Non-bronchoscopic Bronchoalveolar Lavage as a Refinement for Safely Obtaining High-quality Samples from Macaques

Nonbronchoscopic bronchoalveolar lavage (NB-BAL) is a minimally invasive diagnostic and research tool used to sample the cells of lower airways and alveoli without using a bronchoscope. Our study compared NB-BAL and bronchoscopic bronchoalveolar lavage (B-BAL) in terms of costs, cell yields, and the number of post-procedural complications in macaques. We also analyzed procedure times, BAL fluid volume yields, and vital signs in a subset of animals that underwent NB-BAL. Compared with the B-BAL technique, NB-BAL was less expensive to perform, with fewer complications, fewer animals requiring temporary or permanent cessation of BALs, and higher cell yields per mL of recovered saline. The average procedure time for NB-BAL was 6.8 ± 1.6 min, and the average NB-BAL lavage volume yield was 76 ± 9%. We found no significant differences in respiration rate before, during, or after NB-BAL but did find significant differences in heart rate and oxygen saturation (SpO₂). This study demonstrates that NB-BAL is a simple, cost-effective, and safe alternative to B-BAL that results in higher cell yields per mL, improved animal welfare, and fewer missed time points, and thus constitutes a refinement over the B-BAL in macaques.

Bronchoalveolar lavage (BAL) is a minimally invasive diagnostic and research tool used to retrieve cells, microbes, and biomarkers from the lower airways and alveoli. The technique is used in both human and veterinary medicine to aid in diagnosing respiratory tract diseases such as lower airway infections, neoplasia, pulmonary hemorrhage, hypereosinophilic syndromes, hypersensitivity pneumonitis, and environmental lung diseases. BAL is also used in research to investigate the immunologic response of the lower airways to induced or spontaneous diseases. BAL fluid can be analyzed in terms of flow cytometry, gene expression, antibody titers, inflammatory mediators, and the confirmation or monitoring of experimental infections via culture or polymerase chain reaction.BAL may be performed with or without the use of a bronchoscope. Bronchoscopic BAL (B-BAL) has several advantages, including visualization of the upper and lower airways and the capacity to select particular lung lobes for fluid instillation and retrieval. B-BAL is also cited as having a better ability to “wedge” the scope into a bronchus, creating a tight seal that may improve volume yield.⁷ However, B-BAL has several disadvantages, including high equipment cost, the need for trained bronchoscopists, and the difficulty of effective and efficient instrument sterilization. Similarly, B-BAL may not be possible in small human or veterinary patients, and visualization of airways and selection of a particular lung lobe may not be necessary for research purposes.Nonbronchoscopic BAL (NB-BAL) is typically performed by passing a small suction catheter through an endotracheal (ET) tube into the lower airways. This technique has been used in infants and domestic cats requiring small diameter ET tubes because until recently the smallest available bronchoscope with a lavage channel would obstruct the ET tube lumen in these subjects.⁶ Although advancements in endoscope technology have made fine diameter broncho-fiberscopes with lavage channels available, NB-BAL has several advantages over B-BAL, including lower cost, minimal needs for technical skill, and no need for bronchoscope equipment. In addition, the use of sterile, single-use catheters reduces the potential for cross-contamination between patients and samples.⁹Our group, the Oregon National Primate Research Center (ONPRC) Infectious Disease Resource (IDR), provides technical support to facilitate nonhuman primate (NHP) studies in areas such as immunology, infectious disease pathogenesis, and safety and efficacy testing of therapeutics and vaccines. BAL fluid contains abundant effector memory CD8⁺ T cells derived from an easily accessible mucosal site⁴ and is commonly requested by our investigators, with requests of 10 to 50 samples per workday. We initially used the ONPRC Surgical Services Unit (SSU) to obtain samples using B-BAL; this approach was expensive, frequently required medical intervention (supplemental oxygen, terbutaline and/or furosemide), and caused many animals to miss multiple BAL time points due to periprocedural complications. In addition, due to high procedure volumes and a limited number of bronchoscopes, equipment was commonly cleaned but not sterilized between animals. Therefore, we sought an inexpensive, simple BAL technique that promoted equipment sterility between animals, provided comparable results for investigators, and resulted in better clinical outcomes for study animals. We hypothesized that NB-BAL would provide comparable research results (cell yields) to B-BAL at a lower cost to our researchers. We also hypothesized that using the NB-BAL method would minimize complications as compared with the B-BAL method. Finally, we analyzed procedure times, BAL fluid volume yields, and vital signs in a subset of animals that underwent NB-BAL.     

