Your search keyword '"Robert O. Williams"' showing total 309 results

1. The applications of machine learning to predict the forming of chemically stable amorphous solid dispersions prepared by hot-melt extrusion

Author

Junhuang Jiang, Anqi Lu, Xiangyu Ma, Defang Ouyang, and Robert O. Williams, III

Subjects

Amorphous Solid Dispersion, Artificial Intelligence, Machine Learning, Hot-Melt Extrusion, Pharmacy and materia medica, RS1-441

Abstract

Amorphous solid dispersion (ASD) is one of the most important strategies to improve the solubility and dissolution rate of poorly water-soluble drugs. As a widely used technique to prepare ASDs, hot-melt extrusion (HME) provides various benefits, including a solvent-free process, continuous manufacturing, and efficient mixing compared to solvent-based methods, such as spray drying. Energy input, consisting of thermal and specific mechanical energy, should be carefully controlled during the HME process to prevent chemical degradation and residual crystallinity. However, a conventional ASD development process uses a trial-and-error approach, which is laborious and time-consuming. In this study, we have successfully built multiple machine learning (ML) models to predict the amorphization of crystalline drug formulations and the chemical stability of subsequent ASDs prepared by the HME process. We utilized 760 formulations containing 49 active pharmaceutical ingredients (APIs) and multiple types of excipients. By evaluating the built ML models, we found that ECFP-LightGBM was the best model to predict amorphization with an accuracy of 92.8%. Furthermore, ECFP-XGBoost was the best in estimating chemical stability with an accuracy of 96.0%. In addition, the feature importance analyses based on SHapley Additive exPlanations (SHAP) and information gain (IG) revealed that several processing parameters and material attributes (i.e., drug loading, polymer ratio, drug's Extended-connectivity fingerprints (ECFP) fingerprints, and polymer's properties) are critical for achieving accurate predictions for the selected models. Moreover, important API's substructures related to amorphization and chemical stability were determined, and the results are largely consistent with the literature. In conclusion, we established the ML models to predict formation of chemically stable ASDs and identify the critical attributes during HME processing. Importantly, the developed ML methodology has the potential to facilitate the product development of ASDs manufactured by HME with a much reduced human workload.

Published

2023

2. The Development of Thin-Film Freezing and Its Application to Improve Delivery of Biologics as Dry Powder Aerosols

Author

Stephanie Hufnagel, Sawittree Sahakijpijarn, Chaeho Moon, Zhengrong Cui, and Robert O. Williams III

Subjects

thin-film freezing, dry powder, cryogenic technique, protein, pulmonary delivery, Technology (General), T1-995, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

While the formulation of pharmaceuticals as liquids is common practice, powders are associated with enhanced stability, avoidance of the cold chain, lower dosing requirements, and more convenient administration. These are particularly critical for proteins, as they are expensive and complicated to manufacture. Powders also have improved aerosol properties for pulmonary delivery. Conventional techniques for formulating powders include spray-drying, shelf freeze-drying, spray freeze-drying, and spray freezing into liquid, but they produce powders with poor aerosol performance and/or activity due to suboptimal powder properties. Thin-film freezing (TFF) is a new cryogenic technique that can engineer highly porous, brittle, powder matrices with excellent aerosol performance properties and stability. Herein, we describe TFF in comparison to other cryogenic techniques. Physical properties of TFF powders such as morphology, moisture sorption, stability, solubility, and dissolution, as well as aerosol properties are discussed. In addition, factors that significantly affect the physical and aerosol properties of dry powders prepared by TFF, such as solids content, drug loading, solvent system, excipient, and dry powder delivery device, are analyzed. Finally, we provide evidence supporting the applicability of using TFF to prepare dry powder formulations of protein-based pharmaceuticals, enabling their cold chain-free storage as well as efficient pulmonary delivery.

