Effect and mechanism of acupuncture on airway smooth muscle relaxation during acute asthma attack in rats. / é’ˆåˆºæ¾å¼›å“®å–˜æ€¥æ€§å‘ä½œå¤§é¼ æ°”é“å¹³æ»‘è‚Œçš„ä½œç”¨æœºåˆ¶.

OBJECTIVES: To explore the effect and mechanism of acupuncture at "Feishu" (BL 13) and "Dingchuan" (EX-B 1), and "Kongzui" (LU 6) and "Yuji" (LU 10) for relaxing the airway smooth muscle in the rats during acute asthma attack and compare the effect among the two pairs of acupoints and the acupoints combination. METHODS: Forty SD male rats with SPF grade were randomly divided into a blank group, a model group, a pair-point A group (acupuncture at "Feishu" [BL 13] and "Dingchuan" [EX-B 1]), a pair-point B group (acupuncture at "Kongzui" [LU 6] and "Yuji" [LU 10]) and a point combination group (acupuncture at "Feishu" [BL 13] , "Dingchuan" [EX-B 1], "Kongzui" [LU 6] and "Yuji" [LU 10]), with 8 rats in each group. Except the rats in the blank group, the model of acute asthma attack was induced by ovalbumin (OVA) combined with aluminum hydroxide gel in the rest groups. Started on the 15th day of modeling, except in the blank group and the model group, acupuncture was delivered in the other groups, 30 min in each intervention, once daily, for 14 days. In each group, the latent period of asthma inducing was measured; the lung resistance (LR) and dynamic lung compliance (Cdyn) were determined using lung function detector; the levels of endothelin-1 (ET-1), tumor necrosis factor-α (TNF-α), cyclic adenosine monophosphate (cAMP) and cyclic guanosine monophosphate (cGMP) in serum and bronchoalveolar lavage fluid (BALF) were measured by ELISA; with Masson staining and electron microscopy adopted, the morphology and ultrastructure of airway smooth muscle of the rats were observed; the mRNA and protein expressions of ET-1 and beta-2 adrenergic receptor (ß2-AR) were detected by quantitative real-time fluorescence and Western blot, respectively. RESULTS: Compared with the blank group, the latent period of asthma inducing was shortened (P<0.05), RL increased and Cdyn decreased (P<0.05) with the different concentrations of methacholine (0.025 mg/kg, 0.05 mg/kg, 0.1 mg/kg, 0.2 mg/kg) in the model group. In the pair-point A group, the pair-point B group and the point combination group, the latent period of asthma inducing was prolonged (P<0.05), RL decreased and Cdyn increased (P<0.05) with different concentrations of methacholine when compared with those in the model group; and the latent period of asthma inducing in the point combination group was longer than that in the pair-point A group (P<0.05). Compared with the blank group, the levels of ET-1, TNF-α and cGMP in the serum and BALF were elevated (P<0.05), and those of cAMP reduced (P<0.05) in the model group. The levels of ET-1, TNF-α and cGMP in the serum and BALF were reduced (P<0.05), and those of cAMP elevated (P<0.05) in the pair-point A group, the pair-point B group and the point combination group when compared with those in the model group. In the blank group, the lung tissue was normal structurally. In the model group, the collagen fibers were proliferated increasingly, the smooth muscle was thickened, the mitochondria were swollen, and their cristae disrupted and reduced massively. In the pair-point B group, the collagen fibers were proliferated, the smooth muscle was thicker compared with that in the blank group, the mitochondria were mildly swollen and their cristae disrupted partially. In the pair-point A group and the point combination group, the lung tissue changes were obviously alleviated in comparison with the model group, the mitochondria were slightly swollen and their cristae disrupted occasionally. Compared with the blank group, the mRNA and protein expression of ET-1 increased and that of ß2-AR decreased in the lung tissue of the model group (P<0.05). In the pair-point A group, the pair-point B group and the point combination group, the mRNA and protein expression of ET-1 was reduced and that of ß2-AR elevated in the lung tissue when compared with those in the model group (P<0.05). In comparison with the pair-point A group, the mRNA expression of ß2-AR was elevated in the point combination group (P<0.05). When compared with the pair-point B group, the mRNA expression of ß2-AR increased, the protein expression of ET-1 decreased (P<0.05) in the point combination group. CONCLUSIONS: Acupuncture at "Feishu" (BL 13) and "Dingchuan" (EX-B 1), "Kongzui" (LU 6) and "Yuji" (LU 10), two pairs of acupoints relieves the airway smooth muscle spasm in the rats during acute asthma attack, which may be related to inhibiting the mRNA and protein expression of ET-1 to reduce the excretion of ET-1 and TNF-α; while enhancing the mRNA and protein expression of ß2-AR to balance the levels of cAMP and cGMP. The effect is optimal when acupuncture is delivered at two pairs of acupoints simultaneously.

Effects of increasing sensitizing doses of ovalbumin on airway hyperresponsiveness in asthmatic mice.

BACKGROUND: The dosage of ovalbumin (OVA) during the sensitization stage is considered a crucial factor in the development of airway hyperresponsiveness (AHR). However, the inconsistent dosages of sensitizing OVA used in current studies and the lack of research on their impact on AHR are notable limitations. METHODS: We examined the impact of increasing sensitizing doses of OVA in a murine asthma model, which entailed initial sensitization with OVA followed by repeated exposure to OVA aerosols. BALB/c mice were primed with doses of OVA (0, 10, 20, 50, and 100 µg) plus 1 mg Alum on Days 0 and 7, and were challenged with OVA aerosols (10 mg/mL for 30 min) between Days 14 and 17. Antigen-induced AHR to methacholine (MCh), as well as histological changes, eosinophilic infiltration, and epithelial injury were assessed. RESULTS: The result indicated that there are striking OVA dose-related differences in antigen-induced AHR to MCh. The most intense antigen-induced AHR to MCh was observed with sensitization at 50 µg, while weaker responses were seen at 10, 20, and 100 µg. Meanwhile, there was a significant increase in eosinophil count with sensitization at 50 µg. The changes of AHR were correlated with total cells count, lymphocytes count, eosinophils count, and basophils count in bronchoalveolar lavage fluid; however, it did not correlate with histological changes such as cellular infiltration into bronchovascular bundles and goblet cell hyperplasia of the bronchial epithelium. CONCLUSION: Overall, this study demonstrated that sensitization with 50 µg of OVA resulted in the most significant AHR compared to other dosages. These findings may offer valuable insights for future research on mouse asthma modeling protocols.

Pulmonary Function Tests in Thunderstorm-associated Respiratory Symptoms: A Cross-sectional Study.