NAD(P)H quinone oxidoreductase 1 regulates neutrophil elastase-induced mucous cell metaplasia

Mucous cell metaplasia (MCM) and neutrophil-predominant airway inflammation are pathological features of chronic inflammatory airway diseases. A signature feature of MCM is increased expression of a major respiratory tract mucin, MUC5AC. Neutrophil elastase (NE) upregulates MUC5AC in primary airway epithelial cells by generating reactive oxygen species, and this response is due in part to upregulation of NADPH quinone oxidoreductase 1 (NQO1) activity. Delivery of NE directly to the airway triggers inflammation and MCM and increases synthesis and secretion of MUC5AC protein from airway epithelial cells. We hypothesized that NE-induced MCM is mediated in vivo by NQO1. Male wild-type and Nqo1-null mice (C57BL/6 background) were exposed to human NE (50 μg) or vehicle via oropharyngeal aspiration on days 1, 4, and 7. On days 8 and 11, lung tissues and bronchoalveolar lavage (BAL) samples were obtained and evaluated for MCM, inflammation, and oxidative stress. MCM, inflammation, and production of specific cytokines, granulocyte-macrophage colony-stimulating factor, macrophage inflammatory protein-2, interleukin-4, and interleukin-5 were diminished in NE-treated Nqo1-null mice compared with NE-treated wild-type mice. However, in contrast to the role of NQO1 in vitro, we demonstrate that NE-treated Nqo1-null mice had greater levels of BAL and lung tissue lipid carbonyls and greater BAL iron on day 11, all consistent with increased oxidative stress. NQO1 is required for NE-induced inflammation and MCM. This model system demonstrates that NE-induced MCM directly correlates with inflammation, but not with oxidative stress.     

Clara cell protein (CC16): characteristics and potential applications as biomarker of lung toxicity

Most biomarkers of lung toxicity presently available require a bronchoahreolar lavage (BAL). Such a procedure cannot be applied for monitoring populations at risk in the industry or environment nor for a regular follow-up of patients with lung disorders. A lung biomarker, measurable in serum, BAL fluid and sputum has recently been identified. This biomarker is a microptotein initially isolated from urine (Urine Protein 1) and subsequently identified as the major secretory product of lung Clara cells which are non-ciliated cells localized predominantly in terminal bronchioles. This protein called Clara cell protein (CC16) is a homodimer of 15.8 kDA. Several lines of evidence indicate that CC16 is a natural immunoregulator protecting the respiratory tract from unwanted inflammatory reactions. CC16 secreted in the respiratory tract diffuses passively by transudation into plasma from where it is rapidly eliminated by glomerular filtration before being taken up and catabolized in proximal tubule cells. Studies reviewed here suggest that CC16 in BAL fluid or serum is a sensitive indicator of acute or chronic bronchial epithelium injury. A significant reduction of CC16 has been found in serum and BAL fluid of asymptomatic smokers. On average serum CC16 decreases by 15% for each 10 pack-year smoking history. Serum CC16 was also found to be decreased in several occupational groups chronically exposed to different air pollutants (silica, dust, welding fumes). A dose—effect relationship with the intensity of exposure to dust has been found in one study on foundry workers. The concentration of CC16 in serum can also be used to detect an acute or chronic disruption of the bronchoalveolar/blood barrier integrity. While confirming the potential interest of CC16 as a lung biomarker, clinical investigations indicate that CC16 might be an important mediator in the development of lung injury. These findings open new perspectives in the assessment of lung toxicity by suggesting that readily diffusible lung-specific proteins may serve as peripheral markers of pneumotoxicity.     

Mechanisms of Pharmaceutical Aerosol Deposition in the Respiratory Tract

Aerosol delivery is noninvasive and is effective in much lower doses than required for oral administration. Currently, there are several types of therapeutic aerosol delivery systems, including the pressurized metered-dose inhaler, the dry powder inhaler, the medical nebulizer, the solution mist inhaler, and the nasal sprays. Both oral and nasal inhalation routes are used for the delivery of therapeutic aerosols. Following inhalation therapy, only a fraction of the dose reaches the expected target area. Knowledge of the amount of drug actually deposited is essential in designing the delivery system or devices to optimize the delivery efficiency to the targeted region of the respiratory tract. Aerosol deposition mechanisms in the human respiratory tract have been well studied. Prediction of pharmaceutical aerosol deposition using established lung deposition models has limited success primarily because they underestimated oropharyngeal deposition. Recent studies of oropharyngeal deposition of several drug delivery systems identify other factors associated with the delivery system that dominates the transport and deposition of the oropharyngeal region. Computational fluid dynamic simulation of the aerosol transport and deposition in the respiratory tract has provided important insight into these processes. Investigation of nasal spray deposition mechanisms is also discussed.     

