progress of radiological changes, both AD and SPBD should be considered.

N-terminally extended surfactant protein (SP) C isolated from SP-B-deficient children has reduced surface activity and inhibited lipopolysaccharide binding.

In both humans and mice, a deficiency of surfactant protein B (SP-B) is associated with a decreased concentration of mature SP-C and accumulation of a larger SP-C peptide, denoted SP-C(i), which is not observed under normal conditions. Isolation of hydrophobic polypeptides from the lungs of children who died with two different SP-B mutations yielded pure SP-C(i) and showed only trace amounts of mature SP-C. Determination of the SP-C(i) covalent structure revealed a 12-residue N-terminal peptide segment, followed by a 35-residue segment that is identical to mature SP-C. The SP-C(i) structure determined herein is similar to that of a proposed late intermediate in the processing of proSP-C, suggesting that SP-C(i) is the immediate precursor of SP-C. In bronchoalveolar lavage fluid from transgenic mice with a focal deficiency of SP-B, SP-C(i) was detected in the biophysically active, large aggregate fraction and was associated with membrane structures that are typical for a large aggregate surfactant. However, unlike SP-C, SP-C(i) exhibited a very poor ability to promote phospholipid adsorption, gave high surface tension during cyclic film compression, and did not bind lipopolysaccharide in vitro. SP-C(i) is thus capable of associating with surfactant lipids, but its N-terminal dodecapeptide segment must be proteolytically removed to generate a biologically functional peptide. The results of this study indicate that the early postnatal fatal respiratory distress seen in SP-B-deficient children is combined with the near absence of active variants of SP-C.

Surfactant protein B deficiency in infants with respiratory failure.

Surfactant Protein B (SP-B) deficiency has been recently identified as an uncommon, autosomal recessive lung disorder in term infants. This inability to produce SP-B leads to progressive, lethal, hypoxemic respiratory failure in the first year of life. A frameshift mutation (121 ins 2) is the predominant but not exclusive cause. The clue to diagnosis is to have a high suspicion of SP-B deficiency in any term infant with severe respiratory distress without any apparent cause. SP-B deficiency can be diagnosed prenatally or postnatally. The only current treatment options available include lung transplantation or compassionate care. Current developments in gene therapy offer hope for future treatment.

Involvement of Napsin A in the C- and N-terminal Processing of Surfactant Protein B in Type-II Pneumocytes of the Human Lung

Surfactant protein B (SP-B) is a critical component of pulmonary surfactant, and a deficiency of active SP-B results in fatal respiratory failure. SP-B is synthesized by type-II pneumocytes as a 42-kDa propeptide (proSP-B), which is posttranslationally processed to an 8-kDa surface-active protein. Napsin A is an aspartic protease expressed in type-II pneumocytes. To characterize the role of napsin A in the processing of proSP-B, we colocalized napsin A and precursors of SP-B as well as SP-B in the Golgi complex, multivesicular, composite, and lamellar bodies of type-II pneumocytes in human lungs using immunogold labeling. Furthermore, we measured aspartic protease activity in isolated lamellar bodies as well as isolated human type-II pneumocytes and studied the cleavage of proSP-B by napsin A and isolated lamellar bodies in vitro. Both, napsin A and isolated lamellar bodies cleaved proSP-B and generated three identical processing products. Processing of proSP-B by isolated lamellar bodies was completely inhibited by an aspartic protease inhibitor. Sequence analysis of proSP-B processing products revealed several cleavage sites in the N- and C-terminal propeptides as well as one in the mature peptide. Two of the four processing products generated in vitro were also detected in type-II pneumocytes. In conclusion, our results show that napsin A is involved in the N- and C-terminal processing of proSP-B in type-II pneumocytes.

Analysis of 40 sporadic or familial neonatal and pediatric cases with severe unexplained respiratory distress: relationship to SFTPB.