Published

2021

3. Pre-Processing a Polymer Blend into a Polymer Alloy by KinetiSol Enables Increased Ivacaftor Amorphous Solid Dispersion Drug Loading and Dissolution

Author

Stephen A. Thompson, Daniel A. Davis, Dave A. Miller, Sandra U. Kucera, and Robert O. Williams

Subjects

ivacaftor, amorphous solid dispersion, polymer, polymer alloy, drug loading, Kalydeco, Biology (General), QH301-705.5

Abstract

This study compares the effects of pre-processing multiple polymers together to form a single-phase polymer alloy prior to amorphous solid dispersion formulation. KinetiSol compounding was used to pre-process a 1:1 (w/w) ratio of hypromellose acetate succinate and povidone to form a single-phase polymer alloy with unique properties. Ivacaftor amorphous solid dispersions comprising either a polymer, an unprocessed polymer blend, or the polymer alloy were processed by KinetiSol and examined for amorphicity, dissolution performance, physical stability, and molecular interactions. A polymer alloy ivacaftor solid dispersion with a drug loading of 50% w/w was feasible versus 40% for the other compositions. Dissolution in fasted simulated intestinal fluid revealed that the 40% ivacaftor polymer alloy solid dispersion reached a concentration of 595 µg/mL after 6 h, 33% greater than the equivalent polymer blend dispersion. Fourier transform infrared spectroscopy and solid-state nuclear magnetic resonance revealed changes in the ability of the povidone contained in the polymer alloy to hydrogen bond with the ivacaftor phenolic moiety, explaining the differences in the dissolution performance. This work demonstrates that the creation of polymer alloys from polymer blends is a promising technique that provides the ability to tailor properties of a polymer alloy to maximize the drug loading, dissolution performance, and stability of an ASD.

Published

2023

4. Perfluorochemical‐facilitated plasminogen activator delivery to the airways: A novel treatment for inhalational smoke‐induced acute lung injury

Author

Marla R. Wolfson, Perenlei Enkhbaatar, Satoshi Fukuda, Christina L. Nelson, Robert O. Williams III, Soraya Hengsawas Surasarang, Sawittree Sahakijpijarn, Gennaro Calendo, Andrey A. Komissarov, Galina Florova, Krishna Sarva, Steven I. Idell, and Thomas H. Shaffer

Subjects

airway casts, inhalational acute lung injury, perfluorochemicals, plasminogen activators, Medicine (General), R5-920

Abstract

Abstract Background Effective clinical management of airway clot and fibrinous cast formation of severe inhalational smoke‐induced acute lung injury (ISALI) is lacking. Aerosolized delivery of tissue plasminogen activator (tPA) is confounded by airway bleeding; single‐chain urokinase plasminogen activator (scuPA) moderated this adverse effect and supported transient improvement in gas exchange and lung mechanics. However, neither aerosolized plasminogen activator (PA) yielded durable improvements in physiologic responses or reduction in cast burden. Here, we hypothesized that perfluorochemical (PFC) liquids would facilitate PA distribution and sustain improvements in physiologic outcomes in ISALI. Methods Spontaneously breathing adult sheep (n = 36) received anesthesia and analgesia and were instrumented, exposed to cotton smoke inhalation, and supported by mechanical ventilation for 48 h. Groups (n = 6/group) were studied without supplemental treatment, or, starting 4 h post injury, they received intratracheal low volume (8 mL) PFC liquid alone or a dose range of tPA/PFC or scuPA/PFC suspensions (4 or 8 mg in 8 mL PFC) every 8 h. Outcomes were evaluated by sequential measurements of cardiopulmonary parameters, lung histomorphology, and biochemical analyses of bronchoalveolar lavage fluid. Results Dose‐response and PA‐type comparisons of outcomes demonstrated sustained superiority with low‐volume PFC suspensions of scuPA over tPA or PFC alone, favoring the highest dose of scuPA/PFC suspension over lower doses, without airway bleeding. Conclusions We propose that this improved profile over previously reported aerosolized delivery is likely related to improved dose distribution. Sustained salutary responses to scuPA/PFC suspension delivery in this translational model are encouraging and support the possibility that the observed outcomes could be of clinical importance.

