Spray-dried lactose-leucine microparticles for pulmonary delivery of antimycobacterial nanopharmaceuticals

Thiyagarajan, Durairaj; Huck, Benedikt; Nothdurft, Birgit; Koch, M.; Rudolph, David; Rutschmann, Mark; Feldmann, Claus; Hozsa, Constantin; Furch, Marcus; Besecke, Karen F W; Gieseler, R. K. H.; Loretz, Brigitta; Lehr, Claus‐Michael

doi:10.1007/s13346-021-01011-7

Cited by 24 publications

(12 citation statements)

References 38 publications

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“…The DPI formulations of CAF®01-T/D (30:70) prepared with leucine displayed non-significantly higher size and PDI with increasing concentrations of leucine. Prior studies have reported an increased particle size of liposomes after spray drying with L-leucine and lactose (Mangal et al, 2015;Thiyagarajan et al, 2021) due to aggregation in the dissolved microparticle samples (Thiyagarajan et al, 2021). In our recent study with DPI formulations of lipid-polymer hybrid nanoparticles spray-dried with a combination of trehalose, dextran and leucine, we also observed a slight increase in the particle size of nanoparticles after spray drying (Xu et al, 2022a).…”

Section: Discussionsupporting

confidence: 64%

Optimizing the design and dosing of dry powder inhaler formulations of the cationic liposome adjuvant CAF®01 for pulmonary immunization

Thakur

Cano-Garcia

et al. 2022

Front. Drug. Deliv.

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Thermostability is one of the product characteristics preferred by WHO for vaccines against respiratory infections due to ease of administration, pain minimization, and low costs. Thermostable dry powder inhaler (DPI) vaccine formulations can induce protective antibodies and T cells at the site of infection in the lungs. However, the majority of licensed human vaccines is based on liquid dosage forms, and there is no licensed mucosal adjuvants. The cationic adjuvant formulation 01 (CAF®01) is a liposome-based adjuvant system that (i) induces robust T cells and antibodies, (ii) is safe and well-tolerated in clinical trials, and (iii) induces mucosal immune responses after pulmonary administration. However, the optimal DPI formulations of CAF®01 for pulmonary immunization are not known. Here, we show that DPI formulations of CAF®01 spray-dried with a combination of sugars and the amino acid leucine exhibit optimal aerosolization properties and distribute in the lung lobes upon pulmonary administration. We demonstrate that the type of amorphous sugar used as stabilizer and the amount (w/w) of leucine used during spray drying affect the physicochemical properties and aerosol performance of DPI formulations. By systematically varying the ratios (w/w) of trehalose, dextran and leucine used as excipients during spray drying, we manufactured DPI formulations of CAF®01 that displayed (i) a spherical or wrinkled surface morphology, (ii) an aerodynamic diameter and particle size distribution optimal for deep lung deposition, and (iii) solid-state and aerosolization properties suitable for lung delivery. Using a design-of-experiments-based approach, we identified the most optimal process parameters in an in vivo aerosol generator, i.e., the PreciseInhale® system, which was used to measure the flowability of the aerosols. We found that the DPI formulation of CAF®01 spray-dried with trehalose and dextran (70% w/w) and leucine (30% w/w) displayed the most optimal physicochemical, morphological, solid-state, and aerosolization properties for deep lung deposition. Upon pulmonary administration, this DPI formulation distributed in the lung lobes in a way that was almost identical to the biodistribution of the non-spray dried formulation. Hence, DPI formulations of CAF®01, prepared with trehalose and dextran sugar matrix and a leucine shell, display physicochemical and aerosol properties suitable for inhalation.

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Section: Discussionsupporting

confidence: 64%

Optimizing the design and dosing of dry powder inhaler formulations of the cationic liposome adjuvant CAF®01 for pulmonary immunization

Thakur

Cano-Garcia

et al. 2022

Front. Drug. Deliv.

