Abstract
Chalcone derivatives are shown to possess excellent anti-inflammatory and anti-oxidant properties which are of great interest in treating respiratory diseases such as acute lung injury (ALI), acute respiratory distress syndrome (ARDS), chronic obstructive pulmonary disease (COPD), and pulmonary fibrosis (PF). This study successfully designed and developed dry powder inhaler (DPI) formulations of TMC (2-trifluoromethyl-2′-methoxychalone), a new synthetic trifluorinated chalcone and Nrf2 agonist, for targeted pulmonary inhalation aerosol drug delivery. An advanced co-spray drying particle engineering technique was used to design and produce microparticulate/nanoparticulate formulations of TMC with a suitable excipient (mannitol) as inhalable particles with tailored particle properties for inhalation. Raw TMC and co-spray dried TMC formulations were comprehensively characterized for the first time using scanning electron microscopy (SEM) with energy dispersive X-ray (EDX) spectroscopy, thermal analysis, X-ray powder diffraction (XRPD), and molecular fingerprinting as dry powders by ATR-FTIR spectroscopy and Raman spectroscopy. Further, biocompatibility and suitability of formulations were tested with in vitro cellular transepithelial electrical resistance (TEER) in air-interface culture (AIC) using a human pulmonary airway cell line. The ability of these TMC formulations to perform as aerosolized dry powders was systematically evaluated by design of experiments (DOEs) using three different FDA-approved human inhaler devices followed by interaction parameter analyses. Multiple spray drying pump rates (25%, 75%, and 100%) successfully produced co-spray dried TMC:mannitol powders. Raw TMC exhibited a first-order phase transition temperature at 58.15 ± 0.38 °C. Furthermore, the results demonstrate that these innovative TMC dry powder particles are suitable for targeted delivery to the airways by inhalation.
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Introduction
Airways are continuously exposed to environmental insults that trigger inflammation consistent with the body’s natural response to a stimulus such as smoke, infection, pollutants, and allergens. Hence, inflammation is the main characteristic of many respiratory diseases such as pneumonia, acute lung injury (ALI)1, acute respiratory distress syndrome (ARDS), asthma, chronic obstructive pulmonary disease (COPD)2, and pulmonary fibrosis (PF)3,4. The innate defense mechanism of the respiratory system includes mechanical barrier, mucus production, and ciliary movement to remove the pathogen, phagocytosis and inflammatory response. Pulmonary inflammation can be acute, as seen in ALI and ARDS, or it can be chronic such as in asthma and COPD. In acute lung inflammation, the body fights the trigger immediately to resolve and restore homeostasis, if this fails it leads to chronic inflammation5. The inflammatory cells involved in acute and chronic inflammation are different. Neutrophils, eosinophils, are more active in acute cases whereas lymphocytes and macrophages play a dominant role in chronic inflammation5,6. There are several cellular and molecular mechanisms involved in the repair and resolution of lung inflammation6, among those the anti-oxidant signaling pathways are of growing interest. Nuclear factor (erythroid-derived 2)—like 2 (Nrf2) genetic pathway is an anti-oxidant signaling pathway that controls the anti-oxidant and anti-inflammatory response against oxidative stress. In many lung diseases, there is an inherent risk for oxidative stress due to the high oxygen burden in the organ, as reported in chronic obstructive pulmonary disease (COPD) and pulmonary hypertension7,8,9,10,11.
Recently, the involvement of Nrf2 in pulmonary diseases such as COPD, ALI1, and PF and targeting with Nrf2 activators are of great interest12,13,14,15,16,17,18,19,20. The Nrf2 activity of a novel synthetic trifluorinated chalcone chemical derivative, TMC (2-trifluoromethyl-2′-methoxychalone), was reported21. The study synthesized about 59 derivatives of chalcone and systematically screened their Nrf2 activity by testing in normal pulmonary epithelial cell line and mouse model. Among the synthesized derivatives, TMC (the chemical structure is shown in Fig. 1) emerged as a potential lead compound possessing Nrf2 pathway activator properties. Chalcone is also known as 1,3-diaryl-2-propen-1-ones is an aromatic ketone that exists as either cis (Z) or trans (E) isomeric form. It belongs to the flavonoid family naturally occurring in fruits, vegetables, and other plants. There are numerous derivatives of chalcone studied for their biological activities as anti-inflammatory22,23,24, anti-histaminic25, anti-oxidant26,27, anti-cancer28,29,30,31, antituberculosis32, nitric oxide inhibitor33, and antifungal34. The anti-inflammatory effect of chalcones is demonstrated through the NF-κB pathway inhibition35,36,37. Also reported is the Nrf2/ARE cellular pathway activation efficacy of chalcone and its derivatives in different cell lines such as mouse embryonic fibroblast cells38, neural and microglial cells39,40, AREc32 cells41, gastric epithelial cells42, lung epithelial cells21, and colon cells43. More importantly, the Nrf2 activation and anti-fibrotic effects of a chalcone molecule were recently demonstrated in in vitro human skin fibroblasts and in an in vivo skin fibrosis mouse model44.
The main objective of this systematic study was to design, develop and optimize dry powder inhaler (DPI) formulations of TMC (Fig. 1) to treat inflammatory and fibrotic lung diseases directly through targeted lung delivery to the airways. To the authors’ knowledge, this study is the first to report on the solid-state physicochemical properties of TMC and successfully create innovative TMC inhalable nanoparticles/microparticles. TMC was co-spray dried with mannitol as an excipient. Table 1 lists the powder formulations that were created in this study. The aerosol formulations were comprehensively characterized and examined in vitro for its suitability as pulmonary drug delivery. The influence of different human DPI devices on the aerosol properties of the formulations was also quantified and correlated with DPI device properties and formulation properties.