We have analyzed surfactant protein B (SP-B) and its encoding gene (SFTPB, MIM 178640) in 40 unrelated pediatric patients with unexplained respiratory distress (URD). There was high consanguinity (eight kindreds) and an underlying autosomal recessive trait could be inferred in most cases, with overall high sex ratio (32/17) suggesting proband's gender to impact on penetrance. The clinical/biological presentations fitted into three major nosologic frameworks. I: SP-B deficiency (nine probands), complete or incomplete, with homozygous/compoundly heterozygous mutations identified (six probands), including one from the population isolate of Réunion Island (496delG). In addition, there was a consanguineous kindred in which incomplete deficiency was unambiguously unlinked to SFTPB. II: pulmonary alveolar proteinosis (PAP, 19 probands), with typical storage of PAS-positive material within the alveoli with foamy macrophages and variable interstitial reaction, which was diagnosed in most patients from Réunion Island. In contrast to previously published findings, mutation and/or segregation analyses excluded SFTPB as a disease locus, although slight metabolic derangement related to SP-B and/or mild SFTPB changes could somehow contribute to disease. III: URD without evidence for SP-B deficiency or PAP (12 probands), equally unlinked to SFTPB, although a single patient had a possibly causal, maternally-derived, heterozygous genetic change (G4521A). The population frequency of five known and four novel SNPs was studied, providing as many potential markers for pulmonary disease related to SFTPB. Overall, URD was found to be heterogeneous, both phenotypically and genetically, even in population isolates where a founder effect might have been expected. When disease loci are identified, patient genotyping will be crucial as a diagnostic aid, for devising proper treatment, and as a basis for genetic counseling.

High-frequency oscillation and paralysis stabilize surfactant protein-B--deficient infants.

To determine if high-frequency oscillatory ventilation and neuromuscular blockade improve oxygenation and chest radiographic appearance more effectively than high-frequency oscillation alone for surfactant protein-B (SP-B)--deficient infants. We reviewed medical records and chest radiographs of five SP-B--deficient infants awaiting lung transplantation. Changes in FiO2 and radiographic scores were analyzed with respect to neuromuscular blockade status. FiO2 consistently increased 0.20 (SD 0.11) during high-frequency ventilation without neuromuscular blockade (p = 0.02) and decreased 0.14 (SD 0.11) during high-frequency ventilation with neuromuscular blockade (p = 0.05). Chest radiographic appearance, quantified by an expansion/aeration index, consistently deteriorated without neuromuscular blockade (p = 0.01) and consistently improved with neuromuscular blockade (p = 0.03). Changes in FiO2 correlated with changes in radiograph scores (r = 0.7, p < 0.001). High-frequency ventilation with neuromuscular blockade optimizes oxygenation for SP-B--deficient infants. This ventilatory strategy should be considered while awaiting the diagnosis of SP-B deficiency or lung transplantation.

Surfactant Protein B Deficiency: Insights into Surfactant Function through Clinical Surfactant Protein Deficiency

Surfactant protein B (SP-B) deficiency is a disorder of surfactant function with complete or transient absence of SP-B in term neonates. SP-B, 1 of 4 described surfactant-associated proteins, plays a key role in surfactant metabolism, particularly in intracellular packaging of surfactant components, formation of tubular myelin, and the presentation of the surfactant phospholipid monolayer to the air-fluid interface within the alveolus. Neonates with clinical SP-B deficiency best demonstrate the key role of SP-B in surfactant function. "Classic" deficiency results in severe respiratory failure in term infants and death unless lung transplantation is performed. Because the initial description of complete deficiency secondary to a homozygous frameshift mutation in codon 121 of the SP-B cDNA, partial deficiencies with differing genetic backgrounds and less severe clinical courses have been reported. These partial deficiency states may provide a clearer picture of genotype/phenotype relationships in SP-B function and surfactant metabolism. SP-B deficiency or dysfunction may be more common than once thought and may play a significant role in neonatal lung disease.