Background: Epidemic thunderstorm asthma is an observed increase in cases of acute bronchospasm following thunderstorms. This study aimed to compare the frequency of obstructive airway disease or bronchial hyperresponsiveness in subjects with thunderstorm-associated respiratory symptoms with subjects with similar symptoms presented at other times. Methods: A cross-sectional study from June to November of 2013 was conducted on subjects with thunderstorm-associated respiratory symptoms living in Ahvaz City, Iran. Thunderstorm-associated subjects were presented with asthmatic symptoms in thunderstorms, and other patients presented with similar symptoms at other times. Baseline spirometry was performed on patients to examine the presence of obstructive airway disease. In all patients with normal spirometry, a provocation test was applied. A comparison of qualitative and quantitative variables was made using the Chi-square and independent t test, respectively. All analyses were carried out using SPSS Statistics Version 22. A P value less than 0.05 was considered statistically significant. Results: Out of 584 subjects, 300 and 284 participants were in thunderstorm-associated and non-thunderstorm-associated groups, respectively. After the final analysis, 87 (30.6%) and 89 (33.3%) of the thunderstorm-associated subjects and non-thunderstorm-associated group, respectively, had pieces of evidence of airflow limitation (P=0.27). Among the patients with normal spirometry, 161 (81.72%) of the thunderstorm-associated patients and 100 (56.17%) patients of the non-thunderstorm-associated symptoms group had a positive methacholine challenge test result (P<0.001). Conclusion: Most of the patients with thunderstorm-associated respiratory symptoms had no obvious evidence of airflow limitation in spirometry.

Excessive hypercholesterolemia in pregnancy impairs rat uterine artery function via activation of Toll-like receptor 4.

Hypercholesterolemia in pregnancy is a physiological process required for normal fetal development. In contrast, excessive pregnancy-specific hypercholesterolemia increases the risk of complications, such as preeclampsia. However, the underlying mechanisms are unclear. Toll-like receptor 4 (TLR4) is a membrane receptor modulated by high cholesterol levels, leading to endothelial dysfunction; but whether excessive hypercholesterolemia in pregnancy activates TLR4 is not known. We hypothesized that a high cholesterol diet (HCD) during pregnancy increases TLR4 activity in uterine arteries, leading to uterine artery dysfunction. Sprague Dawley rats were fed a control diet (n=12) or HCD (n=12) during pregnancy (gestational day 6-20). Vascular function was assessed in main uterine arteries using wire myography (vasodilation to methacholine and vasoconstriction to phenylephrine; with and without inhibitors for mechanistic pathways) and pressure myography (biomechanical properties). Exposure to a HCD during pregnancy increased maternal blood pressure, induced proteinuria, and reduced the fetal-to-placental weight ratio for both sexes. Excessive hypercholesterolemia in pregnancy also impaired vasodilation to methacholine in uterine arteries, whereby at higher doses, methacholine caused vasoconstriction instead of vasodilation in only the HCD group, which was prevented by inhibition of TLR4 or prostaglandin H synthase 1. Endothelial nitric oxide synthase expression and nitric oxide levels were reduced in HCD compared with control dams. Vasoconstriction to phenylephrine and biomechanical properties were similar between groups. In summary, excessive hypercholesterolemia in pregnancy impairs uterine artery function, with TLR4 activation as a key mechanism. Thus, TLR4 may be a target for therapy development to prevent adverse perinatal outcomes in complicated pregnancies.

[Standard technical specifications for methacholine chloride (Methacholine) bronchial challenge test (2023)].