Results
Scanning electron microscopy (SEM) and energy dispersive X-ray (EDX)
Figure 2 displays the scanning electron micrograph of raw TMC and co-SD TMC: Man particles at different spray drying pump rates (PRs). The raw TMC particles were elongated and exhibited a wide size range with sizes much too large for inhalation aerosol delivery to the lungs. Particle engineering design by advanced co-spray drying TMC with Man successfully rendered the particles into small and equivalent spheres which are essential solid-state particle properties for DPIs. The particles made at 25% PR had smooth surface morphology. Similarly, 100% PR particles had smooth surface morphology with equivalent spheres. The particles SD at 75% PR had a different appearance compared to that of 25% and 100% PR particles. The particles were large where more solid sintering was observed.
The EDX spectra of the raw and co-SD particles are displayed in Fig. 3. The elemental analysis of raw TMC and co-SD TMC: Man particles show peaks of carbon, oxygen, fluorine, and gold at 0.269, 0.520, 0.678, and 2.148 respectively. The presence of fluorine at 0.678 keV energy is elemental atomic evidence in the solid-state of the presence of TMC molecules in the co-SD particles at all three spray drying pump rates.
Particle sizing and size distribution by image analysis of SEM micrographs
The SEM micrographs show discrete particles of co-SD TMC: Man which were measured using imaging software SigmaScan Pro version 5.0 (Systat software, San Jose, CA). The sizing data is shown in Table 2. The average particle size of 25% PR, 75% PR and 100% PR were 0.746 µm, 1.37 µm, and 0.962 µm, respectively. The number based diameters measured were Dn10 = 0.52 µm, 0.79 µm, and 0.60 µm for 25%, 75% and 100% PR, respectively, and Dn90 = 0.98 µm, 2.26 µm, and 1.40 µm for 25%, 75% and 100% PR, respectively.
X-ray powder diffraction (XRPD)
The X-ray diffraction of raw TMC shows several sharp and intense peaks, as evident from Fig. 4A. This is indicative of long-range molecular order as a result of crystallinity in the solid state. Prominent peaks of crystalline TMC were seen at 12.8, 13.5, 14.9, 16.1, 17.1, 18.3, 22.0, 23.0, 24.9, 25.7, 26.9 and 28.4 2θ degrees. The co-SD TMC: Man particles also showed several sharp and intense peaks, as seen in Fig. 4B, indicative of crystallinity and the peaks correspond to those of both components. It has been previously reported that d-mannitol retains its crystallinity following advanced spray drying under our conditions45.
Differential scanning calorimetry (DSC)
Figure 5 shows representative thermograms of raw TMC and co-SD TMC: Man particles with the corresponding thermodynamic properties in Table 3. Raw TMC had a single endothermic transition from the solid-to-liquid state at 58 °C which is the main phase transition temperature and melting temperature (Tm) of TMC. On the other hand, the co-SD TMC: Man particles at all the three pump rates showed two endothermic transitions around 57 °C and 164 °C. The first transition belongs to TMC, while the second transition is that of Man as previously observed45.
Attenuated total reflectance (ATR)–Fourier transform infrared (FTIR) spectroscopy
For molecular fingerprinting in a non-invasive and non-destructive manner, ATR-FTIR is used. ATR-FTIR spectra of raw TMC and all co-SD TMC: Man particles showed similar absorption bands in the fingerprint region, as seen in Fig. 6. The distinctive peaks are seen at 749 cm−1 (CH-out of plane deformation in ortho-disubstituted benzene), 1615 cm−1 (benzene ring stretch seen in aromatic compounds), and 1314 cm−1 (CF3 antisym stretch seen in CF3 attached benzene ring) serve to be the characteristic bands of TMC molecule. These bands are also seen in the co-SD formulations in addition to the band seen around 3200 cm−1 in 75% and 100% PR particles. This is suggestive of H-bonding between TMC and Man particles.
Confocal Raman microspectroscopy (CRM), chemical imaging, and mapping
For molecular fingerprinting in a non-invasive and non-destructive manner, Raman spectroscopy is used and complements ATR-FTIR. The Raman spectra obtained using a 512 nm laser is seen in Fig. 7. The spectra obtained compliment the absorption bands seen in ATR-FTIR. Moreover, the Raman spectra of raw TMC and the co-SD TMC: Man particles at all pump rates look similar to each other suggesting that the co-SD formulations of TMC: Man at all pump rates didn’t affect the intermolecular interaction of the two compounds.
In vitro aerosol dispersion performance
The in vitro aerosol dispersion performance of co-SD TMC: Man particles are shown in Fig. 8 and Table 4. Figure 8 shows the aerosol deposition on individual stages of the NGI when the three different human DPI devices were used. Table 4 lists the ED, FPF, RF, calculated MMAD, and GSD of the co-SD TMC: Man particles at the three pump rates. It can be seen that the highest ED was obtained with the Aerolizer and Neohaler DPI devices. The ED provided with the HandiHaler device was very high in the range of 91–98%. The highest FPF of 38.75 ± 2.33 obtained was with 100% PR particles with the HandiHaler DPI device followed by the same particles aerosolized with Neohaler DPI device giving an FPF of 36.12 ± 1.67. The smallest MMAD (a calculated value) of 3.56 ± 0.51 µm was obtained with 25% PR particles when used with Aerolizer device followed by 4.56 ± 0.56 µm of 25% PR particles with Neohaler device. The calculated MMAD of Co-SD TMC: Man particles at 100% PR was in the range of 5 -5.5 µm using all the inhaler devices.
In vitro transepithelial electrical resistance analysis (TEER)
The TEER values for the raw TMC and co-SD TMC: Man particles are displayed in Fig. 9. The control value represents the cells treated with the vehicle in which the test formulations were dissolved, in this case, 10% ethanol + 90% EMEM cell media. The raw TMC and representative co-SD TMC: Man particles had decreased TEER value right after treatment which gradually recovered. It can be seen that the control cells recovered faster than the drug-treated cells.