Published

2020

5. In vivo pharmacokinetic study of remdesivir dry powder for inhalation in hamsters

Author

Sawittree Sahakijpijarn, Chaeho Moon, Zachary N. Warnken, Esther Y. Maier, Jennie E. DeVore, Dale J. Christensen, John J. Koleng, and Robert O. Williams, III

Subjects

SARS-CoV-2, COVID-19, Remdesivir, Dry powder for inhalation, Thin film freezing, Pharmacokinetics, Pharmacy and materia medica, RS1-441

Abstract

Remdesivir dry powder for inhalation was previously developed using thin film freezing (TFF). A single-dose 24-h pharmacokinetic study in hamsters demonstrated that pulmonary delivery of TFF remdesivir can achieve plasma remdesivir and GS-441524 levels higher than the reported EC50s of both remdesivir and GS-441524 (in human epithelial cells) over 20 h. The half-life of GS-4412524 following dry powder insufflation was about 7 h, suggesting the dosing regimen would be twice-daily administration. Although the remdesivir-Captisol® (80/20 w/w) formulation showed faster and greater absorption of remdesivir and GS-4412524 in the lung, remdesivir-leucine (80/20 w/w) exhibited a greater Cmax with shorter Tmax and lower AUC of GS-441524, indicating lower total drug exposure is required to achieve a high effective concentration against SAR-CoV-2. In conclusion, remdesivir dry powder for inhalation would be a promising alternative dosage form for the treatment of COVID-19 disease.

Published

2021

6. Formulating a heat- and shear-labile drug in an amorphous solid dispersion: Balancing drug degradation and crystallinity

Author

Daniel A. Davis, Jr, Dave A. Miller, Supawan Santitewagun, J. Axel Zeitler, Yongchao Su, and Robert O. Williams, III

Subjects

Residual crystallinity, Seed crystallinity, Amorphous solid dispersion, Degradation, Bioavailability enhancement, KinetiSol processing, Pharmacy and materia medica, RS1-441

Abstract

We seek to further addresss the questions posed by Moseson et al. regarding whether any residual crystal level, size, or characteristic is acceptable in an amorphous solid dispersion (ASD) such that its stability, enhanced dissolution, and increased bioavailability are not compromised. To address this highly relevant question, we study an interesting heat- and shear-labile drug in development, LY3009120. To study the effects of residual crystallinity and degradation in ASDs, we prepared three compositionally identical formulations (57–1, 59–4, and 59–5) using the KinetiSol process under various processing conditions to obtain samples with various levels of crystallinity (2.3%, 0.9%, and 0.1%, respectively) and degradation products (0.74%, 1.97%, and 3.12%, respectively). Samples with less than 1% crystallinity were placed on stability, and we observed no measurable change in the drug's crystallinity, dissolution profile or purity in the 59–4 and 59–5 formulations over four months of storage under closed conditions at 25 °C and 60% humidity. For formulations 57–1, 59–4, and 59–5, bioavailability studies in rats reveal a 44-fold, 55-fold, and 62-fold increase in mean AUC, respectively, compared to the physical mixture. This suggests that the presence of some residual crystals after processing can be acceptable and will not change the properties of the ASD over time.

Published

2021

7. Oral Delivery of Niclosamide as an Amorphous Solid Dispersion That Generates Amorphous Nanoparticles during Dissolution

Author

Miguel O. Jara, Zachary N. Warnken, Sawittree Sahakijpijarn, Rishi Thakkar, Vineet R. Kulkarni, Dale J. Christensen, John J. Koleng, and Robert O. Williams

Subjects

niclosamide, amorphous solid dispersion, enteric capsules, enteric-coated tablet, amorphous nanoparticles, hot-melt extrusion, Pharmacy and materia medica, RS1-441