The methacholine challenge test (MCT) is a standard evaluation method of assessing airway hyperresponsiveness (AHR) and its severity, and has significant clinical value in the diagnosis and treatment of bronchial asthma. A consensus working group consisting of experts from the Pulmonary Function and Clinical Respiratory Physiology Committee of the Chinese Association of Chest Physicians, the Task Force for Pulmonary Function of the Chinese Thoracic Society, and the Pulmonary Function Group of Respiratory Branch of the Chinese Geriatric Society jointly developed this consensus. Based on the "Guidelines for Pulmonary Function-Bronchial Provocation Test" published in 2014, the issues encountered in its use, and recent developments, the group has updated the Standard technical specifications of methacholine chloride (methacholine) bronchial challenge test (2023). Through an extensive collection of expert opinions, literature reviews, questionnaire surveys, and multiple rounds of online and offline discussions, the consensus addressed the eleven core issues in MCT's clinical practice, including indications, contraindications, preparation of provocative agents, test procedures and methods, quality control, safety management, interpretation of results, and reporting standards. The aim was to provide clinical pulmonary function practitioners in healthcare institutions with the tools to optimize the use of this technique to guide clinical diagnosis and treatment.Summary of recommendationsQuestion 1: Who is suitable for conducting MCT? What are contraindications for performing MCT?Patients with atypical symptoms and a clinical suspicion of asthma, patients diagnosed with asthma requiring assessment of the severity of airway hyperresponsiveness, individuals with allergic rhinitis who are at risk of developing asthma, patients in need of evaluating the effectiveness of asthma treatment, individuals in occupations with high safety risks due to airway hyperresponsiveness, patients with chronic diseases prone to airway hyperresponsiveness, others requiring assessment of airway reactivity.Absolute contraindications: (1) Patients who are allergic to methacholine (MCh) or other parasympathomimetic drugs, with allergic reactions including rash, itching/swelling (especially of the face, tongue, and throat), severe dizziness, and dyspnea; (2) Patients with a history of life-threatening asthma attacks or those who have required mechanical ventilation for asthma attacks in the past three months; (3) Patients with moderate to severe impairment of baseline pulmonary function [Forced Expiratory Volume in one second (FEV1) less than 60% of the predicted value or FEV1<1.0 L]; (4) Severe urticaria; (5) Other situations inappropriate for forced vital capacity (FVC) measurement, such as myocardial infarction or stroke in the past three months, poorly controlled hypertension, aortic aneurysm, recent eye surgery, or increased intracranial pressure.Relative contraindications: (1) Moderate or more severe impairment of baseline lung function (FEV1%pred<70%), but individuals with FEV1%pred>60% may still be considered for MCT with strict observation and adequate preparation; (2) Experiencing asthma acute exacerbation; (3) Poor cooperation with baseline lung function tests that do not meet quality control requirements; (4) Recent respiratory tract infection (<4 weeks); (5) Pregnant or lactating women; (6) Patients currently using cholinesterase inhibitors (for the treatment of myasthenia gravis); (7) Patients who have previously experienced airway spasm during pulmonary function tests, with a significant decrease in FEV1 even without the inhalation of provocative.Question 2: How to prepare and store the challenge solution for MCT?Before use, the drug must be reconstituted and then diluted into various concentrations for provocation. The dilution concentration and steps for MCh vary depending on the inhalation method and provocation protocol used. It is important to follow specific steps. Typically, a specified amount of diluent is added to the methacholine reagent bottle for reconstitution, and the mixture is shaken until the solution becomes clear. The diluent is usually physiological saline, but saline with phenol (0.4%) can also be used. Phenol can reduce the possibility of bacterial contamination, and its presence does not interfere with the provocation test. After reconstitution, other concentrations of MCh solution are prepared using the same diluent, following the dilution steps, and then stored separately in sterile containers. Preparers should carefully verify and label the concentration and preparation time of the solution and complete a preparation record form. The reconstituted and diluted MCh solution is ready for immediate use without the need for freezing. It can be stored for two weeks if refrigerated (2-8 ℃). The reconstituted solution should not be stored directly in the nebulizer reservoir to prevent crystallization from blocking the capillary opening and affecting aerosol output. The temperature of the solution can affect the production of the nebulizer and cause airway spasms in the subject upon inhaling cold droplets. Thus, refrigerated solutions should be brought to room temperature before use.Question 3: What preparation is required for subjects prior to MCT?(1) Detailed medical history inquiry and exclusion of contraindications.(2) Inquiring about factors and medications that may affect airway reactivity and assessing compliance with medication washout requirements: When the goal is to evaluate the effectiveness of asthma treatment, bronchodilators other than those used for asthma treatment do not need to be discontinued. Antihistamines and cromolyn have no effect on MCT responses, and the effects of a single dose of inhaled corticosteroids and leukotriene modifiers are minimal, thus not requiring cessation before the test. For patients routinely using corticosteroids, whether to discontinue the medication depends on the objective of the test: if assisting in the diagnosis of asthma, differential diagnosis, aiding in step-down therapy for asthma, or exploring the effect of discontinuing anti-inflammatory treatment, corticosteroids should be stopped before the provocation test; if the patient is already diagnosed with asthma and the objective is to observe the level of airway reactivity under controlled medication conditions, then discontinuation is not necessary. Medications such as IgE monoclonal antibodies, IL-4Rα monoclonal antibodies, traditional Chinese medicine, and ethnic medicines may interfere with test results, and clinicians should decide whether to discontinue these based on the specific circumstances.(3) Explaining the test procedure and potential adverse reactions, and obtaining informed consent if necessary.Question 4: What are the methods of the MCT? And which ones are recommended in current clinical practice?Commonly used methods for MCT in clinical practice include the quantitative nebulization method (APS method), Forced Oscillalion method (Astograph method), 2-minute tidal breathing method (Cockcroft method), hand-held quantitative nebulization method (Yan method), and 5-breath method (Chai 5-breath method). The APS method allows for precise dosing of inhaled Methacholine, ensuring accurate and reliable results. The Astograph method, which uses respiratory resistance as an assessment indicator, is easy for subjects to perform and is the simplest operation. These two methods are currently the most commonly used clinical practice in China.Question 5: What are the steps involved in MCT?The MCT consists of the following four steps:(1) Baseline lung function test: After a 15-minute rest period, the subjects assumes a seated position and wear a nose clip for the measurement of pulmonary function indicators [such as FEV1 or respiratory resistance (Rrs)]. FEV1 should be measured at least three times according to spirometer quality control standards, ensuring that the best two measurements differ by less than 150 ml and recording the highest value as the baseline. Usually, if FEV1%pred is below 70%, proceeding with the challenge test is not suitable, and a bronchodilation test should be considered. However, if clinical assessment of airway reactivity is necessary and FEV1%pred is between 60% and 70%, the provocation test may still be conducted under close observation, ensuring the subject's safety. If FEV1%pred is below 60%, it is an absolute contraindication for MCT.(2) Inhalation of diluent and repeat lung function test for control values: the diluent, serving as a control for the inhaled MCh, usually does not significantly impact the subject's lung function. the higher one between baseline value and the post-dilution FEV1 is used as the reference for calculating the rate of FEV1 decline. If post-inhalation FEV1 decreases, there are usually three scenarios: ①If FEV1 decreases by less than 10% compared to the baseline, the test can proceed, continue the test and administer the first dose of MCh. ②If the FEV1 decreases by≥10% and<20%, indicating a heightened airway reactivity to the diluent, proceed with the lowest concentration (dose) of the provoking if FEV1%pred has not yet reached the contraindication criteria for the MCT. if FEV1%pred<60% and the risk of continuing the challenge test is considerable, it is advisable to switch to a bronchodilation test and indicate the change in the test results report. ③If FEV1 decreases by≥20%, it can be directly classified as a positive challenge test, and the test should be discontinued, with bronchodilators administered to alleviate airway obstruction.(3) Inhalation of MCh and repeat lung function test to assess decline: prepare a series of MCh concentrations, starting from the lowest and gradually increasing the inhaled concentration (dose) using different methods. Perform pulmonaryfunction tests at 30 seconds and 90 seconds after completing nebulization, with the number of measurements limited to 3-4 times. A complete Forced Vital Capacity (FVC) measurement is unnecessary during testing; only an acceptable FEV1 measurement is required. The interval between two consecutive concentrations (doses) generally should not exceed 3 minutes. If FEV1 declines by≥10% compared to the control value, reduce the increment of methacholine concentration (dose) and adjust the inhalation protocol accordingly. If FEV1 declines by≥20% or more compared to the control value or if the maximum concentration (amount) has been inhaled, the test should be stopped. After inhaling the MCh, close observation of the subject's response is necessary. If necessary, monitor blood oxygen saturation and auscultate lung breath sounds. The test should be promptly discontinued in case of noticeable clinical symptoms or signs.(4) Inhalation of bronchodilator and repeat lung function test to assess recovery: when the bronchial challenge test shows a positive response (FEV1 decline≥20%) or suspiciously positive, the subject should receive inhaled rapid-acting bronchodilators, such as short-acting beta-agonists (SABA) or short-acting muscarinic antagonists (SAMA). Suppose the subject exhibits obvious symptoms of breathlessness, wheezing, or typical asthma manifestations, and wheezing is audible in the lungs, even if the positive criteria are not met. In that case, the challenge test should be immediately stopped, and rapid-acting bronchodilators should be administered. Taking salbutamol as an example, inhale 200-400 µg (100 µg per puff, 2-4 puffs, as determined by the physician based on the subject's condition). Reassess pulmonary function after 5-10 minutes. If FEV1 recovers to within 10% of the baseline value, the test can be concluded. However, if there is no noticeable improvement (FEV1 decline still≥10%), record the symptoms and signs and repeat the bronchodilation procedure as mentioned earlier. Alternatively, add Ipratropium bromide (SAMA) or further administer nebulized bronchodilators and corticosteroids for intensified treatment while keeping the subject under observation until FEV1 recovers to within 90% of the baseline value before allowing the subject to leave.Question 6: What are the quality control requirements for the APS and Astograph MCT equipment?