Discussion
This is the first study to report on DPI formulations of TMC for targeted pulmonary inhalation aerosol drug delivery. In addition, this is the first study to report on the physicochemical solid-state characteristics of raw TMC. This study has identified mannitol to be a suitable excipient to formulate TMC into small and spherical solid-state particles in the size range of a few hundred nanometers to a few micrometers. The particle size presented in this study is in the desired range for delivery of particles to the lower airways, as predicted by the in vitro aerosol dispersion and deposition on the lower stages (i.e. smaller aerodynamic size) of the inertial impactor. Advanced spray drying in closed-mode under the reported conditions (Table 1) was successfully used with methanol as the solvent to design and produce engineered solid-state particles with physical properties necessary for dry powder aerosol formulation. Initially, TMC was spray dried individually using methanol and isopropanol at various concentrations using different spray drying conditions. Despite the change in concentrations and solvent, TMC particles were not formed. A similar observation was made when another Nrf2-activator drug dimethyl fumarate (DMF) was spray dried, as reported earlier20. In that study20, mannitol was used to promote particle formation by hydrogen-bonding with DMF. Hence, in this study, a similar approach was adopted and Man was used as an excipient to successful form inhalable TMC nanoparticles and microparticles in the solid-state. Several different molar ratios of TMC and Man were tested to form co-SD particles at different advanced spray drying conditions. The three selective formulations were chosen for characterization and development based on the preliminary aerosol performance and the higher particle yield during spray drying.
From the SEM images (Fig. 2), it can be seen that the co-SD TMC: Man particles formed small, spherical and smooth particles at 25% and 100% PR. The 75% PR particles were relatively larger with some degree of particle coalescence happening, nonetheless, the discrete particles that were measurable were small with the slightly corrugated surface. The particle coalescence observed could also be due to the smearing on to the SEM stub for imaging purpose. This could have caused the primary particles to break or sinter. In any case, co-SD particles were sized and the average particles size and size distribution were calculated. The co-SD TMC: Man particles at 25% and 100% PR had relatively smaller particles compared to the 75% PR. The span value which is an indication of the size distribution width, in other words, this value suggests how far is the 90% and 10% percentile particles from the median diameter. In this study, the span values of 0.63, 1.27 & 0.89 indicating that the particle size distribution is narrow, which correlates well with the SEM images.
Thermal analysis by DSC identified the main phase transition of melting (Tm) for the raw TMC at ~ 58 °C and the change in enthalpy (ΔH) was calculated to be ~ 90 kJ/mol (Table 3 and Fig. 5). This first-order phase transition temperature agrees well with the Tm of the parent chalcone which is reported to be 55–57 °C in ChemSpider and PubChem. This the only transition observed during the thermal analysis, further indicating that the compound was crystalline and in excellent agreement with the XRPD data. The co-SD TMC: Man particles at all the three pump rates also exhibited the same transition around 57–58 °C, which indicates the presence of the same polymorph. This was further confirmed using XRPD diffractogram peaks (Fig. 4) of raw and co-SD TMC: Man. All the prominent peaks of raw TMC seen at 12.8, 13.5, 14.9, 16.1, 17.1, 18.3, 22.0, 23.0, 24.9, 25.7, 26.9 and 28.4 2θ degrees were also seen in the co-SD TMC: Man particles at all pump rates further confirming the that TMC exists in the same crystalline form before and after spray drying. In other words, there was no polymorphic interconversion seen as evident from both XRPD and DSC results. There is no previous report on the solid-state properties of TMC, as this is the first time the XRPD diffractograms and DSC thermograms of TMC are reported.
The elemental atomic analysis using SEM–EDX (Fig. 3) provides confirmation of the chemical presence of the fluorine atom at 0.68 keV which is from the CF3 group attached to the benzene ring. The gold atoms seen in the spectra are the M-lines from the gold coating and do not represent the molecular composition of the powder formulation. In excellent agreement with the SEM–EDX data (Fig. 3) is the molecular fingerprinting spectroscopy data. The vibrational spectroscopy data using ATR-FTIR (Fig. 6) and Raman (Fig. 7) also show the peaks of CF3. The peaks seen in the region between 700–1700 cm−1 wavenumbers match in both raw TMC and co-SD samples, which serves as a molecular fingerprint identification of TMC in the pure solid-state and in the co-SD powder formulations. However, there were additional peaks around 3200 cm−1 seen in some co-SD TMC: Man powders suggesting H-bonding between the TMC and mannitol molecules which agrees well with their chemical structures.
From the in vitro TEER results in air-interface culture (AIC) conditions (Fig. 9), it can be seen that the co-SD TMC: Man formulations upon aerosolization directly onto the cell temporarily disrupted the monolayer of the Calu-3 cells in the transwell inserts for a brief period of time. The TEER of this human lung bronchial cell line recovered within hours. The recovery of drug-treated cells was slower than that of the control cells which was treated with aerosolized cell culture media.
The NGI stage deposition profiles seen in Fig. 8 using Aerolizer and Neohaler showed that the 75% PR particles had a higher deposition on Stage 1 compared to the lower stages, while 25% and 100% PR particles had less deposition on Stage 1. However, with HandiHaler all the three co-SD powders had a higher deposition on Stage 1. From Fig. 8, it is evident that the co-SD TMC: Man 75% PR powder deposition profile was considerably different from that of the other profiles by two PR powders. Even though the 25% and 100% PR powders NGI deposition profile look similar, there was a statistically significant difference between the deposition profiles when Neohaler and HandiHaler DPI devices were used, as reflected in the aerosol performance parameters (Table 4). On the other hand, for 25% PR and 100% PR powders, there was no significant difference between Aerolizer and Neohaler but 75% PR showed no statistical difference between the Aerolizer and HandiHaler devices (Table 4).
