Characterization of Vibrating Mesh Aerosol Generators

Kuo, Yu Mei; Chan, Wei Hsiang; Lin, Chih‐Wei; Huang, Sheng-Hsiu; Chen, Chih-Chieh

doi:10.4209/aaqr.2018.11.0436

Cited by 17 publications

(9 citation statements)

References 30 publications

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“…3 ). Aside from mesh size, the spray frequency significantly influences droplet size, where a higher vibration frequency generates smaller droplets due to more droplet production [ 38 ].…”

Section: Resultsmentioning

confidence: 99%

Development of a Spray-Dried Formulation of Peptide-DNA Nanoparticles into a Dry Powder for Pulmonary Delivery Using Factorial Design

et al. 2022

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Background Gene therapy via pulmonary delivery holds the potential to treat various lung pathologies. To date, spray drying has been the most promising method to produce inhalable powders. The present study determined the parameters required to spray dry nanoparticles (NPs) that contain the delivery peptide, termed RALA (N-WEARLARALARALARHLARALARALRACEA-C), complexed with plasmid DNA into a dry powder form designed for inhalation. Methods The spray drying process was optimised using full factorial design with 19 randomly ordered experiments based on the combination of four parameters and three centre points per block. Specifically, mannitol concentration, inlet temperature, spray rate, and spray frequency were varied to observe their effects on process yield, moisture content, a median of particle size distribution, Z-average, zeta potential, encapsulation efficiency of DNA NPs, and DNA recovery. The impact of mannitol concentration was also examined on the spray-dried NPs and evaluated via biological functionality in vitro. Results The results demonstrated that mannitol concentration was the strongest variable impacting all responses apart from encapsulation efficiency. All measured responses demonstrated a strong dependency on the experimental variables. Furthermore, spray drying with the optimal variables in combination with a low mannitol concentration (1% and 3%, w/v) produced functional RALA/pDNA NPs. Conclusion The optimal parameters have been determined to spray dry RALA/pDNA NPs into an dry powder with excellent biological functionality, which have the potential to be used for gene therapy applications via pulmonary delivery.

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“…3 ). Aside from mesh size, the spray frequency significantly influences droplet size, where a higher vibration frequency generates smaller droplets due to more droplet production [ 38 ].…”

Section: Resultsmentioning

confidence: 99%

Development of a Spray-Dried Formulation of Peptide-DNA Nanoparticles into a Dry Powder for Pulmonary Delivery Using Factorial Design

et al. 2022

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“…The holes were in the shape of a cone with a bottom diameter (reservoir side) of ~ 60 µm and top diameter (dispersing side) of ~ 10 µm. The generated droplets were expected to be in the similar micrometer scale, [15][16][17][18] and these droplets were reported to evaporate almost immediately as compared to the actuation time. 19,20 The atomizer, which was capable of atomizing ~ 11 mg/s in an open system, was then installed inside of a hollow cuboid chamber.…”

Section: Fabricationmentioning

confidence: 99%

Rapid Soft Material Actuation Through Droplet Evaporation

2021

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Soft material actuation is a promising field that can potentially solve several limitations of traditional robotic systems. These systems are composed of soft and flexible materials to achieve high degrees-of-freedom and compliance with its surroundings. One method to actuate such structures is to vaporize liquid that is embedded inside the soft material. The soft elastomers are inflated, since the generated vapor occupies a much larger volume after phase transformation. The simplest and widely used design to vaporize such liquids is by installing a heating element near the liquid. Heating the system beyond the boiling point rapidly boils the liquid and deforms the structure. However, this technique possesses several limitations, where the heating element must be in the liquid's vicinity, and boiling the liquid requires high temperatures. In addition, embedding a small amount of liquid for faster boiling prevents the use of valves to exhaust the vapor. Instead, the structure is slowly cooled until it returns to its original position. In this study, these limitations are addressed by combining heating with vibrating mesh atomization. The atomizer disperses the liquid into small droplets, which vaporize much faster as compared to simply heating the bulk liquid. Actuation through vibrating mesh atomization was first characterized and compared with other techniques. Then, the introduced method was used to demonstrate cyclic actuation, and a bistable structure was designed and fabricated to demonstrate gripping motion.

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“…Without considering the issues of cleaning and maintenance, it has been shown in a previous study (Kuo et al, 2019) that porous materials can be used for solution delivery in a VMN.…”

Section: Performance Comparison Of Feot-based and Wick-based Mhvmnmentioning

confidence: 99%

Development of an Orientation-independent Handheld Nebulizer

Huang

Lin

et al. 2021

Aerosol Air Qual. Res.

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This work aims to develop and characterize a miniaturized handheld vibrating mesh nebulizer (MHVMN) that can be operated equally well in any orientation. The MHVMN developed and tested in the present study comprises a power supply-frequency generator unit, a vibrating mesh plate, and a liquid reservoir equipped with a flat end orifice tube (FEOT) or a traditional wick for liquid delivery. Since the study focused on optimizing the dimensions of the FEOT which is a unique application of capillary force for solution delivery, the operating parameters including gap between reservoir wall and FEOT (LLR-FEOT), diameter of orifice on FEOT (Dorifice), nebulizer orientation, and aperture size were examined to investigate their effects on the performance of the MHVMN. The output rate and residual of a nebulizer were determined gravimetrically. An aerosol size spectrometer (Welas 3000) and a Micro orifice uniform deposit impactor (MOUDI) were employed to measure both aerosol concentration and mass distribution of the generated particles. The developed nebulizer was mainly evaluated with deionized water and 0.9% sodium chloride solution. The results showed that the LLR-FEOT of 0.225 mm was the optimal design because of the output rate and residual were similar for different orientations. The Dorifice needed to be larger than 0.8 mm, to guarantee the continuity of nebulization, and residual less than 4%. The FEOT-based MHVMN had significant advantage over the wick-based one, for much lower residual, which was important when the drug or solution was precious. The most significant and unique feature of the optimized MHVMN was the performance almost orientation independent. This made it ideal for aerosol medications, especially for patients lying on bed.

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Characterization of Vibrating Mesh Aerosol Generators

Cited by 17 publications

References 30 publications

Development of a Spray-Dried Formulation of Peptide-DNA Nanoparticles into a Dry Powder for Pulmonary Delivery Using Factorial Design

Development of a Spray-Dried Formulation of Peptide-DNA Nanoparticles into a Dry Powder for Pulmonary Delivery Using Factorial Design

Rapid Soft Material Actuation Through Droplet Evaporation

Development of an Orientation-independent Handheld Nebulizer

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