(1) APS Method Equipment Quality Control: The APS method for MCT uses a nebulizing inhalation device that requires standardized flowmeters, compressed air power source pressure and flow, and nebulizer aerosol output. Specific quality control methods are as follows:a. Flow and volume calibration of the quantitative nebulization device: Connect the flowmeter, an empty nebulization chamber, and a nebulization filter in sequence, attaching the compressed air source to the bottom of the chamber to ensure airtight connections. Then, attach a 3 L calibration syringe to the subject's breathing interface and simulate the flow during nebulization (typically low flow:<2 L/s) to calibrate the flow and volume. If calibration results exceed the acceptable range of the device's technical standards, investigate and address potential issues such as air leaks or increased resistance due to a damp filter, then recalibrate. Cleaning the flowmeter or replacing the filter can change the resistance in the breathing circuit, requiring re-calibration of the flow.b. Testing the compressed air power source: Regularly test the device, connecting the components as mentioned above. Then, block the opening of the nebulization device with a stopper or hand, start the compressed air power source, and test its pressure and flow. If the test results do not meet the technical standards, professional maintenance of the equipment may be required.c. Verification of aerosol output of the nebulization chamber: Regularly verify all nebulization chambers used in provocation tests. Steps include adding a certain amount of saline to the chamber, weighing and recording the chamber's weight (including saline), connecting the nebulizer to the quantitative nebulization device, setting the nebulization time, starting nebulization, then weighing and recording the post-nebulization weight. Calculate the unit time aerosol output using the formula [(weight before nebulization-weight after nebulization)/nebulization time]. Finally, set the nebulization plan for the provocation test based on the aerosol output, considering the MCh concentration, single inhalation nebulization duration, number of nebulization, and cumulative dose to ensure precise dosing of the inhaled MCh.(2) Astograph method equipment quality control: Astograph method equipment for MCT consists of a respiratory resistance monitoring device and a nebulization medication device. Perform zero-point calibration, volume calibration, impedance verification, and nebulization chamber checks daily before tests to ensure the resistance measurement system and nebulization system function properly. Calibration is needed every time the equipment is turned on, and more frequently if there are significant changes in environmental conditions.a. Zero-point calibration: Perform zero-point calibration before testing each subject. Ensure the nebulization chamber is properly installed and plugged with no air leaks.b. Volume calibration: Use a 3 L calibration syringe to calibrate the flow sensor at a low flow rate (approximately 1 L/s).c. Resistance verification: Connect low impedance tubes (1.9-2.2 cmH2O·L-1·s-1) and high impedance tubes (10.2-10.7 cmH2O·L-1·s-1) to the device interface for verification.d. Bypass check: Start the bypass check and record the bypass value; a value>150 ml/s is normal.e. Nebulization chamber check: Check each of the 12 nebulization chambers daily, especially those containing bronchodilators, to ensure normal spraying. The software can control each nebulization chamber to produce spray automatically for a preset duration (e.g., 2 seconds). Observe the formation of water droplets on the chamber walls, indicating normal spraying. If no nebulization occurs, check for incorrect connections or blockages.Question 7: How to set up and select the APS method in MCT?The software program of the aerosol provocation system in the quantitative nebulization method can independently set the nebulizer output, concentration of the methacholine agent, administration time, and number of administrations and combine these parameters to create the challenge test process. In principle, the concentration of the methacholine agent should increase from low to high, and the dose should increase from small to large. According to the standard, a 2-fold or 4-fold incremental challenge process is generally used. In clinical practice, the dose can be simplified for subjects with good baseline lung function and no history of wheezing, such as using a recommended 2-concentration, 5-step method (25 and 50 g/L) and (6.25 and 25 g/L). Suppose FEV1 decreases by more than 10% compared to the baseline during the test to ensure subject safety. In that case, the incremental dose of the methacholine agent can be reduced, and the inhalation program can be adjusted appropriately. If the subject's baseline lung function declines or has recent daytime or nighttime symptoms such as wheezing or chest tightness, a low concentration, low dose incremental process should be selected.Question 8: What are the precautions for the operation process of the Astograph method in MCT?(1) Test equipment: The Astograph method utilizes the forced oscillation technique, applying a sinusoidal oscillating pressure at the mouthpiece during calm breathing. Subjects inhale nebulized MCh of increasing concentrations while continuous monitoring of respiratory resistance (Rrs) plots the changes, assessing airway reactivity and sensitivity. The nebulization system employs jet nebulization technology, comprising a compressed air pump and 12 nebulization cups. The first cup contains saline, cups 2 to 11 contain increasing concentrations of MCh, and the 12th cup contains a bronchodilator solution.(2) Provocation process: Prepare 10 solutions of MCh provocant with gradually increasing concentrations.(3) Operational procedure: The oscillation frequency is usually set to 3 Hz (7 Hz for children) during the test. The subject breathes calmly, inhales saline solution nebulized first, and records the baseline resistance value (if the subject's baseline resistance value is higher than 10 cmH2O·L-1·s-1, the challenge test should not be performed). Then, the subject gradually inhales increasing concentrations of methacholine solution. Each concentration solution is inhaled for 1 minute, and the nebulization system automatically switches to the next concentration for inhalation according to the set time. Each nebulizer cup contains 2-3 ml of solution, the output is 0.15 ml/min, and each concentration is inhaled for 1 minute. The dose-response curve is recorded automatically. Subjects should breathe tidally during the test, avoiding deep breaths and swallowing. Continue until Rrs significantly rises to more than double the baseline value, or if the subject experiences notable respiratory symptoms or other discomfort, such as wheezing in both lungs upon auscultation. At this point, the inhalation of the provocant should be stopped and the subject switchs to inhaling a bronchodilator until Rrs returns to pre-provocation levels. If there is no significant increase in Rrs, stop the test after inhaling the highest concentration of MCh.Question 9: How to interpret the results of the MCT?The method chosen for the MCT determines the specific indicators used for interpretation. The most commonly used indicator is FEV1, although other parameters such as Peak Expiratory Flow (PEF) and Rrs can also be used to assess airway hyperresponsiveness.Qualitative judgment: The test results can be classified as positive, suspiciously positive, or negative, based on a combination of the judgment indicators and changes in the subject's symptoms. If FEV1 decreases by≥20% compared to the baseline value after not completely inhaling at the highest concentration, the result can be judged as positive for Methacholine bronchial challenge test. If the patient has obvious wheezing symptoms or wheezing is heard in both lungs, but the challenge test does not meet the positive criteria (the highest dose/concentration has been inhaled), and FEV1 decreases between 10% and 20% compared to the baseline level, the result can also be judged as positive. If FEV1 decreases between 15% and 20% compared to the baseline value without dyspnea or wheezing attacks, the result can be judged as suspiciously positive. Astograph method: If Rrs rises to 2 times or more of the baseline resistance before reaching the highest inhalation concentration, or if the subject's lungs have wheezing and severe coughing, the challenge test can be judged as positive. Regardless of the result of the Methacholine bronchial challenge test, factors that affect airway reactivity, such as drugs, seasons, climate, diurnal variations, and respiratory tract infections, should be excluded.Quantitative judgment: When using the APS method, the severity of airway hyperresponsiveness can be graded based on PD20-FEV1 or PC20-FEV1. Existing evidence suggests that PD20 shows good consistency when different nebulizers, inhalation times, and starting concentrations of MCh are used for bronchial provocation tests, whereas there is more variability with PC20. Therefore, PD20 is often recommended as the quantitative assessment indicator. The threshold value for PD20 with the APS method is 2.5 mg.The Astograph method often uses the minimum cumulative dose (Dmin value, in Units) to reflect airway sensitivity. Dmin is the minimum cumulative dose of MCh required to produce a linear increase in Rrs. A dose of 1 g/L of the drug concentration inhaled for 1-minute equals 1 unit. It's important to note that with the continuous increase in inhaled provocant concentration, the concept of cumulative dose in the Astograph method should not be directly compared to other methods. Most asthma patients have a Dmin<10 Units, according to Japanese guidelines. The Astograph method, having been used in China for over twenty years, suggests a high likelihood of asthma when Dmin≤6 Units, with a smaller Dmin value indicating a higher probability. When Dmin is between 6 and 10 Units, further differential diagnosis is advised to ascertain whether the condition is asthma.Precautions:A negative methacholine challenge test (MCT) does not entirely rule out asthma. The test may yield negative results due to the following reasons:(1) Prior use of medications that reduce airway responsiveness, such as ß2 agonists, anticholinergic drugs, antihistamines, leukotriene receptor antagonists, theophylline, corticosteroids, etc., and insufficient washout time.(2) Failure to meet quality control standards in terms of pressure, flow rate, particle size, and nebulization volume of the aerosol delivery device.(3) Poor subject cooperation leads to inadequate inhalation of the methacholine agent.(4) Some exercise-induced asthma patients may not be sensitive to direct bronchial challenge tests like the Methacholine challenge and require indirect bronchial challenge tests such as hyperventilation, cold air, or exercise challenge to induce a positive response.(5) A few cases of occupational asthma may only react to specific antigens or sensitizing agents, requiring specific allergen exposure to elicit a positive response.A positive MCT does not necessarily indicate asthma. Other conditions can also present with airway hyperresponsiveness and yield positive results in the challenge test, such as allergic rhinitis, chronic bronchitis, viral upper respiratory infections, allergic alveolitis, tropical eosinophilia, cystic fibrosis, sarcoidosis, bronchiectasis, acute respiratory distress syndrome, post-cardiopulmonary transplant, congestive heart failure, and more. Furthermore, factors like smoking, air pollution, or exercise before the test may also result in a positive bronchial challenge test.Question 10: What are the standardized requirements for the MCT report?The report should include: (1) basic information about the subject; (2) examination data and graphics: present baseline data, measurement data after the last two challenge doses or concentrations in tabular form, and the percentage of actual measured values compared to the baseline; flow-volume curve and volume-time curve before and after challenge test; dose-response curve: showing the threshold for positive challenge; (3) opinions and conclusions of the report: including the operator's opinions, quality rating of the examination, and review opinions of the reviewing physician.Question 11: What are the adverse reactions and safety measures of MCT?During the MCT, the subject needs to repeatedly breathe forcefully and inhale bronchial challenge agents, which may induce or exacerbate bronchospasm and contraction and may even cause life-threatening situations. Medical staff should be fully aware of the indications, contraindications, medication use procedures, and emergency response plans for the MCT.