From the particle sizing data (Table 2), it was seen that the geometric diameters were few hundred nanometers to a few micrometers, and all less than 3 µm in linear geometric diameter. Yet, the MMAD calculated from the NGI results was in the range of 3.5–15 µm (Table 4). This can be due to the physical properties influencing the aerodynamic properties46. Firstly, nanoparticles47,48 have an increased surface area-to-volume ratio leading to higher surface forces that could cause increased interparticulate interactions leading to cohesive forces between the solid-state particles. On the other hand, the shear stress generated from the DPI devices could have been insufficient to completely disperse all of the particle aggregates into their primary particles. The co-SD TMC: Man particles at 25% PR, which had a geometric particles size range of 520 nm-980 nm (Table 2) was better dispersed by the lower resistance (low shear stress) DPI device, the Aerolizer (Fig. 8 and Table 4), whereas, the 75% PR particles had a geometric size range of 790 nm–2.26 µm (Table 2).
The interaction correlation between spray drying inlet feed pump rate and the inhaler device’s inherent specific resistance was analyzed using Design-Expert software (Stat-Ease, Minneapolis, MN). Figure 10 shows the 3-D surface and interaction plots where ED, FPF, RF, and MMAD were considered as design response terms. The ED (p-value = 0.2647) was not a significant term. Evidently, neither the pump rate nor the device resistance affected the fraction of powder emitted from the inhaler device. The overlapping error bars in the interaction plot in Fig. 10A demonstrates the same. However, the opposite trend was correlated for FPF (Fig. 10B), RF (Fig. 10C), and MMAD (Fig. 10D) (p < 0.0001), which were affected by both pump rate and device resistance. From Fig. 10, it can be seen that co-SD TMC: Man 75% PR particles had the lowest FPF, RF and highest MMAD. However, 25% and 100% PR particles had comparable results for FPF, RF and MMAD. At lower (25%) and higher (100%) spray drying pump rates TMC: Man formed relatively smaller and spherical particles that dispersed well with low and low-medium resistance inhaler devices. The mediocre performance of the 75% spray drying pump rate particles can be related to the physicochemical properties of the powder.
Conclusions
This systematic and comprehensive study reports for the first time on innovative dry powder inhaler formulations of the novel synthetic trifluorinated Nrf2-agonist TMC molecularly mixed with a d-mannitol in the solid-state. This study is the first to report on the comprehensive characterization of the physicochemical properties of TMC including Tm, crystalline phase, and spectroscopy molecular fingerprinting by both ATR-FTIR and Raman spectroscopy. The study also successfully designed, produced, and optimized inhalable TMC nanoparticles and microparticles in the solid-state molecularly mixed with d-mannitol as an excipient engineered advanced organic closed-mode spray drying technique at three rationally chosen pump rates. All of these microparticulate/nanoparticulate powders possessed the essential particle properties necessary for dry powder aerosolization and all readily aerosolized with three different human DPI devices that vary in resistance and shear stress. The correlation between spray drying process parameters, inhaler device resistance (shear stress), and aerosol properties were correlated in a meaningful manner.
Materials and methods
Materials
Synthetic TMC (2-trifluoromethyl-2′-methoxychalone) with a molecular formula of C17H13F3O2 and molecular weight (MW) of 306.28 g/mol was generously provided by Cureveda LLC. d-mannitol (C6H14O6; MW: 182.17 g/mol) was obtained from Acros Organics (New Jersey, USA). Methanol (HPLC grade, ACS-certified grade, purity 99.9%) was obtained from Fisher Scientific (Fair Lawn, New Jersey). Hydranal-Coulomat AD was obtained from Sigma-Aldrich. The nitrogen gas used was ultra-high purity (UHP) nitrogen gas (Cryogenics and Gas facility, The University of Arizona, Tucson, AZ). Raw TMC was stored in sealed glass desiccators over Indicating Drierite desiccant at − 80 °C. Raw d-mannitol was used as received and stored under room conditions. Other chemicals were stored under room conditions.
Methods
Preparation of co-SD particles by organic solution advanced spray drying in closed-mode
Organic solution advanced spray drying process in the absence of water was performed in a closed-mode using a Büchi B-290 Mini spray dryer with a high-performance cyclone in a closed mode using UHP dry nitrogen gas as the atomizing drying gas. The feed solution consists of drug dissolved in methanol. For the two-component system, the components were dissolved successively in the solvent consisting of the drug with Man in rationally selected molar ratios. Table 1 lists the spray drying conditions used for the dry powder aerosol formulation development. The drying gas atomization rate (670 L/h at 35 mmHg) and aspiration rate (35 m3/h at 100% rate) were maintained constant during all the experiments. Three feed pump rates were employed to obtain particles using pump rates of 7.5 mL/min (low, 25%), 22.5 mL/min (medium–high, 75%), and 30 mL/min (high, 100%). The stainless steel two-fluid nozzle used to spray the feed solution had a tip diameter of 0.7 mm with 1.5 mm gas cap. All co-SD powders were carefully stored in sealed glass vials stored in sealed glass desiccators over indicating Drierite desiccant at − 20 °C under ambient pressure.
Scanning electron microscopy (SEM) and energy dispersive X-ray (EDX) spectroscopy
Using conditions similar to those previously reported20,45,49,50,51, raw and spray dried particles were visualized using scanning electron microscopy (SEM). The powder samples were sputter coated with gold for 90 s under Argon plasma. An electron beam of 30 kV voltage was used for imaging.
Particle sizing and size distribution image analysis using SEM micrographs
The mean particle size, standard deviation, and particle size range were determined digitally using SigmaScan Pro 5 (Systat software, San Jose, CA) using similar conditions that have been previously reported20,52. Representative SEM micrographs of each powder sample at 10,000 × magnification were analyzed by measuring the diameter of at least 100 particles.