Abstract

Niclosamide is an FDA-approved anthelmintic that is being studied in clinical trials as a chemotherapeutic and broad-spectrum antiviral. Additionally, several other applications are currently in the preclinical stage. Unfortunately, niclosamide is a poorly water soluble molecule, with reduced oral bioavailability, which hinders its use for new indications. Moreover, niclosamide is a poor glass former; in other words, the molecule has a high tendency to recrystallize, and it is virtually impossible to generate a stable amorphous solid employing the neat molecule. Previously, our group reported the development of an amorphous solid dispersion (ASD) of niclosamide (niclosamide ASD) that generates nanoparticles during its dissolution, not only increasing niclosamide’s apparent solubility from 6.6 ± 0.4 to 481.7 ± 22.2 µg/mL in fasted state simulated intestinal fluid (FaSSIF) but also its oral bioavailability 2.6-fold in Sprague–Dawley rats after being administered as a suspension. Nevertheless, niclosamide ASD undergoes recrystallization in acidic media, and an enteric oral dosage form is needed for its translation into the clinic. In this work, we further characterized the nanoparticles that generated during the dissolution of the niclosamide ASD. Cryogenic transmission electron microscopy (Cryo-TEM) and wide-angle X-ray scattering (WAXS) revealed that the nanoparticles were amorphous and had a particle size of ~150 nm. The oral dosage forms of niclosamide ASD were formulated using commercial enteric capsules (Capsuline® and EudracapTM) and as enteric-coated tablets. The enteric dosage forms were tested using pH-shift dissolution and acid-uptake tests, using the USP type II dissolution apparatus and the disintegration apparatus, respectively. The capsules exhibited a higher percentage of weight gain, and visual rupture of the Capsuline capsules was observed. Eudracap capsules protected the formulation from the acidic media, but polymer gelling and the formation of a nondispersible plug were noted during dissolution testing. In contrast, enteric-coated tablets protected the formulation from acid ingress and maintained the performance of niclosamide ASD granules during dissolution in FaSSIF media. These enteric-coated tablets were administered to beagle dogs at a niclosamide dose of 75 mg/kg, resulting in plasma concentrations of niclosamide higher than those reported in the literature using solubilized niclosamide at a higher dose (i.e., 100 mg/kg). In summary, an enteric oral dosage form of niclosamide ASD was formulated without hindering the generation of nanoparticles while maintaining the increase in the niclosamide’s apparent solubility. The enteric-coated tablets successfully increased the niclosamide plasma levels in dogs when compared to a niclosamide solution prepared using organic solvents.

Published

2022

8. Emerging Artificial Intelligence (AI) Technologies Used in the Development of Solid Dosage Forms

Author

Junhuang Jiang, Xiangyu Ma, Defang Ouyang, and Robert O. Williams

Subjects

solid dosage formulation, artificial intelligence, machine learning, deep learning, Pharmacy and materia medica, RS1-441

Abstract

Artificial Intelligence (AI)-based formulation development is a promising approach for facilitating the drug product development process. AI is a versatile tool that contains multiple algorithms that can be applied in various circumstances. Solid dosage forms, represented by tablets, capsules, powder, granules, etc., are among the most widely used administration methods. During the product development process, multiple factors including critical material attributes (CMAs) and processing parameters can affect product properties, such as dissolution rates, physical and chemical stabilities, particle size distribution, and the aerosol performance of the dry powder. However, the conventional trial-and-error approach for product development is inefficient, laborious, and time-consuming. AI has been recently recognized as an emerging and cutting-edge tool for pharmaceutical formulation development which has gained much attention. This review provides the following insights: (1) a general introduction of AI in the pharmaceutical sciences and principal guidance from the regulatory agencies, (2) approaches to generating a database for solid dosage formulations, (3) insight on data preparation and processing, (4) a brief introduction to and comparisons of AI algorithms, and (5) information on applications and case studies of AI as applied to solid dosage forms. In addition, the powerful technique known as deep learning-based image analytics will be discussed along with its pharmaceutical applications. By applying emerging AI technology, scientists and researchers can better understand and predict the properties of drug formulations to facilitate more efficient drug product development processes.

Published

2022

9. Lack of durable protection against cotton smoke-induced acute lung injury in sheep by nebulized single chain urokinase plasminogen activator or tissue plasminogen activator

Author

Satoshi Fukuda, Perenlei Enkhbaatar, Christina Nelson, Robert A. Cox, Marla R. Wolfson, Thomas H. Shaffer, Robert O. Williams, Soraya Hengsawas Surasarang, Sahakijpijarn Sawittree, Galina Florova, Andrey A. Komissarov, Kathleen Koenig, Krishna Sarva, Harrison T. Ndetan, Karan P. Singh, and Steven Idell

Subjects

Plasminogen activators, Fibrinolysins, Plasminogen activator inhibitor-1, Inhalational acute lung injury, Medicine (General), R5-920