Antenatal Endotoxin Induces Dysanapsis in Experimental Bronchopulmonary Dysplasia.

Bronchopulmonary dysplasia (BPD), the chronic lung disease of prematurity, is characterized by impaired lung development with sustained functional abnormalities due to alterations of airways and the distal lung. Although clinical studies have shown striking associations between antenatal stress and BPD, little is known about the underlying pathogenetic mechanisms. Whether dysanapsis, the concept of discordant growth of the airways and parenchyma, contributes to late respiratory disease as a result of antenatal stress is unknown. We hypothesized that antenatal endotoxin (ETX) impairs juvenile lung function as a result of altered central airway and distal lung structure, suggesting the presence of dysanapsis in this preclinical BPD model. Fetal rats were exposed to intraamniotic ETX (10 µg) or saline solution (control) 2 days before term. We performed extensive structural and functional evaluation of the proximal airways and distal lung in 2-week-old rats. Distal lung structure was quantified by stereology. Conducting airway diameters were measured using micro-computed tomography. Lung function was assessed during invasive ventilation to quantify baseline mechanics, response to methacholine challenge, and spirometry. ETX-exposed pups exhibited distal lung simplification, decreased alveolar surface area, and decreased parenchyma-airway attachments. ETX-exposed pups exhibited decreased tracheal and second- and third-generation airway diameters. ETX increased respiratory system resistance and decreased lung compliance at baseline. Only Newtonian resistance, specific to large airways, exhibited increased methacholine reactivity in ETX-exposed pups compared with controls. ETX-exposed pups had a decreased ratio of FEV in 0.1 second to FVC and a normal FEV in 0.1 second, paralleling the clinical definition of dysanapsis. Antenatal ETX causes abnormalities of the central airways and distal lung growth, suggesting that dysanapsis contributes to abnormal lung function in juvenile rats.

High-fat Western diet alters crystalline silica-induced airway epithelium ion transport but not airway smooth muscle reactivity.

OBJECTIVES: Silicosis is an irreversible occupational lung disease resulting from crystalline silica inhalation. Previously, we discovered that Western diet (HFWD)-consumption increases susceptibility to silica-induced pulmonary inflammation and fibrosis. This study investigated the potential of HFWD to alter silica-induced effects on airway epithelial ion transport and smooth muscle reactivity. METHODS: Six-week-old male F344 rats were fed a HFWD or standard rat chow (STD) and exposed to silica (Min-U-Sil 5®, 15 mg/m3, 6 h/day, 5 days/week, for 39 d) or filtered air. Experimental endpoints were measured at 0, 4, and 8 weeks post-exposure. Transepithelial potential difference (Vt), short-circuit current (ISC) and transepithelial resistance (Rt) were measured in tracheal segments and ion transport inhibitors [amiloride, Na+ channel blocker; NPPB; Cl- channel blocker; ouabain, Na+, K+-pump blocker] identified changes in ion transport pathways. Changes in airway smooth muscle reactivity to methacholine (MCh) were investigated in the isolated perfused trachea preparation. RESULTS: Silica reduced basal ISC at 4 weeks and HFWD reduced the ISC response to amiloride at 0 week compared to air control. HFWD + silica exposure induced changes in ion transport 0 and 4 weeks after treatment compared to silica or HFWD treatments alone. No effects on airway smooth muscle reactivity to MCh were observed.

The role of bronchial challenge test in guiding therapy in preschool children with atypical recurrent respiratory symptoms.

OBJECTIVE: This retrospective observational cohort study aimed to assess the real-life application of bronchial challenge test (BCT) in the management of preschool children presenting with atypical recurrent respiratory symptoms (ARRS). METHODS: We included children aged 0.5-6 years referred to a pediatric-pulmonology clinic who underwent BCT using methacholine or adenosine between 2012 and 2018 due to ARRS. BCT was considered positive based on spirometry results and/or wheezing, desaturation, and tachypnea reactions. We collected data on demographics, BCT results, pre-BCT and post-BCT treatment changes, and 3-6 months post-BCT compliance and symptom control. The primary outcome measure was the change in treatment post-BCT (step-up or step-down). RESULTS: A total of 228 children (55% males) with a mean age of 4.2 ± 0.6 years underwent BCT (52% adenosine-BCT, 48% methacholine-BCT). Children referred for methacholine were significantly younger compared with adenosine (3.6 ± 1.2 vs. 4.2 ± 1.2 years, p < .01). Methacholine and adenosine BCTs were positive in 95% and 61%, respectively. Overall, changes in management were observed in 122 (53.5%) children following BCT, with 83 (36.4%) being stepped up and 37 (17%) being stepped down. Significantly more children in the methacholine group were stepped up compared with the adenosine group (46% vs. 28%, p = .004). During the follow-up assessment, we observed a clinical improvement in 119/162 (73.4%) of the children, with nearly 87% being compliant. CONCLUSION: This study demonstrates the importance of BCT in the management of preschool children presenting to pediatric pulmonary units with ARRS. The change in treatment and subsequent clinical improvement observed highlight the added value of BCT to the pulmonologist.

Functional role of glial-derived neurotrophic factor in a mixed allergen murine model of asthma.