Human LPLUNC1 is a secreted product of goblet cells and minor glands of the respiratory and upper aerodigestive tracts

Long PLUNC1 (LPLUNC1, C20orf114) is a member of a family of poorly described proteins (PLUNCS) expressed in the upper respiratory tract and oral cavity, which may function in host defence. Although it is one of the most highly expressed genes in the upper airways and has been identified in sputum and nasal secretions by proteomic studies, localisation of LPLUNC1 protein has not yet been described. We developed affinity purified antibodies and localised the protein in tissues of the human respiratory tract, oro- and nasopharynx. We have complemented these studies with analysis of LPLUNC1 expression in primary human lung cell cultures and used Western blotting to study the protein in cell culture secretions and in BAL. LPLUNC1 is a product of a population of goblet cells in the airway epithelium and nasal passages and is also present in airway submucosal glands and minor glands of the oral and nasal cavities. The protein is not expressed in peripheral lung epithelial cells. LPLUNC1 is present in bronchoalveolar lavage fluid as two glycosylated isoforms and primary airway epithelial cells produce identical proteins as they undergo mucociliary differentiation. Our results suggest that LPLUNC1 is an abundant, secreted product of goblet cells and minor mucosal glands of the respiratory tract and oral cavity and suggest that the protein functions in the complex milieu that protects the mucosal surfaces in these locations.     

Abundant DNase I-Sensitive Bacterial DNA in Healthy Porcine Lungs and Its Implications for the Lung Microbiome

Human lungs are constantly exposed to bacteria in the environment, yet the prevailing dogma is that healthy lungs are sterile. DNA sequencing-based studies of pulmonary bacterial diversity challenge this notion. However, DNA-based microbial analysis currently fails to distinguish between DNA from live bacteria and that from bacteria that have been killed by lung immune mechanisms, potentially causing overestimation of bacterial abundance and diversity. We investigated whether bacterial DNA recovered from lungs represents live or dead bacteria in bronchoalveolar lavage (BAL) fluid and lung samples in young healthy pigs. Live bacterial DNA was DNase I resistant and became DNase I sensitive upon human antimicrobial-mediated killing in vitro. We determined live and total bacterial DNA loads in porcine BAL fluid and lung tissue by comparing DNase I-treated versus untreated samples. In contrast to the case for BAL fluid, we were unable to culture bacteria from most lung homogenates. Surprisingly, total bacterial DNA was abundant in both BAL fluid and lung homogenates. In BAL fluid, 63% was DNase I sensitive. In 6 out of 11 lung homogenates, all bacterial DNA was DNase I sensitive, suggesting a predominance of dead bacteria; in the remaining homogenates, 94% was DNase I sensitive, and bacterial diversity determined by 16S rRNA gene sequencing was similar in DNase I-treated and untreated samples. Healthy pig lungs are mostly sterile yet contain abundant DNase I-sensitive DNA from inhaled and aspirated bacteria killed by pulmonary host defense mechanisms. This approach and conceptual framework will improve analysis of the lung microbiome in disease.     

Stimulation of respiratory immunity by oral administration of Lactococcus lactis

This work demostrates that nonrecombinant Lactococcus lactis NZ, administered by the oral route at the proper dose, is able to improve resistance against pneumococcal infection. Lactococcus lactis NZ oral administration was able to improve pathogen lung clearance, increased survival of infected mice, and reduced lung injuries. This effect was related to an upregulation of the respiratory innate and specific immune responses. Administration of L. lactis NZ improved production of bronchoalveolar lavage (BAL) fluid TNF-alpha, enhanced recruitment of neutrophils into the alveolar spaces, and induced a higher activation of BAL phagocytes compared with the control group. Lactococcus lactis NZ administered orally stimulated the IgA cycle, increased IgA+ cells in intestine and bronchus, and improved production of BAL IL-4 and IL-10 during infection. Moreover, mice treated with L. lactis NZ showed higher levels of BAL anti-pneumococcal IgA and IgG. Taking into consideration that orally administered L. lactis NZ stimulates both the innate and the specific immune responses in the respiratory tract and that bacterial and viral antigens have been efficiently produced in this strain, L. lactis NZ is an excellent candidate for the development of an effective pneumococcal oral vaccine.     