Abstract

Abstract Background Airway fibrin casts are clinically important complications of severe inhalational smoke-induced acute lung injury (ISIALI) for which reliable evidence-based therapy is lacking. Nebulized anticoagulants or a tissue plasminogen activator; tPA, has been advocated, but airway bleeding is a known and lethal potential complication. We posited that nebulized delivery of single chain urokinase plasminogen activator, scuPA, is well-tolerated and improves physiologic outcomes in ISIALI. To test this hypothesis, we nebulized scuPA or tPA and delivered these agents every 4 h to sheep with cotton smoke induced ISIALI that were ventilated by either adaptive pressure ventilation/controlled mandatory ventilation (APVcmv; Group 1, n = 14) or synchronized controlled mandatory ventilation (SCMV)/limited suctioning; Group 2, n = 32). Physiologic readouts of acute lung injury included arterial blood gas analyses, PaO2/FiO2 ratios, peak and plateau airway pressures, lung resistance and static lung compliance. Lung injury was further assessed by histologic scoring. Biochemical analyses included determination of antigenic and enzymographic uPA and tPA levels, plasminogen activator and plasminogen activator inhibitor-1 activities and d-dimer in bronchoalveolar lavage (BAL). Plasma levels of uPA, tPA antigens, d-dimers and α-macroglobulin-uPA complex levels were also assessed. Results In Group 1, tPA at the 2 mg dose was ineffective, but at 4 mg tPA or scuPA, the PaO2/FiO2 ratios, peak/plateau pressures improved during evolving injury (p

Published

2018

10. The immunogenicity of thin-film freeze-dried, aluminum salt-adjuvanted vaccine when exposed to different temperatures

Author

Sachin G. Thakkar, Tinashe B. Ruwona, Robert O. Williams, and Zhengrong Cui

Subjects

aluminum oxyhydroxide, antibody responses, antigen desorption, particle aggregation, thin-film freeze-drying, Immunologic diseases. Allergy, RC581-607, Therapeutics. Pharmacology, RM1-950

Abstract

Insoluble aluminum salts such as aluminum oxyhydroxide have been used for decades as adjuvants in human vaccines, and many vaccines contain aluminum salts as adjuvants. Aluminum salt-adjuvanted vaccines must be managed in cold-chain (2–8° C) during transport and storage, as vaccine antigens in general are too fragile to be stable in ambient temperatures, and unintentional slowing freezing causes irreversible aggregation and permanent damage to the vaccines. Previously, we reported that thin-film freeze-drying can be used to convert vaccines adjuvanted with an aluminum salt from liquid suspension into dry powder without causing particle aggregation or decreasing in immunogenicity following reconstitution. In the present study, using ovalbumin (OVA)-adsorbed Alhydrogel® (i.e. aluminum oxyhydroxide, 2% w/v) as a model vaccine, we showed that the immunogenicity of thin-film freeze-dried OVA-adsorbed Alhydrogel® vaccine powder was not significantly changed after it was exposed for an extended period of time in temperatures as high as 40° C or subjected to repeated slow freezing-and-thawing. It is expected that immunization programs can potentially benefit by integrating thin-film freeze-drying into vaccine preparations.

Published

2017

11. A Safety and Tolerability Study of Thin Film Freeze-Dried Tacrolimus for Local Pulmonary Drug Delivery in Human Subjects

Author

Sawittree Sahakijpijarn, Moeezullah Beg, Stephanie M. Levine, Jay I. Peters, and Robert O. Williams

Subjects

lung transplantation, immunosuppressant, tacrolimus, thin film freezing, dry powder inhalation, nebulization, Pharmacy and materia medica, RS1-441

Abstract

Due to the low and erratic bioavailability of oral tacrolimus (TAC), the long-term survival rate following lung transplantation remained low compared to other solid organs. TAC was reformulated and developed as inhaled formulations by thin film freezing (TFF). Previous studies reported that inhaled TAC combined with 50% w/w lactose (LAC) was safe and effective for the treatment of lung transplant rejection in rodent models. In this study, we aimed to investigate the safety and tolerability of TFF TAC-LAC in human subjects. The formulation can be delivered to the lung as colloidal dispersions after reconstitution and as a dry powder. Healthy subjects inhaled TAC-LAC colloidal dispersions at 3 mg TAC/dose via a vibrating mesh nebulizer in the first stage of this study and TAC-LAC dry powder at 3 mg TAC/dose via a single dose dry powder inhaler in the second stage. Our results demonstrated that oral inhalation of TAC-LAC colloidal dispersions and dry powder exhibited low systemic absorption. Additionally, they were well-tolerated with no changes in CBC, liver, kidney, and lung functions. Only mild adverse side effects (e.g., cough, throat irritation, distaste) were observed. In summary, pulmonary delivery of TFF TAC-LAC would be a safe and promising therapy for lung transplant recipients.