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“…Lactose and leucine were selected as well‐established excipients for dry‐powder formulations. [ 26 ] When the concentrations of lactose and leucine were optimized to 2.5% or 1% w/v, respectively, stable microparticles with a high fine‐particle fraction were achieved. To determine its aerodynamic properties after adding BDQ‐loaded liposomes, the microparticles were investigated using a next‐generation impactor.…”

Section: Resultsmentioning

confidence: 99%

Nano‐in‐Microparticles for Aerosol Delivery of Antibiotic‐Loaded, Fucose‐Derivatized, and Macrophage‐Targeted Liposomes to Combat Mycobacterial Infections: In Vitro Deposition, Pulmonary Barrier Interactions, and Targeted Delivery

Huck

Thiyagarajan

Bali

et al. 2022

Adv Healthcare Materials

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Nontuberculous mycobacterial infections rapidly emerge and demand potent medications to cope with resistance. In this context, targeted loco‐regional delivery of aerosol medicines to the lungs is an advantage. However, sufficient antibiotic delivery requires engineered aerosols for optimized deposition. Here, the effect of bedaquiline‐encapsulating fucosylated versus nonfucosylated liposomes on cellular uptake and delivery is investigated. Notably, this comparison includes critical parameters for pulmonary delivery, i.e., aerosol deposition and the noncellular barriers of pulmonary surfactant (PS) and mucus. Targeting increases liposomal uptake into THP‐1 cells as well as peripheral blood monocyte‐ and lung‐tissue derived macrophages. Aerosol deposition in the presence of PS, however, masks the effect of active targeting. PS alters antibiotic release that depends on the drug's hydrophobicity, while mucus reduces the mobility of nontargeted more than fucosylated liposomes. Dry‐powder microparticles of spray‐dried bedaquiline‐loaded liposomes display a high fine particle fraction of >70%, as well as preserved liposomal integrity and targeting function. The antibiotic effect is maintained when deposited as powder aerosol on cultured Mycobacterium abscessus. When treating M. abscessus infected THP‐1 cells, the fucosylated variant enabled enhanced bacterial killing, thus opening up a clear perspective for the improved treatment of nontuberculous mycobacterial infections.

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“…Ter domínio das técnicas de aerolização dos lipossomas é importante para garantir um produto com qualidade segundo as especificações (Ran, et al, 2015), uma vez que através destas técnicas é possível preservar a integridade do nanocarreador e minimizar as interações físico-químicas que causam a agregação das partículas (Thiyagarajan, et al, 2021). As técnicas de aerolização mais utilizadas são Spray Drying, Spray Freeze Drying e Freeze Drying (Misra, et al,2009).…”

Section: Técnicas De Aerolização De Lipossomasunclassified

Liposomes techniques of aerosolization for the treatment of obstructive, restrictive and infectious pulmonary diseases: a review

Santos

Macêdo

Silva³

et al. 2023

RSD

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The current treatment of lung diseases, such as tuberculosis, chronic obstructive pulmonary disease (COPD), asthma, cancer and SARS-CoV-2, presents problems related to drug administration. Thus, nanotechnology, an innovative method that stands out in recent years, especially in nanomedicine, due to the development of materials on the nanometer scale (1-1000 nm). Among the various nanosystems, liposomes for their physicochemical properties, which make them a technology of interest to encapsulate hydrophilic or hydrophobic drugs, in addition to enabling controlled drug release. These techniques employed using an inhalation route have been considered as an alternative to deliver drugs encapsulated in site-specific liposomes. For this purpose, the literature describes several liposome aerosolization techniques in order to optimize an aerosolization system. The objective of this research was to carry out a bibliographic survey of the use of liposomes in the treatment of lung diseases as well as patents related to liposomes in aerosol dosage form. According to articles searched in Science Direct, Springer Nature, National Library of Medicine (PubMed) and Scientific Electronic Library Online (SCIELO) databases on the most used techniques such as Spray Drying, Spray Freeze Drying and Freeze Drying, specifically spray-drying is described in the literature as the solution base as the one that favors obtaining vesicles with low density, good fluidity and good dispersibility. In short, it was found that, linked to the use of spray-drying and nanotechnology, the inhalation route is a promising route for the administration of drugs aimed at the of lung diseases.

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Spray-dried lactose-leucine microparticles for pulmonary delivery of antimycobacterial nanopharmaceuticals

Cited by 24 publications

References 38 publications

Optimizing the design and dosing of dry powder inhaler formulations of the cationic liposome adjuvant CAF®01 for pulmonary immunization

Optimizing the design and dosing of dry powder inhaler formulations of the cationic liposome adjuvant CAF®01 for pulmonary immunization

Nano‐in‐Microparticles for Aerosol Delivery of Antibiotic‐Loaded, Fucose‐Derivatized, and Macrophage‐Targeted Liposomes to Combat Mycobacterial Infections: In Vitro Deposition, Pulmonary Barrier Interactions, and Targeted Delivery

Liposomes techniques of aerosolization for the treatment of obstructive, restrictive and infectious pulmonary diseases: a review

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