Nanoscale colocalized thermal and chemical mapping of pharmaceutical powder aerosols.

Inhalation of pharmaceutical aerosol formulations is widely used to treat respiratory diseases. Spatially resolved thermal characterization offers promise for better understanding drug release rates from particles; however, this has been an analytical challenge due to the small particle size (from a few micrometers down to nanometers) and the complex composition of the formulations. Here, we employ nano-thermal analysis (nanoTA) to probe the nanothermal domain of a pharmaceutical aerosol formulation containing a mixture of fluticasone propionate (FP), salmeterol xinafoate (SX), and excipient lactose, which is widely used to treat asthma and chronic obstructive pulmonary disease (COPD). Furthermore, atomic force microscopy-infrared spectroscopy (AFM-IR) and AFM force measurements are performed to provide nanochemical and nanomechanical information to complement the nanothermal data. The colocalized thermal and chemical mapping clearly reveals the surface heterogeneity of the drugs in the aerosol particles and demonstrates the contribution of the surface chemical composition to the variation in the thermal properties of the particles. We present a powerful analytical approach for in-depth characterization of thermal/chemical/morphological properties of dry powder inhaler particles at micro- and nanometer scales. This approach can be used to facilitate the comparison between generics and reference inhalation products and further the development of high-performance pharmaceutical formulations.

Stability of bacteriophages in organic solvents for formulations.

Bacteriophages or phages used as an alternative therapy for treating multi-drug resistant infections require formulation consideration. Current strategies to produce phage formulations involving organic solvents are based on empirical practices without a good understanding of phage stability during formulation development. In this study, we investigated the effect of common formulation organic solvents (ethanol, isopropyl alcohol, tetrahydrofuran (THF) and dimethyl sulfoxide (DMSO)) on the stability of Pseudomonas aeruginosa-specific myovirus (PEV1, PEV20) and podovirus (PEV31) phages using biological assay, transmission electron microscopy (TEM) and scattering near field optical microscopy (SNOM). The three phages were mixed with the solvents at different concentrations (25%, 50%, and 75% (v/v)) for 20 min. All phages were fully viable in the organic solvents at 25% (v/v) showing negligible titre changes. At the higher solvent concentration of 50% (v/v), the myoviruses PEV1 and PEV20 remained relatively stable (titre loss 0.4-1.3 log10), whereas the podovirus PEV31 became less stable (titre loss 0.25-3.8 log10), depending on the solvent used. Increasing the solvent level to 75% (v/v) caused increased morphological changes in TEM and decreased viability as indicated by the titre loss (0.32-7.4 log10), with DMSO being the most phage-destabilising solvent. SNOM spectra showed differences in the signal intensity and peak positions in the amide I and amide II regions, revealing altered phage proteins by the solvents. In conclusion, the choice of the solvents for phage formulation depends on both the phages and solvent types. Our results showed (1) the phages are more stable in the alcohols than DMSO and THF, and (2) the myoviruses tend to be more stable than the podovirus in the solvents. Overall, a low to moderate (25-50 % v/v) level of organic solvents (except 50% THF) can be used in formulation of the phages without a substantial titre loss.

Bacteriophage endolysin powders for inhaled delivery against pulmonary infections.

Endolysins are bacteriophage-encoded enzymatic proteins that have great potential to treat multidrug-resistant bacterial infections. Bacteriophage endolysins Cpl-1 and ClyJ-3 have shown promising antimicrobial activity against Streptococcus pneumoniae, which causes pneumonia in humans. This is the first study to investigate the feasibility of spray-dried endolysins Cpl-1 and ClyJ-3 with excipients to produce inhalable powders. The two endolysins were individually tested with leucine and sugar (lactose or trehalose) for spray drying method followed by characterization of biological and physico-chemical properties. A complete loss of ClyJ-3 bioactivity was observed after atomization of the liquid feed solution（before the drying process）, while Cpl-1 maintained its bioactivity in the spray-dried powders. Cpl-1 formulations containing leucine with lactose or trehalose showed promising physico-chemical properties (particle size, crystallinity, hygroscopicity, etc.) and aerosol performances (fine particle fraction values above 65%). The results indicated that endolysin Cpl-1 can be formulated as spray dried powders suitable for inhaled delivery to the lungs for the potential treatment of pulmonary infections.