Published

2021

12. Amorphous Solid Dispersions and the Contribution of Nanoparticles to In Vitro Dissolution and In Vivo Testing: Niclosamide as a Case Study

Author

Miguel O. Jara, Zachary N. Warnken, and Robert O. Williams

Subjects

hot-melt extrusion, amorphous solid dispersions, nanoparticles, niclosamide, Pharmacy and materia medica, RS1-441

Abstract

We developed an amorphous solid dispersion (ASD) of the poorly water-soluble molecule niclosamide that achieved a more than two-fold increase in bioavailability. Notably, this niclosamide ASD formulation increased the apparent drug solubility about 60-fold relative to the crystalline material due to the generation of nanoparticles. Niclosamide is a weakly acidic drug, Biopharmaceutics Classification System (BCS) class II, and a poor glass former with low bioavailability in vivo. Hot-melt extrusion is a high-throughput manufacturing method commonly used in the development of ASDs for increasing the apparent solubility and bioavailability of poorly water-soluble compounds. We utilized the polymer poly(1-vinylpyrrolidone-co-vinyl acetate) (PVP–VA) to manufacture niclosamide ASDs by extrusion. Samples were analyzed based on their microscopic and macroscopic behavior and their intermolecular interactions, using differential scanning calorimetry (DSC), X-ray diffraction (XRD), nuclear magnetic resonance (NMR), Fourier-transform infrared (FTIR), and dynamic light scattering (DLS). The niclosamide ASD generated nanoparticles with a mean particle size of about 100 nm in FaSSIF media. In a side-by-side diffusion test, these nanoparticles produced a four-fold increase in niclosamide diffusion. We successfully manufactured amorphous extrudates of the poor glass former niclosamide that showed remarkable in vitro dissolution and diffusion performance. These in vitro tests were translated to a rat model that also showed an increase in oral bioavailability.

Published

2021

13. Bioavailability Improvement of Carbamazepine via Oral Administration of Modified-Release Amorphous Solid Dispersions in Rats

Author

Houli Li, Meimei Zhang, Lilong Xiong, Weiyi Feng, and Robert O. Williams

Subjects

carbamazepine, amorphous solid dispersions, modified-release, oral administration, bioavailability, thin film freezing, Pharmacy and materia medica, RS1-441

Abstract

The purpose of this study was to improve the bioavailability of carbamazepine (CBZ), a poorly water-soluble antiepileptic drug, via modified-release amorphous solid dispersions (mr-ASD) by a thin film freezing (TFF) process. Three types of CBZ-mr-ASD with immediate-, delayed-, and controlled-release properties were successfully prepared with HPMC E3 (hydrophilic), L100-55 (enteric), and cellulose acetate (CA, lipophilic), defined as CBZ-ir-ASD, CBZ-dr-ASD, and CBZ-cr-ASD, respectively. A dry granulation method was used to prepare CBZ-mr-ASD capsule formulations. Various characterization techniques were applied to evaluate the physicochemical properties of CBZ-mr-ASD and the related capsules. The drug remained in an amorphous state when encapsulated within CBZ-mr-ASD, and the capsule formulation progress did not affect the performance of the dispersions. In dissolution tests, the preparations and the corresponding dosage forms similarly showed typical immediate-, delayed-, and controlled-release properties depending on the solubility of the polymers. Moreover, single-dose 24 h pharmacokinetic studies in rats indicated that CBZ-mr-ASD significantly enhanced the oral absorption of CBZ compared to that of crude CBZ. Increased oral absorption of CBZ was observed, especially in the CBZ-dr-ASD formulation, which showed a better pharmacokinetic profile than that of crude CBZ with 2.63- and 3.17-fold improved bioavailability of the drug and its main active metabolite carbamazepine 10,11-epoxide (CBZ-E).