X-ray powder diffraction (XRPD)
Using conditions similar to previously reported20,45,49,50,51, X-ray powder diffraction (XRPD) patterns were collected at room temperature using copper Kα radiation (45 kV, 40 mA, and λ = 1.5406 Å) between 5.0° and 70.0° (2θ) for raw TMC and 5.0° and 50.0° (2θ) for co-SD powders at a scan rate of 2.00°/min at ambient temperature. A zero background silicon wafer sample holder was used.
Differential scanning calorimetry (DSC)
Using conditions similar to previously reported20,45,49,50,51, thermal analysis and phase transition measurements were performed. Approximately 1–10 mg of sample was placed into an anodized aluminum hermetic DSC pan that was sealed with the T-Zero hermetic press. The samples were heated from 0.00 to 250.00 °C at a scanning rate of 5.00 °C/min.
Confocal Raman microspectroscopy (CRM), and chemical imaging
Confocal Raman microspectroscopy (CRM) provides noninvasive and nondestructive microspectroscopic component analysis of DPI formulations. Using similar conditions previously reported20,45,49,50,51, Raman spectra were obtained at 514 nm laser excitation using Renishaw InVia Reflex using a 20 × magnification objective on a Leica DM2700 optical microscope. Raman spectral map was obtained with the stage moved in increments of 20 × 20 µm in each axis. Each map point was acquired 1 accumulation using 2 s of detector exposure time per accumulation.
Attenuated total reflectance (ATR)–Fourier-transform infrared (FTIR) spectroscopy
Each spectrum was collected for 32 scans at a spectral resolution of 8 cm−1 over the wavenumber range of 4000–400 cm−1. A background spectrum was subtracted from each sample spectrum. These conditions are similar to those in our previous reports45,49,50,51.
In vitro aerosol dispersion performance
In vitro aerosol dispersion analysis was conducted in accordance with USP Chapter \(\left\langle {601} \right\rangle\) specifications53 on aerosols and using conditions similar to previously reported45,49,50,51 using the Next Generation Impactor (NGI) with a stainless steel induction port (USP throat) attachment. Three FDA approved human DPI devices Aerolizer (Merck, Germany), Neohaler (Novartis, Switzerland) and HandiHaler (Boehringer Ingelheim, Germany) were used for the aerosol dispersion. An airflow rate (Q) of 60 L/min (adult airflow rate) was adjusted and measured before each experiment. The mass of powder deposited on each stage was quantified gravimetrically. Quali-V clear HPMC size 3 inhalation grade capsules were used with about 10 mg of powder filled in it. Three capsules were used in each experiment. In vitro aerosolization was evaluated in triplicate (n = 3) under ambient conditions. Design of experiments (DoEs) was conducted using Design-Expert 8.0.7.1 software (Stat-Ease Corporation, Minneapolis, MN). A full-factorial design of 32 for co-SD TMC: Man systems was utilized.
The emitted dose (ED), fine particle fraction (FPF) and respirable fraction (RF) were calculated similar to previous reports45,49,50,51. The ED was determined as the difference between the initial mass of powder loaded in the capsules and the remaining mass of powder in the capsules following aerosolization. The ED (%) Eq. (1) was used to express the percentage of ED based on the total dose (TD) used. The fine particle dose (FPD) was defined as the dose deposited on stages 2 to 7. The FPF % in Eq. (2) was expressed as the percentage of FPD to ED. The RF % in Eq. (3) was used as the percentage of FPD to total deposited dose (DD) on all NGI stages.
In vitro transepithelial electrical resistance analysis in air-interface culture (AIC)
Calu-3 human lung adenocarcinoma cell line derived from the bronchial submucosal airway region was grown in Eagle’s minimum essential medium (EMEM), 10% (v/v) fetal bovine serum (FBS), Pen-Strep (100 U/mL penicillin, 100 µg/mL), Fungizone (0.5 µg/mL amphotericin B, 0.41 µg/mL sodium deoxycholate) as previously reported 54,55,56. They were seeded at a concentration of 500,000 cells/mL in Costar Transwells® (0.4 μm polyester membrane, 12 mm for a 12-well plate). After few days of growth, when the cells reached a TEER value of about 1000 Ω/cm2 the media was removed apical side to facilitate air-interface culture (AIC) conditions. When the TEER values reached approximately 500 Ω/cm2 (indicating a confluent monolayer at AIC conditions), the cells were exposed to 100 µM of the test formulation dissolved in non-supplemented EMEM media. The aerosol formulations were delivered as a liquid aerosol using the Penn-Century MicroSprayer Aerosolizer Model IA-1B. TEER values were then recorded for up to 7 days after aerosol treatment, as previously reported53,56. Media was added to the apical side temporary for TEER measurements, after which the cells returned to AIC conditions.
Statistical analysis
Design of experiments (DoEs) for in vitro aerosol performance was conducted using Design-Expert 8.0.7.1 software (Stat-Ease Corporation, Minneapolis, MN). A full-factorial design of 32 for co-SD TMC: Man systems was utilized for in vitro aerosol dispersion performance testing. Aerosol dispersion parameters and process parameters interactions were evaluated using the Analysis of Variance (ANOVA) test performed using SigmaPlot Version 13 (Systat software, Inc, San Jose, CA) and Design-Expert software programs. All experiments were performed in at least triplicate (n = 3).
References
Rojo de la Vega, M. et al. Role of Nrf2 and autophagy in acute lung injury. Curr. Pharmacol. Rep. 2, 91–101 (2016).