Applications of AFM-IR for drug delivery vector characterization: infrared, thermal, and mechanical characterization at the nanoscale.

The development of effective drug delivery systems requires in-depth characterization of the micro- or nanostructure of the material vectors with high spatial resolution, resulting in a deep understanding of the design-function relationship and maximum therapeutic efficacy. Atomic force microscopy-infrared spectroscopy (AFM-IR) combines the high spatial resolution of AFM and the capabilities of IR spectroscopy to identify chemical composition and it has emerged as a powerful tool for the detailed characterization of a drug delivery system at the nanoscale. In addition, the instruments also allow thermal and mechanical evaluation at the nanoscale. In this review, we highlight the applications of AFM-IR in various drug delivery systems, including polymer-based carriers, lipid-contained nanocarriers, and metal-based nanocarriers. The existing challenges as well as the future perspectives for the application of AFM-IR for drug delivery vector characterization are also discussed.

Optical photothermal infrared spectroscopy for nanochemical analysis of pharmaceutical dry powder aerosols.

The aim of this research was to chemically analyse the distribution of drugs and excipients in pharmaceutical dry powder inhalation (DPI) aerosol particles of various sizes in solid state. The conventional wet assay of the chemical composition of particles after collection in a cascade impactor lacks the capability to differentiate spatially resolved morphology and chemical composition of particles in complex DPI formulations. In this proof-of-concept study, we aim to demonstrate the feasibility of using optical photothermal infrared spectroscopy (O-PTIR) to characterize micro- to nano-scale chemical composition of size-segregated particles of pharmaceutical DPI formulations. These formulations were prepared by spray drying a solution or a suspension comprising an inhaled corticosteroid fluticasone propionate, a long-acting ß2-agonist salmeterol xinafoate, and excipient lactose. The active ingredients fluticasone propionate and salmeterol xinafoate are widely used for the treatment of asthma and chronic obstructive pulmonary disease. Spatially resolved O-PTIR spectra acquired from the particles collected from stages 1-7 of a Next Generation Impactor (NGI) for both formulations confirmed the presence of peaks related to fluticasone propionate (1746 cm-1, 1702 cm-1, 1661 cm-1 and 1612 cm-1), salmeterol xinafoate (1582 cm-1), and lactose (1080 cm-1). There was no significant difference in the drug to lactose peak ratio among various size fractions of particles spray dried from solution indicating a homogeneity in drug and lactose content in the aerosol formulation. In contrast, the suspension-spray dried formulation showed the drug content increased while the lactose content decreased in the particles collected down the NGI from stage 1 to stage 7, indicating heterogeneity in the ratio of drug-excipient distribution. The qualitative chemical compositions from O-PTIR were comparable to conventional wet chemical assays of various size fractions, indicating the suitability of O-PTIR to serve as a valuable analytical platform for screening the physicochemical properties of DPIs in solid state.

Preparation and Characterization of Inhalable Ivermectin Powders as a Potential COVID-19 Therapy.

Background: Ivermectin has received worldwide attention as a potential COVID-19 treatment after showing antiviral activity against SARS-CoV-2 in vitro. However, the pharmacokinetic limitations associated with oral administration have been postulated as limiting factors to its bioavailability and efficacy. These limitations can be overcome by targeted delivery to the lungs. In this study, inhalable dry powders of ivermectin and lactose crystals were prepared and characterized for the potential treatment of COVID-19. Methods: Ivermectin was co-spray dried with lactose monohydrate crystals and conditioned by storage at two different relative humidity points (43% and 58% RH) for a week. The in vitro dispersion performance of the stored powders was examined using a medium-high resistance Osmohaler connecting to a next-generation impactor at 60 L/min flow rate. The solid-state characteristics including particle size distribution and morphology, crystallinity, and moisture sorption profiles of raw and spray-dried ivermectin samples were assessed by laser diffraction, scanning electron microscopy, Raman spectroscopy, X-ray powder diffraction, thermogravimetric analysis, differential scanning calorimetry, and dynamic vapor sorption. Results: All the freshly spray-dried formulation (T0) and the conditioned samples could achieve the anticipated therapeutic dose with fine particle dose of 300 µg, FPFrecovered of 70%, and FPFemitted of 83%. In addition, the formulations showed a similar volume median diameter of 4.3 µm and span of 1.9. The spray-dried formulations were stable even after conditioning and exposing to different RH points as ivermectin remained amorphous with predominantly crystalline lactose. Conclusion: An inhalable and stable dry powder of ivermectin and lactose crystals was successfully formulated. This powder inhaler ivermectin candidate therapy appears to be able to deliver doses that could be safe and effective to treat the SARS-COV-2 infection. Further development of this therapy is warranted.