Our previous study showed that glial-derived neurotrophic factor (GDNF) expression is upregulated in asthmatic human lungs, and GDNF regulates calcium responses through its receptor GDNF family receptor α1 (GFRα1) and RET receptor in human airway smooth muscle (ASM) cells. In this study, we tested the hypothesis that airway GDNF contributes to airway hyperreactivity (AHR) and remodeling using a mixed allergen mouse model. Adult C57BL/6J mice were intranasally exposed to mixed allergens (ovalbumin, Aspergillus, Alternaria, house dust mite) over 4 wk with concurrent exposure to recombinant GDNF, or extracellular GDNF chelator GFRα1-Fc. Airway resistance and compliance to methacholine were assessed using FlexiVent. Lung expression of GDNF, GFRα1, RET, collagen, and fibronectin was examined by RT-PCR and histology staining. Allergen exposure increased GDNF expression in bronchial airways including ASM and epithelium. Laser capture microdissection of the ASM layer showed increased mRNA for GDNF, GFRα1, and RET in allergen-treated mice. Allergen exposure increased protein expression of GDNF and RET, but not GFRα1, in ASM. Intranasal administration of GDNF enhanced baseline responses to methacholine but did not consistently potentiate allergen effects. GDNF also induced airway thickening, and collagen deposition in bronchial airways. Chelation of GDNF by GFRα1-Fc attenuated allergen-induced AHR and particularly remodeling. These data suggest that locally produced GDNF, potentially derived from epithelium and/or ASM, contributes to AHR and remodeling relevant to asthma.NEW & NOTEWORTHY Local production of growth factors within the airway with autocrine/paracrine effects can promote features of asthma. Here, we show that glial-derived neurotrophic factor (GDNF) is a procontractile and proremodeling factor that contributes to allergen-induced airway hyperreactivity and tissue remodeling in a mouse model of asthma. Blocking GDNF signaling attenuates allergen-induced airway hyperreactivity and remodeling, suggesting a novel approach to alleviating structural and functional changes in the asthmatic airway.

The link between early childhood lower airway symptoms, airway hyperresponsiveness, and school-age lung function.

BACKGROUND: The role of early airway hyperresponsiveness (AHR) in the lung function of school-age children is currently unclear. OBJECTIVE: To conduct a prospective follow-up study of lung function in schoolchildren with a history of lower airway symptoms and AHR to methacholine in early childhood and to compare the findings to schoolchildren with no previous or current lung diseases. We also explored symptoms and markers of type 2 inflammation. METHODS: In 2004 to 2011, data on atopic markers, lung function, and AHR to methacholine were obtained from 193 symptomatic children under 3 years old. In 2016 to 2018, a follow-up sample of 84 children (median age, 11 years; IQR, 11-12) underwent measurements of atopic parameters, lung function, and AHR to methacholine. Moreover, in 2017 to 2018, 40 controls (median age, 11 years; IQR, 9-12) participated in the study. RESULTS: Schoolchildren with early childhood lower airway symptoms and increased AHR had more frequent blood eosinophilia than their peers without increased AHR and lower prebronchodilator forced expiratory volume in 1 second (FEV1) and FEV1/forced vital capacity Z-scores than those without increased AHR and controls. Post-bronchodilator values were not significantly different between the two AHR groups. Atopy in early childhood (defined as atopic eczema and at least 1 positive skin prick test result) was associated with subsequent lung function and atopic markers, but not AHR. CONCLUSION: In symptomatic young children, increased AHR was associated with subsequent obstructive lung function, which appeared reversible by bronchodilation, and blood eosinophilia, indicative of type 2 inflammation.

Anticipating undiagnosed asthma in symptomatic adults with normal pre- and post-bronchodilator spirometry: a decision tool for bronchial challenge testing.

BACKGROUND: Some patients with asthma demonstrate normal spirometry and remain undiagnosed without further testing. OBJECTIVE: To determine clinical predictors of asthma in symptomatic adults with normal spirometry, and to generate a tool to help clinicians decide who should undergo bronchial challenge testing (BCT). METHODS: Using random-digit dialling and population-based case-finding, we recruited adults from the community with respiratory symptoms and no previous history of diagnosed lung disease. Participants with normal pre- and post-bronchodilator spirometry subsequently underwent BCT. Asthma was diagnosed in those with symptoms and a methacholine provocative concentration (PC20) of < 8 mg/ml. Sputum and blood eosinophils, and exhaled nitric oxide were measured. Univariate analyses identified potentially predictive variables, which were then used to construct a multivariable logistic regression model to predict asthma. Model sensitivity, specificity, and area under the receiver operating curve (AUC) were calculated. RESULTS: Of 132 symptomatic individuals with normal spirometry, 34 (26%) had asthma. Of those ultimately diagnosed with asthma, 33 (97%) answered 'yes' to a question asking whether they experienced cough, chest tightness or wheezing provoked by exercise or cold air. Other univariate predictors of asthma included female sex, pre-bronchodilator FEV1 percentage predicted, and percent positive change in FEV1 post bronchodilator. A multivariable model containing these predictive variables yielded an AUC of 0.82 (95% CI: 0.72-0.91), a sensitivity of 82%, and a specificity of 66%. The model was used to construct a nomogram to advise clinicians which patients should be prioritized for BCT. CONCLUSIONS: Four readily available patient characteristics demonstrated a high sensitivity and AUC for predicting undiagnosed asthma in symptomatic adults with normal pre- and post-bronchodilator spirometry. These characteristics can potentially help clinicians to decide which individuals with normal spirometry should be investigated with bronchial challenge testing. However, further prospective validation of our decision tool is required.

Amitriptyline inhibits bronchoconstriction and directly promotes dilatation of the airways.

INTRODUCTION: The standard therapy for bronchial asthma consists of combinations of acute (short-acting ß2-sympathomimetics) and, depending on the severity of disease, additional long-term treatment (including inhaled glucocorticoids, long-acting ß2-sympathomimetics, anticholinergics, anti-IL-4R antibodies). The antidepressant amitriptyline has been identified as a relevant down-regulator of immunological TH2-phenotype in asthma, acting-at least partially-through inhibition of acid sphingomyelinase (ASM), an enzyme involved in sphingolipid metabolism. Here, we investigated the non-immunological role of amitriptyline on acute bronchoconstriction, a main feature of airway hyperresponsiveness in asthmatic disease. METHODS: After stimulation of precision cut lung slices (PCLS) from mice (wildtype and ASM-knockout), rats, guinea pigs and human lungs with mediators of bronchoconstriction (endogenous and exogenous acetylcholine, methacholine, serotonin, endothelin, histamine, thromboxane-receptor agonist U46619 and leukotriene LTD4, airway area was monitored in the absence of or with rising concentrations of amitriptyline. Airway dilatation was also investigated in rat PCLS by prior contraction induced by methacholine. As bronchodilators for maximal relaxation, we used IBMX (PDE inhibitor) and salbutamol (ß2-adrenergic agonist) and compared these effects with the impact of amitriptyline treatment. Isolated perfused lungs (IPL) of wildtype mice were treated with amitriptyline, administered via the vascular system (perfusate) or intratracheally as an inhalation. To this end, amitriptyline was nebulized via pariboy in-vivo and mice were ventilated with the flexiVent setup immediately after inhalation of amitriptyline with monitoring of lung function. RESULTS: Our results show amitriptyline to be a potential inhibitor of bronchoconstriction, induced by exogenous or endogenous (EFS) acetylcholine, serotonin and histamine, in PCLS from various species. The effects of endothelin, thromboxane and leukotrienes could not be blocked. In acute bronchoconstriction, amitriptyline seems to act ASM-independent, because ASM-deficiency (Smdp1-/-) did not change the effect of acetylcholine on airway contraction. Systemic as well as inhaled amitriptyline ameliorated the resistance of IPL after acetylcholine provocation. With the flexiVent setup, we demonstrated that the acetylcholine-induced rise in central and tissue resistance was much more marked in untreated animals than in amitriptyline-treated ones. Additionally, we provide clear evidence that amitriptyline dilatates pre-contracted airways as effectively as a combination of typical bronchodilators such as IBMX and salbutamol. CONCLUSION: Amitriptyline is a drug of high potential, which inhibits acute bronchoconstriction and induces bronchodilatation in pre-contracted airways. It could be one of the first therapeutic agents in asthmatic disease to have powerful effects on the TH2-allergic phenotype and on acute airway hyperresponsiveness with bronchoconstriction, especially when inhaled.