Hayes, D. Jr., Black, S. M., Tobias, J. D., Mansour, H. M. & Whitson, B. A. Prevalence of pulmonary hypertension and its influence on survival in patients with advanced chronic obstructive pulmonary disease prior to lung transplantation. Copd 13, 50–56. https://doi.org/10.3109/15412555.2015.1043425 (2016).
Muralidharan, P., Hayes, D. J. & Mansour, H. M. In Inhalation Aerosols: Physical and Biological Basis for Therapy Lung Biology in Health and Diseases Series, Ch. 18 (eds Hickey, A. J. & Mansour, H. M.) 303–312 (CRC Press/Taylor and Francis, Coca Raton, 2019).
Hayes, D. Jr. et al. Influence of pulmonary hypertension on patients with idiopathic pulmonary fibrosis awaiting lung transplantation. Ann. Thorac. Surg. 101, 246–252. https://doi.org/10.1016/j.athoracsur.2015.06.024 (2016).
Moldoveanu, B. et al. Inflammatory mechanisms in the lung. J. Inflamm. Res. 2, 1–11 (2009).
Robb, C. T., Regan, K. H., Dorward, D. A. & Rossi, A. G. Key mechanisms governing resolution of lung inflammation. Semin. Immunopathol. 38, 425–448. https://doi.org/10.1007/s00281-016-0560-6 (2016).
McGuinness, A. J. & Sapey, E. Oxidative sstress in COPD: sources, markers, and potential mechanisms. J. Clin. Med. https://doi.org/10.3390/jcm6020021 (2017).
Sharma, S. et al. Alterations in lung arginine metabolism in lambs with pulmonary hypertension associated with increased pulmonary blood flow. Vascul. Pharmacol. 51, 359–364. https://doi.org/10.1016/j.vph.2009.09.005 (2009).
Gabrielli, L. A. et al. Systemic oxidative stress and endothelial dysfunction is associated with an attenuated acute vascular response to inhaled prostanoid in pulmonary artery hypertension patients. J. Card. Fail. 17, 1012–1017 (2011).
Firth, A. L., Yuill, K. H. & Smirnov, S. V. Mitochondria-dependent regulation of Kv currents in rat pulmonary artery smooth muscle cells. Am. J. Physiol. 295, L61–L70 (2008).
Fresquet, F. et al. Role of reactive oxygen species and gp91phox in endothelial dysfunction of pulmonary arteries induced by chronic hypoxia. Br. J. Pharmacol. 148, 714–723 (2006).
Harvey, C. J. et al. Targeting Nrf2 signaling improves bacterial clearance by alveolar macrophages in patients with COPD and in a mouse model. Sci. Transl. Med. 3, 78ra32. https://doi.org/10.1126/scitranslmed.3002042 (2011).
Chen, C., Jiang, X., Gu, S. & Zhang, Z. MicroRNA-155 regulates arsenite-induced malignant transformation by targeting Nrf2-mediated oxidative damage in human bronchial epithelial cells. Toxicol. Lett. 278, 38–47. https://doi.org/10.1016/j.toxlet.2017.07.215 (2017).
Chen, W. et al. Artemisitene activates the Nrf2-dependent antioxidant response and protects against bleomycin-induced lung injury. FASEB J. 30, 2500–2510. https://doi.org/10.1096/fj.201500109R (2016).
Tao, S. et al. Tanshinone I activates the Nrf2-dependent antioxidant response and protects against As(III)-induced lung inflammation in vitro and in vivo. Antioxid. Redox Signal. 19, 1647–1661. https://doi.org/10.1089/ars.2012.5117 (2013).
Zheng, Y. et al. Sulforaphane prevents pulmonary damage in response to inhaled arsenic by activating the Nrf2-defense response. Toxicol. Appl. Pharmacol. 265, 292–299. https://doi.org/10.1016/j.taap.2012.08.028 (2012).
Sussan, T. E. et al. Targeting Nrf2 with the triterpenoid CDDO-imidazolide attenuates cigarette smoke-induced emphysema and cardiac dysfunction in mice. Proc. Natl. Acad. Sci. U.S.A. 106, 250–255. https://doi.org/10.1073/pnas.0804333106 (2009).
Jaramillo, M. C. & Zhang, D. D. The emerging role of the Nrf2-Keap1 signaling pathway in cancer. Genes Dev. 27, 2179–2191. https://doi.org/10.1101/gad.225680.113 (2013).
Zhao, H., Eguchi, S., Alam, A. & Ma, D. The role of nuclear factor-erythroid 2 related factor 2 (Nrf-2) in the protection against lung injury. Am. J. Physiol. 312, L155–L162. https://doi.org/10.1152/ajplung.00449.2016 (2017).
Muralidharan, P., Hayes, D. Jr., Black, S. M. & Mansour, H. M. Microparticulate/nanoparticulate powders of a novel Nrf2 activator and an aerosol performance enhancer for pulmonary delivery targeting the lung Nrf2/Keap-1 pathway. Mol. Syst. Design Eng. 1, 48–65. https://doi.org/10.1039/C5ME00004A (2016).
Kumar, V. et al. Novel chalcone derivatives as potent Nrf2 activators in mice and human lung epithelial cells. J. Med. Chem. 54, 4147–4159. https://doi.org/10.1021/jm2002348 (2011).
Israf, D. A., Khaizurin, T. A., Syahida, A., Lajis, N. H. & Khozirah, S. Cardamonin inhibits COX and iNOS expression via inhibition of p65NF-kappaB nuclear translocation and Ikappa-B phosphorylation in RAW 264.7 macrophage cells. Mol. Immunol. 44, 673–679. https://doi.org/10.1016/j.molimm.2006.04.025 (2007).
Singh, H., Sidhu, S., Chopra, K. & Khan, M. U. Hepatoprotective effect of trans-Chalcone on experimentally induced hepatic injury in rats: inhibition of hepatic inflammation and fibrosis. Can. J. Physiol. Pharmacol. 94, 879–887. https://doi.org/10.1139/cjpp-2016-0071 (2016).