Rhinovirus genome variation during chronic upper and lower respiratory tract infections

Routine screening of lung transplant recipients and hospital patients for respiratory virus infections allowed to identify human rhinovirus (HRV) in the upper and lower respiratory tracts, including immunocompromised hosts chronically infected with the same strain over weeks or months. Phylogenetic analysis of 144 HRV-positive samples showed no apparent correlation between a given viral genotype or species and their ability to invade the lower respiratory tract or lead to protracted infection. By contrast, protracted infections were found almost exclusively in immunocompromised patients, thus suggesting that host factors rather than the virus genotype modulate disease outcome, in particular the immune response. Complete genome sequencing of five chronic cases to study rhinovirus genome adaptation showed that the calculated mutation frequency was in the range observed during acute human infections. Analysis of mutation hot spot regions between specimens collected at different times or in different body sites revealed that non-synonymous changes were mostly concentrated in the viral capsid genes VP1, VP2 and VP3, independent of the HRV type. In an immunosuppressed lung transplant recipient infected with the same HRV strain for more than two years, both classical and ultra-deep sequencing of samples collected at different time points in the upper and lower respiratory tracts showed that these virus populations were phylogenetically indistinguishable over the course of infection, except for the last month. Specific signatures were found in the last two lower respiratory tract populations, including changes in the 5'UTR polypyrimidine tract and the VP2 immunogenic site 2. These results highlight for the first time the ability of a given rhinovirus to evolve in the course of a natural infection in immunocompromised patients and complement data obtained from previous experimental inoculation studies in immunocompetent volunteers.     

Profiling of bisenoic prostaglandins and thromboxane B2 in bronchoalveolar fluid from the lower respiratory tract of human subjects by combined capillary gas chromatography-mass spectrometry

Methods for the profiling of prostaglandin D2 (PGD2), prostaglandin E2 (PGE2), prostaglandin F2 alpha (PGF2 alpha), 15(S),9 alpha,11 beta-trihydroxyprosta-5Z,13E-dien-1-oic acid (9 alpha,11 beta-PGF2), 6-keto-prostaglandin F1 alpha (6kPGF1 alpha), and thromboxane B2 (TxB2) in bronchoalveolar lavage (BAL) fluids from human subjects by combined capillary gas chromatography-mass spectrometry are described. Aliquots (5 ml) of BAL fluid obtained using a standardized lavage protocol were extracted on octadecylsilyl silica cartridges after addition of 0.8 to 2.0 nanograms of tetradeuterated analogs of PGE2, PGF2 alpha, and 6kPGF1 alpha as internal standards. Eluted analytes and internal standards were prepared for vapor phase analysis by sequential reactions resulting in the formation of methyloxime-pentafluorobenzyl ester-trimethylsilyl ether derivatives. The derivatized analytes were detected by simultaneous monitoring of ions at six different masses characteristic for each of the derivatized prostanoids. The samples were of adequate purity for identification and quantitation of each of the prostanoids with detection limits of 0.1 to 0.2 picograms of each analyte per milliliter of BAL fluid. The time required for analysis of each sample was approximately 30 minutes. Standard curves of unlabeled species of the six prostanoids extracted after addition to BAL fluid were linear over a range from subpicogram to nanogram quantities. The differences between the amounts of prostanoid added and the amounts of prostanoid measured were typically less than 19%, and the intra-assay coefficients of variation for repeated measurements of a single sample were less than 20%. PGE2, PGD2, PGF2 alpha, and TxB2 were detectable in BAL fluids from normal subjects with levels of each of these compounds being less than 2.6 picograms/ml. BAL fluids from patients with lung disease presented qualitative and quantitative profiles of prostanoids markedly different than those from normal subjects. These analytical methods provide a basis for in vivo comparisons of prostanoid profiles in the lower respiratory tract of man and should be readily adaptable for use in a variety of clinical studies.     