Raman spectroscopic evaluation of crystallinity, chemical composition and stability of pharmaceutical powder aerosols.

Raman spectroscopy was used to evaluate the effects of temperature and humidity on the physicochemical stability of inhalable spray-dried (SD) powders containing budesonide (BUD) and crystalline or amorphous lactose. Powders prepared by spray drying of BUD-lactose solution or suspension containing lactose crystals in BUD solution were stored for 0, 1 and 7 days at 25 °C/60 RH or 40 °C/75 RH. Bulk powders along with the large and small particle size fractions collected on stages 2 and 5, respectively, of the Next Generation Impactor (NGI) were chemically characterised. SD powder from solution contained BUD and lactose in amorphous form and both components were homogeneously distributed in bulk and in the particles collected from the two NGI stages. In contrast, SD powder from suspension showed heterogeneous distribution of lactose and drug in the particles containing crystalline lactose. After 1 day of storage at either condition, recrystallisation and changes in the chemical composition of the particles for the SD powder from solution occurred. The number of drug-only particles increased by 70 on stage 5, whereas most particles on stage 2 still contained both drug and lactose. These changes were not observed in the SD powder from suspension after storage, confirming superior stability of the SD powder obtained from suspension.

Enteric-coated bacteriophage tablets for oral administration against gastrointestinal infections.

Intestinal Pseudomonas aeruginosa is highly problematic in immunocompromised patients such as those in intensive care units in hospitals. Phage therapy is an attractive alternative or supplementary therapy to antibiotics as it not only kills multidrug-resistant bacteria, but also minimises the disruption of gut microflora. Solid oral dosage forms (i.e., tablets) have the potential to effectively deliver viable phages to the gastrointestinal tract, but formulation studies have been scarce. In this study, Pseudomonas-targeting phage PEV20 was used as a model to produce tablets suitable for oral delivery by utilising industry-scale tablet compression and tablet coating machines. Phage tablets were produced by (i) spray drying of phages, (ii) direct compression of the phage powders into tablets, and then (iii) tablet coating. The resulting phage tablets had negligible phage titre reduction throughout the process and passed the British Pharmacopeia tests, including friability, weight variation, disintegration and dissolution of the tablets as well as weight gain and disintegration (in 0.1 M HCl and pH 7.4 phosphate buffer) of coated tablets. The developed formulation method can be utilised to produce tablets containing other phages and phage cocktails that are effective against enteric bacterial infections.

Co-spray dried hydrophobic drug formulations with crystalline lactose for inhalation aerosol delivery.

Spray drying is a rapid method for converting a liquid feed into dried particles for inhalation aerosols. Lactose is a major inhalation excipient used in spray-dried (SD) formulations. However, SD powders produced from solutions are usually amorphous hence unstable to moisture. This problem can potentially be minimized by spray drying a suspension (instead of solution) containing crystalline lactose particles and dissolved drugs. In the present study, the suspension formulation containing dissolved budesonide (BUD) or rifampicin (RIF) and suspended lactose crystals in isopropanol alcohol (IPA) were produced. For comparison, powders were also produced from solution formulations containing the same proportions of drug and lactose dissolved in 50:50 IPA/water as controls. These SD powders were stored at 25 °C/60% RH and 40 °C/75% RH for six months. The particulate properties and in vitro dispersion performance were examined at various storage time points. All powders obtained from spray drying of solutions recrystallized after one week of storage at 25 °C/60% RH. In contrast, SD BUD-lactose obtained from suspension did not change until after three-months of storage when the particle size increased gradually with morphology change and yet the crystallinity remained the same as determined by X-ray powder diffraction. For the SD RIF-lactose obtained from suspension, both particulate properties and in vitro powder dispersion performance showed no significant difference before and after storage at both storage conditions. To conclude, this is the first study to show that SD powder formulations obtained from suspensions containing lactose crystals demonstrated superior storage stability performance, which is desirable for inhaled powders.