Martinez, R. M. et al. Topical formulation containing hesperidin methyl chalcone inhibits skin oxidative stress and inflammation induced by ultraviolet B irradiation. Photochem. Photobiol. Sci. 15, 554–563. https://doi.org/10.1039/c5pp00467e (2016).
Yamamoto, T. et al. Anti-allergic activity of naringenin chalcone from a tomato skin extract. Biosci. Biotechnol. Biochem. 68, 1706–1711. https://doi.org/10.1271/bbb.68.1706 (2004).
Aoki, N., Muko, M., Ohta, E. & Ohta, S. C-geranylated chalcones from the stems of Angelicakeiskei with superoxide-scavenging activity. J. Nat. Prod. 71, 1308–1310. https://doi.org/10.1021/np800187f (2008).
Hofmann, E. et al. Hydroxylated chalcones with dual properties: xanthine oxidase inhibitors and radical scavengers. Bioorg. Med. Chem. 24, 578–587. https://doi.org/10.1016/j.bmc.2015.12.024 (2016).
Xia, Y. et al. Antitumor agents. Part 202: novel 2’-amino chalcones: design, synthesis and biological evaluation. Bioorg. Med. Chem. Lett. 10, 699–701 (2000).
Bois, F. et al. Halogenated chalcones with high-affinity binding to P-glycoprotein: potential modulators of multidrug resistance. J. Med. Chem. 41, 4161–4164. https://doi.org/10.1021/jm9810194 (1998).
Zhang, S. et al. A novel chalcone derivative S17 induces apoptosis through ROS dependent DR5 up-regulation in gastric cancer cells. Sci. Rep. 7, 9873. https://doi.org/10.1038/s41598-017-10400-3 (2017).
Coskun, D., Erkisa, M., Ulukaya, E., Coskun, M. F. & Ari, F. Novel 1-(7-ethoxy-1-benzofuran-2-yl) substituted chalcone derivatives: synthesis, characterization and anticancer activity. Eur. J. Med. Chem. 136, 212–222. https://doi.org/10.1016/j.ejmech.2017.05.017 (2017).
Lin, Y. M. et al. Chalcones and flavonoids as anti-tuberculosis agents. Bioorg. Med. Chem. 10, 2795–2802 (2002).
Rojas, J., Paya, M., Dominguez, J. N. & Luisa Ferrandiz, M. The synthesis and effect of fluorinated chalcone derivatives on nitric oxide production. Bioorg. Med. Chem. Lett. 12, 1951–1954 (2002).
Svetaz, L. et al. Antifungal chalcones and new caffeic acid esters from Zuccagniapunctata acting against soybean infecting fungi. J. Agric. Food Chem. 52, 3297–3300. https://doi.org/10.1021/jf035213x (2004).
Liu, Y. C., Hsieh, C. W., Wu, C. C. & Wung, B. S. Chalcone inhibits the activation of NF-kappaB and STAT3 in endothelial cells via endogenous electrophile. Life Sci. 80, 1420–1430. https://doi.org/10.1016/j.lfs.2006.12.040 (2007).
Lee, J. H. et al. Blockade of nuclear factor-kappaB signaling pathway and anti-inflammatory activity of cardamomin, a chalcone analog from Alpiniaconchigera. J. Pharmacol. Exp. Ther. 316, 271–278. https://doi.org/10.1124/jpet.105.092486 (2006).
Ban, H. S. et al. Inhibition of lipopolysaccharide-induced expression of inducible nitric oxide synthase and tumor necrosis factor-alpha by 2’-hydroxychalcone derivatives in RAW 264.7 cells. Biochem. Pharmacol. 67, 1549–1557. https://doi.org/10.1016/j.bcp.2003.12.016 (2004).
Han, J. Y. et al. The chalcone compound isosalipurposide (ISPP) exerts a cytoprotective effect against oxidative injury via Nrf2 activation. Toxicol. Appl. Pharmacol. 287, 77–85. https://doi.org/10.1016/j.taap.2015.05.015 (2015).
Yao, J., Zhang, B., Ge, C., Peng, S. & Fang, J. Xanthohumol, a polyphenol chalcone present in hops, activating Nrf2 enzymes to confer protection against oxidative damage in PC12 cells. J. Agric. Food Chem. 63, 1521–1531. https://doi.org/10.1021/jf505075n (2015).
Kim, S. S. et al. Licochalcone E activates Nrf2/antioxidant response element signaling pathway in both neuronal and microglial cells: therapeutic relevance to neurodegenerative disease. J. Nutr. Biochem. 23, 1314–1323. https://doi.org/10.1016/j.jnutbio.2011.07.012 (2012).
Wu, K. C., McDonald, P. R., Liu, J. & Klaassen, C. D. Screening of natural compounds as activators of the keap1-nrf2 pathway. Planta Med. 80, 97–104. https://doi.org/10.1055/s-0033-1351097 (2014).
Shibuya, A. et al. Sofalcone, a gastric mucosa protective agent, increases vascular endothelial growth factor via the Nrf2-heme-oxygenase-1 dependent pathway in gastric epithelial cells. Biochem. Biophys. Res. Commun. 398, 581–584. https://doi.org/10.1016/j.bbrc.2010.06.124 (2010).
Lee, S. H. et al. 2’,4’,6’-tris(methoxymethoxy) chalcone protects against trinitrobenzene sulfonic acid-induced colitis and blocks tumor necrosis factor-alpha-induced intestinal epithelial inflammation via heme oxygenase 1-dependent and independent pathways. Biochem. Pharmacol. 74, 870–880. https://doi.org/10.1016/j.bcp.2007.06.034 (2007).