Efficacy of levocetirizine in isolated rat tracheal smooth muscle.

Histamine receptor-1 (H1) antagonists like levocetirizine are frequently used nowadays to treat rhinitis patients who experience rhinorrhea and sneezing. The trachea may be affected by the H1 antagonist when it is used to treat nasal symptoms, either orally or through inhalation. The purpose of this study was to ascertain in vitro effects of levocetirizine on isolated tracheal smooth muscle. As a parasympathetic mimetic, methacholine (10-6 M) causes contractions in tracheal smooth muscle, which is how we tested effectiveness of levocetirizine on isolated rat tracheal smooth muscle. We also tested the drug's impact on electrically induced tracheal smooth muscle contractions. The impact of menthol (either before or after) on the contraction brought on by 10-6 M methacholine was also investigated. According to the results, the addition of levocetirizine at concentrations of 10-5 M or more caused a slight relaxation in response to methacholine's 10-6 M contraction. Levocetirizine could prevent spike contraction brought on by electrical field stimulation (EFS). As the concentration rose, it alone had a neglect effect on the trachea's basal tension. Before menthol was applied, levocetirizine might have also inhibited the function of the cold receptor. According to this study, levocetirizine might potentially impede the parasympathetic function of the trachea. If levocetirizine was used prior to menthol addition, it also reduced the function of cold receptors.

Allosteric modulator potentiates ß2AR agonist-promoted bronchoprotection in asthma models.

Asthma is a chronic inflammatory disease associated with episodic airway narrowing. Inhaled ß2-adrenergic receptor (ß2AR) agonists (ß2-agonists) promote - with limited efficacy - bronchodilation in asthma. All ß2-agonists are canonical orthosteric ligands that bind the same site as endogenous epinephrine. We recently isolated a ß2AR-selective positive allosteric modulator (PAM), compound-6 (Cmpd-6), which binds outside of the orthosteric site and modulates orthosteric ligand functions. With the emerging therapeutic potential of G-protein coupled receptor allosteric ligands, we investigated the impact of Cmpd-6 on ß2AR-mediated bronchoprotection. Consistent with our findings using human ß2ARs, Cmpd-6 allosterically potentiated ß2-agonist binding to guinea pig ß2ARs and downstream signaling of ß2ARs. In contrast, Cmpd-6 had no such effect on murine ß2ARs, which lack a crucial amino acid in the Cmpd-6 allosteric binding site. Importantly, Cmpd-6 enhanced ß2 agonist-mediated bronchoprotection against methacholine-induced bronchoconstriction in guinea pig lung slices, but - in line with the binding studies - not in mice. Moreover, Cmpd-6 robustly potentiated ß2 agonist-mediated bronchoprotection against allergen-induced airway constriction in lung slices obtained from a guinea pig model of allergic asthma. Cmpd-6 similarly enhanced ß2 agonist-mediated bronchoprotection against methacholine-induced bronchoconstriction in human lung slices. Our results highlight the potential of ß2AR-selective PAMs in the treatment of airway narrowing in asthma and other obstructive respiratory diseases.

Impact of airway challenges on cardiovascular risk in asthma - a randomized controlled trial.

BACKGROUND: People experiencing asthma exacerbations are at increased risk of cardiovascular events. To better understand the relationship between asthma exacerbations and cardiovascular risk, this randomized case-control, cross-over controlled trial assessed the immediate systemic inflammatory and vascular responses to acutely induced pulmonary inflammation and bronchoconstriction in people with asthma and controls. METHODS: Twenty-six people with asthma and 25 controls underwent three airway challenges (placebo, mannitol, and methacholine) in random order. Markers of cardiovascular risk, including serum C-reactive protein, interleukin-6, and tumor necrosis factor, endothelial function (flow-mediated dilation), microvascular function (blood-flow following reactive hyperemia), and arterial stiffness (pulse wave velocity) were evaluated at baseline and within one hour following each challenge. The systemic responses in a) asthma/control and b) positive airway challenges were analyzed. (ClinicalTrials.gov reg# NCT02630511). RESULTS: Both the mannitol and methacholine challenges resulted in clinically significant reductions in forced expiratory volume in 1 second (FEV1) in asthma (-7.6% and -17.9%, respectively). Following positive challenges, reduction in FEV1 was -27.6% for methacholine and -14.2% for mannitol. No meaningful differences in predictors of cardiovascular risk were observed between airway challenges regardless of bronchoconstrictor response. CONCLUSION: Neither acutely induced bronchoconstriction nor pulmonary inflammation and bronchoconstriction resulted in meaningful changes in systemic inflammatory or vascular function. These findings question whether the increased cardiovascular risk associated with asthma exacerbations is secondary to acute bronchoconstriction or inflammation, and suggest that other factors need to be further evaluated such as the cardiovascular impacts of short-acting inhaled beta-agonists.

Force adaptation through the intravenous route in naïve mice.

Aim of the study: Force adaptation is a process whereby the contractile capacity of the airway smooth muscle increases during a sustained contraction (aka tone). Tone also increases the response to a nebulized challenge with methacholine in vivo, presumably through force adaptation. Yet, due to its patchy pattern of deposition, nebulized methacholine often spurs small airway narrowing heterogeneity and closure, two important enhancers of the methacholine response. This raises the possibility that the potentiating effect of tone on the methacholine response is not due to force adaptation but by furthering heterogeneity and closure. Herein, methacholine was delivered homogenously through the intravenous (i.v.) route. Materials and Methods: Female and male BALB/c mice were subjected to one of two i.v. methacholine challenges, each of the same cumulative dose but starting by a 20-min period either with or without tone induced by serial i.v. boluses. Changes in respiratory mechanics were monitored throughout by oscillometry, and the response after the final dose was compared between the two challenges to assess the effect of tone. Results: For the elastance of the respiratory system (Ers), tone potentiated the methacholine response by 64 and 405% in females (37.4 ± 10.7 vs. 61.5 ± 15.1 cmH2O/mL; p = 0.01) and males (33.0 ± 14.3 vs. 166.7 ± 60.6 cmH2O/mL; p = 0.0004), respectively. For the resistance of the respiratory system (Rrs), tone potentiated the methacholine response by 129 and 225% in females (9.7 ± 3.5 vs. 22.2 ± 4.3 cmH2O·s/mL; p = 0.0003) and males (10.7 ± 3.1 vs. 34.7 ± 7.9 cmH2O·s/mL; p < 0.0001), respectively. Conclusions: As previously reported with nebulized challenges, tone increases the response to i.v. methacholine in both sexes; albeit sexual dimorphisms were obvious regarding the relative resistive versus elastic nature of this potentiation. This represents further support that tone increases the lung response to methacholine through force adaptation.

