Pulmonary Deposition of Ultrasound Rock Salt Aerosol Inhalation Therapy

I. Research Background Respiratory diseases, such as asthma, COPD, cystic fibrosis and other chronic respiratory inflammatory diseases, are major global health problems. WHO data shows respiratory diseases are the world's second - leading cause of death, with rising incidence. These diseases, marked by chronic inflammation, airway obstruction and increased airway reactivity, severely affect patients' quality of life. Traditional treatments include inhaled corticosteroids, long - acting bronchodilators and systemic medications. While effective in symptom control and disease progression, they have limitations like systemic side - effects and low drug deposition efficiency from inhalers.

Ultrasonic rock salt aerosol inhalation therapy uses ultrasonic atomization to convert salt solution into tiny aerosol particles, with advantages like high efficiency, micro - moisture, dry aerosol properties, and physiological effects such as enhanced clearance and anti - inflammation.

It has been preliminarily applied in respiratory disease treatment, showing potential in reducing acute exacerbations and improving patients' quality of life. With technological advances and better understanding of aerosol delivery, this therapy has a promising future in respiratory disease management. Future research should focus on confirming its long - term efficacy and safety, exploring personalized applications and evaluating its role in comprehensive treatment strategies.

II. Research Objectives To clarify the process and state of ultrasonic micro - moist rock salt aerosol entering the airway, verify the advantages of the new inhalation device's effective inhalation deposition rate, and provide a new, convenient and effective inhalation technology for drug delivery.

III. Research Overview 3.1 Overall Research Design and Plan This prospective, randomized, crossover study includes two stages: in - vitro modeling and clinical verification.

3.2 Study Population 3.2.1 Inclusion Criteria

• Healthy volunteers.
• Patients with chronic airway diseases needing aerosol inhalation therapy.

3.2.2 Exclusion Criteria

• Age under 18.
• Declining study participation.
• Needing invasive ventilator support.
• Having artificial airways.
• Chronic liver/kidney dysfunction.
• Allergy to radioactive elements.

3.2.3 Withdrawal Criteria

• Patient's consent withdrawal request.
• Investigator's medical judgment for termination.

3.3 Sample Size and Grouping The study will recruit 6 healthy volunteers and 20 patients, randomly divided into Group A (ultrasonic rock salt aerosol inhalation first, then small - volume nebulization) and Group B (small - volume nebulization first, then ultrasonic rock salt aerosol inhalation).

3.4 Research Steps and Related Tests Stage 1: In - vitro Modeling Using real human upper airway and asymmetric ideal bronchial tree models, combining 3D printing and CFD simulation to study aerosol deposition rates and distributions in ultrasonic rock salt aerosol inhalation, compared with small - volume nebulizers.

• Build CFD models for upper airway particle deposition based on CT scans.
• Create CFD models for bronchial tree particle deposition up to the 17th generation.
• Validate deposition characteristics in a whole airway model.

Stage 2: Clinical Verification Using radioactive aerosols and PET/CT imaging to assess lung deposition rates.

• Collect baseline data: demographics, medical history, biochemistry, pulmonary function, etc.
• Aerosol inhalation: patients inhale aerosols in a separate room, with random order. Use 2ml Ga - 68 EDTA for inhalation.
• PET/CT imaging: after inhalation, perform low - dose CT for attenuation correction and lung ventilation PET acquisition.
• Image analysis: use Fiji software and MorphoLibJ plugin to analyze images, calculate deposition rates and concentrations.

3.5 Endpoint Criteria Primary: In - vitro model lung deposition rate, lung drug deposition rate (percentage of deposited drug in lungs relative to total inhaled dose).

Secondary: Peripheral deposition distribution of aerosol particles, residual volume of inhalation device.

IV. Adverse Event Observation

• Radioactive contamination.
• Adverse events related to ultrasonic rock salt aerosol inhalation: dry mouth, nasal burning, pain, etc.
• Nebulization - related adverse events: bronchospasm, coughing, etc.

V. Statistical Analysis 5.1 Sample Size Estimation Based on previous studies, the estimated sample size is 26.

5.2 Data Analysis Analyze data using R Project for Statistical Computing (v 3.5.2). Use Dunnett's test, Bonferroni - corrected post - hoc tests after Kruskal - Wallis ANOVA. Express results as mean ± SD. Use Spearman's correlation for variable relationships. Statistical significance is set at P < 0.05.

VI. Research Ethics The study protocol, consent forms and related materials must be approved by the ethics committee before commencement. Investigators must submit annual reports and inform the committee of any changes. Any changes must be approved before implementation, except those necessary to eliminate immediate risks to participants.