Wei, J. et al. Nrf2 exerts cell-autonomous antifibrotic effects: compromised function in systemic sclerosis and therapeutic rescue with a novel heterocyclic chalcone derivative. Transl. Res. 183, 71-86 e71. https://doi.org/10.1016/j.trsl.2016.12.002 (2017).
Li, X., Vogt, F., Hayes, D. J. & Mansour, H. M. Design, characterization, and aerosol dispersion performance modeling of advanced spray-dried microparticulate/nanoparticulate mannitol powders for targeted pulmonary delivery as dry powder inhalers. J. Aerosol Med. Pulm. Drug Deliv. 27, 81–93 (2014).
Xu, Z., Mansour, H. M. & Hickey, A. J. Particle interactions in dry powder inhaler unit processes. J. Adhes. Sci. Technol. 25, 451–482 (2011).
Praphawatvet, T., Peters, J. I. & Williams, R. O. 3rd. Inhaled nanoparticles—an updated review. Int. J. Pharm. 587, 119671. https://doi.org/10.1016/j.ijpharm.2020.119671 (2020).
Muralidharan, P., Malapit, M., Mallory, E., Hayes, D. J. & Mansour, H. M. Inhalable nanoparticulate powders for respiratory delivery. Nanomed. Nanotechnol. Biol. Med. 11, 1189–1199 (2015).
Li, X., Vogt, F. G., Hayes, D. Jr. & Mansour, H. M. Design, characterization, and aerosol dispersion performance modeling of advanced co-spray dried antibiotics with mannitol as respirable microparticles/nanoparticles for targeted pulmonary delivery as dry powder inhalers. J. Pharm. Sci. https://doi.org/10.1002/jps.23955 (2014).
Meenach, S. A., Anderson, K. W., Zach Hilt, J., McGarry, R. C. & Mansour, H. M. Characterization and aerosol dispersion performance of advanced spray-dried chemotherapeutic PEGylated phospholipid particles for dry powder inhalation delivery in lung cancer. Eur. J. Pharm. Sci. 49, 699–711. https://doi.org/10.1016/j.ejps.2013.05.012 (2013).
Meenach, S. A. et al. Design, physicochemical characterization, and optimization of organic solution advanced spray-dried inhalable dipalmitoylphosphatidylcholine (DPPC) and dipalmitoylphosphatidylethanolamine poly(ethylene glycol) (DPPE-PEG) microparticles and nanoparticles for targeted respiratory nanomedicine delivery as dry powder inhalation aerosols. Int. J. Nanomed. 8, 275–293. https://doi.org/10.2147/IJN.S30724 (2013).
Meenach, S. A., Anderson, K. W., Hilt, J. Z., McGarry, R. C. & Mansour, H. M. High-performing dry powder inhalers of paclitaxel DPPC/DPPG lung surfactant-mimic multifunctional particles in lung cancer: physicochemical characterization, in vitro aerosol dispersion, and cellular studies. AAPS PharmSciTech 15, 1574–1587. https://doi.org/10.1208/s12249-014-0182-z (2014).
In USP 29-NF 24 The United States Pharmacopoeia and The National Formulary: The Official Compendia of Standards Vol. 29/24 2617–2636 (The United States Pharmacopeial Convention, Inc., 2006).
Acosta, M. F. et al. In vitro pulmonary cell culture in pharmaceutical inhalation aerosol delivery: 2-D, 3-D, and in situ bioimpactor models. Curr. Pharm. Des. 22, 2522–2531 (2016).
Meenach, S. A., Anderson, K. W., Hilt, J. Z., McGarry, R. C. & Mansour, H. M. Characterization and aerosol dispersion performance of advanced spray-dried chemotherapeutic PEGylated phospholipid particles for dry powder inhalation delivery in lung cancer. Eur. J. Pharm. Sci. 49, 699–711 (2013).
Meenach, S. A. et al. Development of three-dimensional lung multicellular spheroids in air- and liquid-interface culture for the evaluation of anticancer therapeutics. Int. J. Oncol. 48, 1701–1709. https://doi.org/10.3892/ijo.2016.3376 (2016).
Acknowledgements
The authors gratefully acknowledge financial support from the College of Pharmacy graduate student fellowship awarded to PM. This work was partially supported by a Maryland TEDCO (Technology Development Corporation) grant award to Curveda LLC, NIH NHLBI R41HL122004 (Cureveda LLC), NIH NIAMS R41AR066418 (Cureveda LLC), NIH NIDDK R43DK098984 (Cureveda LLC), NIH NIAID HHSN2272201000033I/HHSN27200002 A65 (HMM), NIH NIA R21AG054766 (HMM), and NIH NHLBI R01HL137282 (HMM). SEM images and data were collected in the W.M. Keck Center for Nano-Scale Imaging in the Department of Chemistry and Biochemistry at the University of Arizona with funding from the W.M. Keck Foundation Grant. All Raman data was collected in the Imaging Cores—Materials Imaging and Characterization Facility supported by the office of Research, Discovery and Innovation at the University of Arizona. This material is based upon work supported by the National Science Foundation under Grant Number #0619599 and Arizona Proposition 301: Technology and Research Initiative Fund (A.R.S.§15-1648). X-ray diffraction data were collected in the X-Ray Diffraction Facility of the Department of Chemistry and Biochemistry, The University of Arizona. The authors sincerely thank Dr. Brooke Beam-Masani, Dr. Paul Wallace and Dr. Andrei Astachkine for core facility access and assistance.
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Muralidharan, P., Jones, B., Allaway, G. et al. Design and development of innovative microparticulate/nanoparticulate inhalable dry powders of a novel synthetic trifluorinated chalcone derivative and Nrf2 agonist. Sci Rep 10, 19771 (2020). https://doi.org/10.1038/s41598-020-76585-2
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DOI: https://doi.org/10.1038/s41598-020-76585-2
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