Bronchoscopic Diagnosis of Pulmonary Infections—Comparison of Protected-Specimen Brush and Cytology Brush With Lung Aspirates

In a recent study the use of a new plugged double-lumen protected-specimen brush with the flexible fiberoptic bronchoscope was advocated to isolate pathogens in lower respiratory tract infections while avoiding upper respiratory tract contamination. To compare the efficacy of this brush and a standard single-lumen cytology brush in identifying the etiologic agent in lower respiratory tract infections, we studied 18 patients with lung infections. Transthoracic lung aspiration was done in all but two patients in an attempt to identify the specific etiologic agent. In these two cases, cultures of specimens of blood or postmortem lung tissue yielded the causative organism. In 12 patients anaerobic or aerobic bacteria (or both) were identified, whereas one patient had a mixed bacterial and fungal infection. Using the cytology brush and the protected-specimen brush we identified at least one pathogen in 10 of 12 and 10 of 13 cases, whereas both brushes missed one or more causative organisms in 8 of 12 and 8 of 13 cases, respectively. Nonetiologic organisms were found in 8 of 12 cases by the cytology brush and 8 of 13 cases by the protected-specimen brush. Quantitative culture techniques improved the specificity of the brush results in infections where aerobes predominated. Our data show that bronchoscopic cultures of lower respiratory tract infections do not consistently recover the causative agent and are frequently subject to contamination by nonetiologic organisms. There was no difference between the brushes in avoiding contamination.     

Analysis of Lung Microbiota in Bronchoalveolar Lavage,Protected Brush and Sputum Samples from Subjects with Mild-To-Moderate Cystic Fibrosis Lung Disease

Individuals with cystic fibrosis (CF) often acquire chronic lung infections that lead to irreversible damage. We sought to examine regional variation in the microbial communities in the lungs of individuals with mild-to-moderate CF lung disease, to examine the relationship between the local microbiota and local damage, and to determine the relationships between microbiota in samples taken directly from the lung and the microbiota in spontaneously expectorated sputum. In this initial study, nine stable, adult CF patients with an FEV₁>50% underwent regional sampling of different lobes of the right lung by bronchoalveolar lavage (BAL) and protected brush (PB) sampling of mucus plugs. Sputum samples were obtained from six of the nine subjects immediately prior to the procedure. Microbial community analysis was performed on DNA extracted from these samples and the extent of damage in each lobe was quantified from a recent CT scan. The extent of damage observed in regions of the right lung did not correlate with specific microbial genera, levels of community diversity or composition, or bacterial genome copies per ml of BAL fluid. In all subjects, BAL fluid from different regions of the lung contained similar microbial communities. In eight out of nine subjects, PB samples from different regions of the lung were also similar in microbial community composition, and were similar to microbial communities in BAL fluid from the same lobe. Microbial communities in PB samples were more diverse than those in BAL samples, suggesting enrichment of some taxa in mucus plugs. To our knowledge, this study is the first to examine the microbiota in different regions of the CF lung in clinically stable individuals with mild-to-moderate CF-related lung disease.     

Modulation of lung epithelial functions by Pseudomonas aeruginosa

Microorganisms gain access to the airways and respiratory epithelial surface during normal breathing. Most inhaled microbes are trapped on the mucous layer coating the nasal epithelium and upper respiratory tract, and are cleared by ciliary motion. Microorganisms reaching the alveolar spaces are deposited on the pulmonary epithelium. This contact initiates complex offensive and defensive strategies by both parties. Here, we briefly outline how the pulmonary pathogen Pseudomonas aeruginosa uses multi-pronged strategies that include cell surface appendages, and secreted and injected virulence determinants to switch from an unobtrusive soil bacterium to a pathogen for lung epithelium colonization. Understanding the complex interactions between the lung epithelium and P. aeruginosa might enable more effective therapeutic strategies against infection in cystic fibrosis and immuno-compromised individuals.     