Chronic intermittent hypoxia increases airway hyperresponsiveness during house dust mites exposures in rats.

INTRODUCTION: Accumulating clinical evidence links Obstructive Sleep Apnea (OSA) with worse outcomes of asthma, but impact on airway function remains sparsely studied. We tested effects of Chronic Intermittent Hypoxia (CIH) - a hallmark of OSA - on airway hyperresponsiveness (AHR), in a rat model of chronic allergen-induced inflammation. METHODS: Brown Norway rats were exposed to six weeks of CIH or normoxia (NORM) concurrent with weekly house dust mites (HDM) or saline (SAL) challenges. At endpoint, we assessed responses to seven Methacholine (Mch) doses (0, 4, 8, 16, 32, 64, 128 mg/mL) on a FlexiVent system (Scireq). Maximal (or plateau) responses (reactivity) for total respiratory system Resistance (Rrs) and Elastance (Ers), Newtonian airway resistance (RN, a measure of central airways function) and tissue damping (G, a measure of distal airways function) were plotted. RESULTS: HDM/CIH-treated animals demonstrated the highest reactivity to Mch in Rrs and Ers compared to all other groups (HDM/NORM, SAL/CIH and SAL/NORM p < 0.05 for all comparisons, for doses 5-7 for Rrs, and for doses 4-7 for Ers). The enhanced Rrs response was due to an increase in G (doses 4-7, p < 0.05 for comparisons to all other groups), whereas RN was not affected by CIH. CONCLUSIONS: In rats chronically challenged with HDM, concurrent CIH exposure induces AHR primarily in the distal airways, which affects the respiratory system frequency-dependent elastic properties.

Sphingosine-1-phosphate induces airway smooth muscle hyperresponsiveness and proliferation.

BACKGROUND: The emerging role of sphingosine-1-phosphate (S1P) in regulating smooth muscle functions has led to the exploration of the possibility that this sphingolipid could represent a potential therapeutic target in asthma and other lung diseases. Several studies in animal surrogates have suggested a role for S1P-mediated signaling in the regulation of airway smooth muscle (ASM) contraction, airway hyperresponsiveness, and airway remodeling, but evidence from human studies is lacking. OBJECTIVE: We sought to compare the responsiveness of the airways to S1P in healthy and asthmatic individuals in vivo, in isolated human airways ex vivo, and in murine airways dissected from healthy and house dust mite (HDM)-sensitized animals. METHODS: Airway responsiveness was measured by spirometry during inhalation challenges and by wire myography in airways isolated from human and mouse lungs. Thymidine incorporation and calcium mobilization assays were used to study human ASM cell responses. RESULTS: S1P did not induce contraction of airways isolated from healthy and HDM-exposed mice, nor in human airways. Similarly, there was no airway constriction observed in healthy and asthmatic subjects in response to increasing concentrations of inhaled S1P. However, a 30-minute exposure to S1P induced a significant concentration-dependent enhancement of airway reactivity to methacholine and to histamine in murine and human airways, respectively. HDM-sensitized mice demonstrated a significant increase in methacholine responsiveness, which was not further enhanced by S1P treatment. S1P also concentration-dependently enhanced proliferation of human ASM cells, an effect mediated through S1P receptor type 2, as shown by selective antagonism and S1P receptor type 2 small-interfering RNA knockdown. CONCLUSIONS: Our data suggest that S1P released locally into the airways may be involved in the regulation of ASM hyperresponsiveness and hyperplasia, defining a novel target for future therapies.

Disposition of Work-Related Asthma in a Spanish Asthma Cohort: Comparison of Asthma Severity Between Employed and Retired Workers.

BACKGROUND: Exposure to certain agents in the workplace can trigger occupational asthma or work-exacerbated asthma, both of which come under the heading of work-related asthma (WRA). Understanding the burden that WRA represents can help in the management of these patients. OBJECTIVE: To assess the influence of occupation on asthma in real life and analyze the characteristics of patients with WRA included in an asthma cohort. METHODS: This was a prospective multicenter study of a cohort of consecutive patients with asthma. A standardized clinical history was completed. Patients were classified as having WRA or non-WRA. All patients underwent respiratory function tests, FeNO test, and methacholine challenge (methacholine concentration that causes a 20% drop in FEV1) at the beginning of the study. They were classified into two groups, depending on their employment status: employed (group 1) or unemployed (group 2). RESULTS: Of the 480 patients included in the cohort, 82 (17%) received the diagnosis of WRA. Fifty-seven patients (70%) were still working. Mean age (SD) was 46 (10.69) years in group 1 and 57 (9.91) years in group 2 (P < .0001). Significant differences were observed in adherence to treatment (64.9% in group 1 vs 88% in group 2; P = .0354) and in severe asthma exacerbations (35.7% in group 1 vs 0% in group 2; P = .0172). No significant differences were observed in the rest of the variables analyzed. CONCLUSIONS: The burden of WRA in specialized asthma units is not negligible. The absence of differences in the severity of asthma, the treatment administered, alterations in lung function, and the number of exacerbations in those working versus not working may support the idea that advice regarding changing jobs should be customized for individual patients.

Based on what parameters is safe to discontinuate inhaled corticosteroids in children with asthma?

OBJECTIVE: Remission of childhood asthma has not been widely studied. Patients in clinical remission continue to have some degree of bronchial hyperresponsiveness (BHR). The aim of this study was to investigate whether clinical parameters and lung function test are good parameters for discontinuation of inhaled corticosteroids (ICS) in asthmatic children, including patients with persistent BHR, as measured by the methacholine challenge test (MCT). METHODS: One year after discontinuation of inhaled corticosteroids (ICS), MCT was performed in a group of 40 asthmatic children to confirm or exclude BHR. In all patients, ICS treatment was discontinued based on the same parameters: symptoms, spirometry, daily PEF, and negative bronchodilator test. After achieving complete asthma control for at least 6 to 12 months, ICS treatment was stepped down and discontinued. Clinical course and spirometry were followed up after ICS discontinuation. RESULTS: Positive MCT was found in 50% of the patients. There was no statistically significant difference between the positive and negative MCT groups in age at initiation and discontinuation of ICS therapy, duration of ICS therapy, duration of stepping down period, FEV1, and PEF at the time of withdrawal of ICS and one year later. ICS treatment had to be restarted in two patients from the positive MCT group, due to recurrence of asthma symptoms. CONCLUSION: Clinical parameters, normal spirometry, daily PEF values, and a negative bronchodilator test are good parameters for discontinuing ICS treatment in asthmatic children, even in patients with persistent BHR. Children should continue to be monitored, as symptoms may recur.