Dry powder pharmaceutical biologics for inhalation therapy.

Therapeutic biologics such as genes, peptides, proteins, virus and cells provide clinical benefits and are becoming increasingly important tools in respiratory medicine. Pulmonary delivery of therapeutic biologics enables the potential for safe and effective treatment option for respiratory diseases due to high bioavailability while minimizing absorption into the systemic circulation, reducing off-target toxicity to other organs. Development of inhalable powder formulation requires stabilization of complex biological materials, and each type of biologics may present unique challenges and require different formulation strategy combined with manufacture process to ensure biological and physical stabilities during production and over shelf-life. This review examines key formulation strategies for stabilizing proteins, nucleic acids, virus (bacteriophages) and bacterial cells in inhalable powders. It also covers characterization methods used to assess physicochemical properties and aerosol performance of the powders, biological activity and structural integrity of the biologics, and chemical analysis at the nanoscale. Furthermore, the review includes manufacture technologies which are based on lyophilization and spray-drying as they have been applied to manufacture Food and Drug Administration (FDA)-approved protein powders. In perspective, formulation and manufacture of inhalable powders for biologic are highly challenging but attainable. The key requirements are the stability of both the biologics and the powder, along with the powder dispersibility. The formulation to be developed depends on the manufacture process as it will subject the biologics to different stresses (temperature, mechanical and chemical) which could lead to degradation by different pathways. Stabilizing excipients coupled with the suitable choice of process can alleviate the stability issues of inhaled powders of biologics.

Can bacteriophage endolysins be nebulised for inhalation delivery against Streptococcus pneumoniae?

Endolysins are bacteriophage-derived protein molecules highly effective for bacterial killing. Cpl-1 and ClyJ-3 are native and chimeric endolysins, respectively, having antimicrobial activity against Streptococcus pneumoniae which causes lung infections. We conducted the first feasibility study on nebulisation of Cpl-1 and ClyJ-3, with a focus on the antimicrobial activity, structural changes of the proteins and aerosol performance. Bacterial colony counts, live cell imaging and Fourier-transform infrared(FTIR) spectroscopy were used to evaluate the proteins before and after jet or vibrating mesh nebulisation. These nebulised aerosols were inhalable with a volume median size of 3.8-4.2 µm (span 1.1-2.3) measured by laser diffraction. How-ever, neb-u-li-sa-tion caused al-most com-plete loss in bioac-tiv-ity of ClyJ-3, which were corroborated with the live cell imaging observation and protein structural damage with a large intensity reduction in the amide absorption bands between 1300 and 1700 cm-1. In contrast, the bactericidal activity of Cpl-1 showed no significant difference (p ≥ 0.05) before and after mesh nebulisation with 4.9 and 4.6-log10 bacterial count reduction, respectively. However, jet nebulisation reduced the bioactivity of Cpl-1 and the effect was time-dependent showing 1.7, 1.0-log10 bacterial count reduction at 7 and 14 min with complete loss of antimicrobial activity at 21 min after nebulisation, respectively. The results were consistent with time-dependent changes in live cell images and FTIR amide band changes at 1655, 1640, 1632 and 1548 cm-1. In conclusion, it is feasible to nebulise endolysins for inhalation delivery but it depends on both the protein and the nebuliser, with the mesh nebuliser being the preferred choice.

Nanoscale Probing of Liposome Encapsulating Drug Nanocrystal Using Atomic Force Microscopy-Infrared Spectroscopy.