Bronchoalveolar lavage fluid cytology in patients with Pneumocystis carinii pneumonia

OBJECTIVE: To evaluate bronchoalveolar lavage (BAL) cytology and organism burden in patients with Pneumocystis carinii pneumonia (PCP) who were infected with the human immunodeficiency virus (HIV) and in those with other immunodeficiencies. STUDY DESIGN: BAL fluid samples from patients with PCP were selected (HIV-infected patients, n = 15; patients with other immunodeficiencies, n = 11). May-Grünwald-Giemsa-stained cytocentrifuge preparations were evaluated. Foamy alveolar casts (FACs) and P carinii clusters were counted. RESULTS: The numbers of FACs and P carinii clusters in BAL fluid samples of HIV-infected patients were significantly higher as compared to those in samples from patients with other immunodeficiencies. Striking cytologic findings observed in half the samples from both patient groups included the presence of foamy alveolar macrophages, activated lymphocytes, plasma cells and reactive type II pneumocytes. Furthermore, a peculiar cell type, "nonidentified cell" (NIC), was observed almost exclusively in BAL fluid samples from HIV-infected patients. CONCLUSION: BAL fluid samples from HIV-infected patients with PCP displayed higher organism burdens as compared to those from patients with other immunodeficiencies. Moreover, cytologic findings suggestive of noninfectious lung conditions were common in BAL fluid samples obtained from patients with PCP. Further study is required to elucidate the identity of the NIC cell type.     

Reactive type II pneumocytes in bronchoalveolar lavage fluid

OBJECTIVE: To evaluate the prevalence of reactive type II pneumocytes (RPII) in bronchoalveolar lavage (BAL) fluid samples obtained from patients with various pulmonary disorders. STUDY DESIGN: Consecutive BAL fluid samples were screened for the presence of RPII on May-Grünwald-Giemsa-stained cytocentrifuge preparations. BAL fluid samples with and without RPII were compared with regard to prevalence, associated clinical diagnoses and cytologic findings. RESULTS: RPII were generally large cells with a high nuclear:cytoplasmic ratio and deeply blue-stained, vacuolated cytoplasm. Most RPII occurred in cohesive cell groups, and the vacuoles tended to be confluent. Cytologic findings associated with RPII were foamy alveolar macrophages, activated lymphocytes and plasma cells. RPII were present in 94 (21.7%) of 433 included BAL fluid samples. The highest prevalences were noted in patients with systemic inflammatory response syndrome and alveolar hemorrhage. In addition, RPII tended to occur more frequently in ventilator-associated pneumonia, Pneumocystis carinii pneumonia, extrinsic allergic alveolitis and drug-induced pulmonary disorders. In contrast, RPII were not observed in BAL fluid samples obtained from patients with sarcoidosis. CONCLUSION: RPII were prevalent in about 20% of BAL fluid specimens. They were associated mainly with conditions of acute lung injury and not observed in sarcoidosis.     

Diagnosis of PCP by ITSs Nested PCR on Notinvasive Oropharingeal Samples

Pneumocystis carinii pneumonia is an opportunistic disease usually affecting immunocompromised hosts. Diagnosis is based on the microscopical detection of microrganism on BAL, an invasive sample which requires pt compliance for collection and skilled health care personnel for examination. In order to verify the possible diagnostic utility of noninvasive specimens collected in the upper respiratory tract we examined by the Internal Transcribed Spacers (ITSs) nested PCR, 39 oropharingeal samples (garglings) collected from 20 HIVAb positive pts and from 15 healthy controls.     

Inhalation efficacy of RFI-641 in an African green monkey model of RSV infection

Human respiratory syncytial virus (RSV) is a major cause of acute upper and lower respiratory tract infections. RFI-641 is a novel RSV fusion inhibitor with potent in vitro activity. In vivo efficacy of RFI was determined in an African green monkey model of RSV infection involving prophylactic and therapeutic administration by inhalation exposure. Inhalation was with an RFI-641 nebulizer reservoir concentration of 15 mg/ml for 15 minutes (short exposure) or 2 hours (long exposure). Efficacy and RFI-641 exposure was determined by collection of throat swabs, nasal washes and bronchial alveolar lavage (BAL) on selected days. The short-exposure group (15 minutes) exhibited no effect on the nasal, throat or BAL samples. The throat and nasal samples for the long-exposure group failed to show a consistent reduction in viral titers. RFI-641 2 hours exposure-treated monkeys showed a statistically significantly log reduction for BAL samples of 0.73-1.34 PFU/ml (P-value 0.003) over all the sampling days. Analysis indicates that the long-exposure group titer was lower than the control titer on day 7 and when averaged across days. The results of this study demonstrate the ability of RFI-641 to reduce the viral load of RSV after inhalation exposure in the primate model of respiratory infection.     