Use of liposomes encapsulating drug nanocrystals for the treatment of diseases like cancer and pulmonary infections is gaining attention. The potential therapeutic benefit of these engineered formulations relies on maintaining the physical integrity of the liposomes and the stability of the encapsulated drug. With the significant advancement in the microscopic and analytical techniques, analysis of the size and size distribution of these nanosized vesicles is possible. However, due to the limited spatial resolution of conventional vibrational spectroscopy techniques, the chemical composition of individual nanosized liposome cannot be resolved. To address this limitation, we applied atomic force microscopy infrared spectroscopy (AFM-IR) to assess the chemical composition of individual liposomes encapsulating ciprofloxacin in dissolved and nanocrystalline form. Spatially resolved AFM-IR spectra acquired from individual liposomes confirmed the presence of peaks related to N-H bending vibration, C-N stretching and symmetric, and asymmetric vibration of the carboxyl group present in the ciprofloxacin. Our results further demonstrated the effectiveness of AFM-IR in differentiating the liposome containing ciprofloxacin in dissolved or nanocrystalline form. Spectra acquired from dissolved ciprofloxacin had peaks related to the ionised carboxyl group, i.e., at 1576 and 1392 cm-1, which were either absent or far weaker in intensity in the spectra of liposomal sample containing ciprofloxacin nanocrystals. These findings are highly significant for pharmaceutical scientists to ascertain the stability and physicochemical composition of individual liposomes and will facilitate the design and development of liposomes with greater therapeutic benefits.

Inhalable bacteriophage powders: Glass transition temperature and bioactivity stabilization.

Recent heightened interest in inhaled bacteriophage (phage) therapy for combating antibacterial resistance in pulmonary infections has led to the development of phage powder formulations. Although phages have been successfully bioengineered into inhalable powders with preserved bioactivity, the stabilization mechanism is yet unknown. This paper reports the first study investigating the stabilization mechanism for phages in these powders. Proteins and other biologics are known to be preserved in dry state within a glassy sugar matrix at storage temperatures (T s) at least ~50°C below the glass transition temperature (T g). This is because at (T g - T s) >50°C, molecules are sufficiently immobilized with reduced reactivity. We hypothesized that this glass stabilization mechanism may also be applicable to phages comprising mostly of proteins. In this study, spray dried powders of Pseudomonas phage PEV20 containing lactose and leucine as excipients were stored at 5, 25 or 50°C and 15 or 33% relative humidity (RH), followed by assessment of bioactivity (PEV20 stability) and physical properties. PEV20 was stable with negligible titer loss after storage at 5°C/15% RH for 250 days, while storage at 33% RH caused increased titer losses of 1 log10 and 3 log10 at 5 and 25°C, respectively. The plasticizing effect of water at 33% RH lowered the T g by 30°C, thus narrowing the gap between T s and T g to 19-28°C, which was insufficient for glass stabilization. In contrast, the (T g - T s) values were higher (range, 46-65°C) under the drier condition of 15% RH, resulting in the improved stability which corroborated with the vitrification hypothesis. Furthermore, phage remained stable (≤1 log10) when the (T g - T s) value lay between 26-48°C, but became inactivated as the value fell below 20°C. In conclusion, this study demonstrated that phage can be sufficiently stabilized in spray dried powders by keeping the (T g - T s) value above 46°C, thus supporting the vitrification hypothesis that phages are stabilized by immobilization inside a rigid glassy sugar matrix. These findings provide a guide to better manufacture and storage practices of inhaled phage powder products using for translational medicines.

Bulk to Nanometer-Scale Infrared Spectroscopy of Pharmaceutical Dry Powder Aerosols.

Solid state chemical analysis of pharmaceutical inhalation aerosols at the individual particle level has been an analytical challenge. These particles can range from a few nanometers to micrometers and are a complex mixture of drugs and excipients. Conventional analytical techniques cannot resolve the distribution of excipients and drugs at the submicrometer scale. Understanding the nanochemical composition of individual particles can be critical for pharmaceutical scientists to evaluate drug and excipient stability as well as the drug-drug or drug-excipient interactions that affect the aerosol performance of powders. Herein, we show the novel application of a combination of optical photothermal infrared (O-PTIR) spectroscopy and atomic force microscopy infrared (AFM-IR) spectroscopy to probe nanochemical domains of powders containing the inhaled corticosteroid fluticasone propionate and long-acting ß2-agonist salmeterol xinafoate, which are widely used to treat asthma and chronic obstructive pulmonary disease. Three types of powder formulation were analyzed, including the commercial product Seretide, which is a physical mixture of the drugs with crystalline lactose, and two spray-dried powders containing the drugs along with either amorphous or crystalline lactose. We obtained spatially resolved O-PTIR and AFM-IR spectra confirming the presence of peaks related to fluticasone propionate at 1743, 1661, and 1700 cm-1, salmeterol xinafoate at 1580 cm-1, and lactose at 1030 and 1160 cm-1. The location of the drugs and lactose among the particles varied significantly, depending on the formulation type. For the first time, it was possible to map the drug distribution in individual aerosol particles. This is significant as such information has been lacking, and it will open an exciting research direction on how drug distribution affects the aerosol performance of powders and the consistency of dose uniformity. Further, these advanced spectroscopic techniques can be applied to study a wide range of pharmaceutical formulations.