Compartmentalization of vascular endothelial growth factor to the epithelial surface of the human lung

BACKGROUND: Based on assessment of mRNA expression, the lung is a major site of expression of the vascular endothelial growth factor (VEGF) gene, largely from type II alveolar epithelial cells. With the knowledge that VEGF can function to induce vascular leak, we hypothesized that to protect the lung from pulmonary edema, the VEGF produced in the lung must be compartmentalized from the pulmonary endothelium, and thus must be compartmentalized to the surface of the respiratory epithelium. MATERIAL AND METHODS: To assess this hypothesis, we quantified the levels of VEGF in human respiratory epithelial lining fluid recovered by bronchoalveolar lavage from normal individuals. RESULTS: Strikingly, human respiratory epithelial lining fluid contains 11 +/- 5 ng/mL as quantified by ELISA, a 500-fold greater concentration than plasma (22 +/- 10 pg/mL, p < 0.0005). Western analysis of BAL fluid proteins showed the major VEGF isoform in respiratory epithelial lining fluid is VEGF165. CONCLUSIONS: With the knowledge that proteins of molecular mass like VEGF (34 to 46 kDa) slowly diffuse across the alveolar epithelium, it is likely that this high level "reservoir" of VEGF protein on the respiratory epithelial surface plays a role in normal lung endothelial biology. However, this compartmentalized VEGF reservoir may also be a "Damocles sword" poised to induce lung endothelial permeability in conditions of acute lung injury when the integrity of the alveolar epithelial barrier is breached.     

Segregation of virulent influenza A(H1N1) variants in the lower respiratory tract of critically ill patients during the 2010-2011 seasonal epidemic

Background

Since its appearance in 2009, the pandemic influenza A(H1N1) virus circulated worldwide causing several severe infections.

Methods

Respiratory samples from patients with 2009 influenza A(H1N1) and acute respiratory distress attending 24 intensive care units (ICUs) as well as from patients with lower respiratory tract infections not requiring ICU admission and community upper respiratory tract infections in the Lombardy region (10 million inhabitants) of Italy during the 2010–2011 winter-spring season, were analyzed.

Results

In patients with severe ILI, the viral load was higher in bronchoalveolar lavage (BAL) with respect to nasal swab (NS), (p<0.001) suggesting a higher virus replication in the lower respiratory tract. Four distinct virus clusters (referred to as cluster A to D) circulated simultaneously. Most (72.7%, n = 48) of the 66 patients infected with viruses belonging to cluster A had a severe (n = 26) or moderate ILI (n = 22). Amino acid mutations (V26I, I116M, A186T, D187Y, D222G/N, M257I, S263F, I286L/M, and N473D) were observed only in patients with severe ILI. D222G/N variants were detected exclusively in BAL samples.

Conclusions

Multiple virus clusters co-circulated during the 2010–2011 winter-spring season. Severe or moderate ILI were associated with specific 2009 influenza A(H1N1) variants, which replicated preferentially in the lower respiratory tract.     

Increased Viral Loads and Exacerbated Innate Host Responses in Aged Macaques Infected with the 2009 Pandemic H1N1 Influenza A Virus

In contrast to seasonal influenza virus infections, which typically cause significant morbidity and mortality in the elderly, the 2009 H1N1 virus caused severe infection in young adults. This phenomenon was attributed to the presence of cross-protective antibodies acquired by older individuals during previous exposures to H1N1 viruses. However, this hypothesis could not be empirically tested. To address this question, we compared viral replication and the development of the immune response in naïve young adult and aged female rhesus macaques infected with A/California/04/2009 H1N1 (CA04) virus. We show higher viral loads in the bronchoalveolar lavage (BAL) fluid and nasal and ocular swabs in aged animals, suggesting increased viral replication in both the lower and upper respiratory tracts. T cell proliferation was higher in the BAL fluid but delayed and reduced in peripheral blood in aged animals. This delay in proliferation correlated with a reduced frequency of effector CD4 T cells in old animals. Aged animals also mobilized inflammatory cytokines to higher levels in the BAL fluid. Finally, we compared changes in gene expression using microarray analysis of BAL fluid samples. Our analyses revealed that the largest difference in host response between aged and young adult animals was detected at day 4 postinfection, with a significantly higher induction of genes associated with inflammation and the innate immune response in aged animals. Overall, our data suggest that, in the absence of preexisting antibodies, CA04 infection in aged macaques is associated with changes in innate and adaptive immune responses that were shown to correlate with increased disease severity in other respiratory disease models.