Stimuli-sensitive fatty acid-based microparticles for the treatment of lung cancer.

Despite recent advancements in medicine, lung cancer still lacks an effective therapy. In the present study we have decided to combine superparamagnetic iron oxide nanoparticles (SPION) with solid lipid microparticles to develop novel, stimuli-sensitive drug carriers that increase the bioavailability of the anticancer drug (paclitaxel - PAX) through guided accumulation directly at the tumour site and controlled drug delivery. SPION and PAX-loaded microparticles (MPs) were fabricated from lauric acid (LAU) and a mixture of myristic and palmitic acids (MYR/PAL) using hot oil-in-water emulsification method. MP size, surface properties, melting temperature and magnetic mobility were evaluated along with their in vitro efficacy against malignant lung epithelial cells (A549). MPs were spherical in shape with the average particle size between 2 and 3.5 µm and responded to external magnetic field up to the distance of 15 mm. MPs were effectively internalised by the cells. Unloaded or NP-loaded MPs were cytocompatible with A549 cells, while NP + PAX-loaded MPs significantly decreased cell viability and effectively suppressed colony formation. The developed stimuli-sensitive, inhalable MPs have shown promising results as PAX carriers for controlled pulmonary delivery for the treatment of lung cancer.

Distinct Influence of Saturated Fatty Acids on Malignant and Nonmalignant Human Lung Epithelial Cells.

The impact of saturated fatty acids (FA) on viability and properties of malignant and nonmalignant cells has not been studied in detail so far. The present study was aimed at evaluation of the influence of saturated FA (10:0-18:0) on malignant (A459) and nonmalignant (BEAS-2B) human lung epithelial cells. FA strongly affected A549 cells, but not BEAS-2B cells. Viability of A549 cells incubated with 14:0-18:0 was decreased by 53-91% as compared to untreated cells. Cell membrane stiffness in those cells as measured by atomic force microscopy was also reduced. Median value of apparent Young's modulus of untreated A549 cell membrane was 16.9 kPa and it decreased to 8.9 kPa for cells incubated with 14:0. Viability and mechanical properties of BEAS-2B cells were not altered by presence of FA. Those surprising discrepancies can be related to the differences in FA uptake rate. A549 cells were found to incorporate higher amount of FA and this corresponded to decrease in cell membrane stiffness and reduced cell viability. The performed studies showed that saturated FA have distinct influence on various types of cells, which may be exploited in development of the advanced lipid drug delivery systems.

The protein corona determines the cytotoxicity of nanodiamonds: implications of corona formation and its remodelling on nanodiamond applications in biomedical imaging and drug delivery.

The use of nanodiamonds for biomedical and consumer applications is growing rapidly. As their use becomes more widespread, so too do concerns around their cytotoxicity. The cytotoxicity of nanodiamonds correlates with their cellular internalisation and circulation time in the body. Both internalisation and circulation time are influenced by the formation of a protein corona on the nanodiamond surface. However, a precise understanding of both how the corona forms and evolves and its influence on cytotoxicity is lacking. Here, we investigated protein corona formation and evolution in response to two classes of nanodiamonds, pristine and aminated, and two types of proteins, bovine serum albumin and fibronectin. Specifically, we found that a corona made of bovine serum albumin (BSA), which represents the most abundant protein in blood plasma, reduced nanodiamond agglomeration. Fibronectin (FN9-10), the second most abundant protein found in the plasma, exhibited a significantly higher nanodiamond binding affinity than BSA, irrespective of the nanodiamond surface charge. Finally, nanodiamonds with a BSA corona displayed less cytotoxicity towards nonphagocytic liver cells. However, regardless of the type of corona (FN9-10 or BSA), both classes of nanodiamonds induced substantial phagocytic cell death. Our results emphasise that a precise understanding of the corona composition is fundamental to determining the fate of nanoparticles in the body.

High Resolution Nanoscale Probing of Bacteriophages in an Inhalable Dry Powder Formulation for Pulmonary Infections.

Use of powder phage formulations for the treatment of multiple-drug-resistant pulmonary infections is gaining attention. To achieve therapeutic benefits, it is critical for phages to remain stable in the formulation. Assessment of phage stability relies on plaque assay (bioactivity), which requires powder samples to be reconstituted in liquid. The purpose of this study was to develop an innovative approach using photothermal-induced resonance-enhanced atomic force microscopy infrared spectroscopy (AFM-IR) to assess the presence of phages and investigate their protein conformation in the solid state. Staphylococcal phage S83 was spray-dried with lactose and sodium stearate using spray-drying. The phage powder recrystallized at 60% relative humidity (RH), so it was stored and handled below this RH. For the AFM-IR measurements, spray-dried Staphylococcal phage Sa83 powder was embedded in resin, followed by microtome sectioning. AFM-IR spectra collected from different regions within the microtomed sections revealed the presence of phage proteins with amide I and amide II bands at 1640 and 1550 cm-1, respectively. The phages were confirmed to be stable, as the plaque assay showed negligible titer reduction after spray-drying. Our results thus demonstrated the utility of AFM-IR for characterization of nanosized phages present in extremely low quantity in spray-dried particles. These biologically active phages were shown to retain their physical and chemical integrity in the spray-dried particles.

Biological impact of nanodiamond particles - label free, high-resolution methods for nanotoxicity assessment.

Current methods for the assessment of nanoparticle safety that are based on 2D cell culture models and fluorescence-based assays show limited sensitivity and they lack biomimicry. Consequently, the health risks associated with the use of many nanoparticles have not yet been established. There is a need to develop in vitro models that mimic physiology more accurately and enable high throughput assessment. There is also a need to set up new assays that offer high sensitivity and are label-free. Here we developed 'mini-liver' models using scaffold-free bioprinting and used these models together with label-free nanoscale techniques for the assessment of toxicity of nanodiamond produced by laser-assisted technology. Results showed that NDs induced cytotoxicity in a concentration and exposure-time dependent manner. The loss of cell function was confirmed by increased cell stiffness, decreased cell membrane barrier integrity and reduced cells mobility. We further showed that NDs elevated the production of reactive oxygen species and reduced cell viability. Our approach that combined mini-liver models with label-free high-resolution techniques showed improved sensitivity in toxicity assessment. Notably, this approach allowed for label-free semi-high throughput measurements of nanoparticle-cell interactions, thus could be considered as a complementary approach to currently used methods.

Placenta Stem/Stromal Cell-Derived Extracellular Vesicles for Potential Use in Lung Repair.

Many acute and chronic lung injuries are incurable and rank as the fourth leading cause of death globally. While stem cell treatment for lung injuries is a promising approach, there is growing evidence that the therapeutic efficacy of stem cells originates from secreted extracellular vesicles (EVs). Consequently, EVs are emerging as next-generation therapeutics. While EVs are extensively researched for diagnostic applications, their therapeutic potential to promote tissue repair is not fully elucidated. By housing and delivering tissue-repairing cargo, EVs refine the cellular microenvironment, modulate inflammation, and ultimately repair injury. Here, the potential use of EVs derived from two placental mesenchymal stem/stromal cell (MSC) lines is presented; a chorionic MSC line (CMSC29) and a decidual MSC cell line (DMSC23) for applications in lung diseases. Functional analyses using in vitro models of injury demonstrate that these EVs have a role in ameliorating injuries caused to lung cells. It is also shown that EVs promote repair of lung epithelial cells. This study is fundamental to advancing the field of EVs and to unlock the full potential of EVs in regenerative medicine.