Published

2020

14. Development of Remdesivir as a Dry Powder for Inhalation by Thin Film Freezing

Author

Sawittree Sahakijpijarn, Chaeho Moon, John J. Koleng, Dale J. Christensen, and Robert O. Williams

Subjects

remdesivir, SARS-CoV-2, COVID-19, dry powder for inhalation, thin film freezing, brittle matrix powder, Pharmacy and materia medica, RS1-441

Abstract

Remdesivir exhibits in vitro activity against SARS-CoV-2 and was granted approval for emergency use. To maximize delivery to the lungs, we formulated remdesivir as a dry powder for inhalation using thin film freezing (TFF). TFF produces brittle matrix nanostructured aggregates that are sheared into respirable low-density microparticles upon aerosolization from a passive dry powder inhaler. In vitro aerodynamic testing demonstrated that drug loading and excipient type affected the aerosol performance of remdesivir. Remdesivir combined with optimal excipients exhibited desirable aerosol performance (up to 93.0% FPF< 5 µm; 0.82 µm mass median aerodynamic diameter). Remdesivir was amorphous after the TFF process, which benefitted drug dissolution in simulated lung fluid. TFF remdesivir formulations are stable after one month of storage at 25 °C/60% relative humidity. An in vivo pharmacokinetic evaluation showed that TFF remdesivir–leucine was poorly absorbed into systemic circulation while TFF remdesivir-Captisol® demonstrated increased systemic uptake compared to leucine. Remdesivir was hydrolyzed to the nucleoside analog GS-441524 in the lung, and levels of GS-441524 were greater in the lung with leucine formulation compared to Captisol®. In conclusion, TFF technology produces high-potency remdesivir dry powder formulations for inhalation that are suitable to treat patients with COVID-19 on an outpatient basis and earlier in the disease course where effective antiviral therapy can reduce related morbidity and mortality.

Published

2020

15. Influence of Carbamazepine Dihydrate on the Preparation of Amorphous Solid Dispersions by Hot Melt Extrusion

Author

Xiangyu Ma, Felix Müller, Siyuan Huang, Michael Lowinger, Xu Liu, Rebecca Schooler, and Robert O. Williams

Subjects

Amorphous solid dispersions, hot melt extrusion, hydrate, anhydrate, dehydration, Pharmacy and materia medica, RS1-441

Abstract

Amorphous solid dispersions (ASDs) are commonly used in the pharmaceutical industry to improve the dissolution and bioavailability of poorly water-soluble drugs. Hot melt extrusion (HME) has been employed to prepare ASD based products. However, due to the narrow processing window of HME, ASDs are normally obtained with high processing temperatures and mechanical stress. Interestingly, one-third of pharmaceutical compounds reportedly exist in hydrate forms. In this study, we selected carbamazepine (CBZ) dihydrate to investigate its solid-state changes during the dehydration process and the impact of the dehydration on the preparation of CBZ ASDs using a Leistritz micro-18 extruder. Various characterization techniques were used to study the dehydration kinetics of CBZ dihydrate under different conditions. We designed the extrusion runs and demonstrated that: 1) the dehydration of CBZ dihydrate resulted in a disordered state of the drug molecule; 2) the resulted higher energy state CBZ facilitated the drug solubilization and mixing with the polymer matrix during the HME process, which significantly decreased the required extrusion temperature from 140 to 60 °C for CBZ ASDs manufacturing compared to directly processing anhydrous crystalline CBZ. This work illustrated that the proper utilization of drug hydrates can significantly improve the processability of HME for preparing ASDs.

Published

2020

16. Improved Dissolution and Pharmacokinetics of Abiraterone through KinetiSol® Enabled Amorphous Solid Dispersions

Author

Urvi Gala, Dave Miller, and Robert O. Williams

Subjects

abiraterone, dissolution, pharmacokinetics, amorphous solid dispersions, KinetiSol® technology, Pharmacy and materia medica, RS1-441

Abstract

Abiraterone is a poorly water-soluble drug. It has a high melting point and limited solubility in organic solvents, making it difficult to formulate as an amorphous solid dispersion (ASD) with conventional technologies. KinetiSol® is a high-energy, fusion-based, solvent-free technology that can produce ASDs. The aim of this study was to evaluate the application of KinetiSol to make abiraterone ASDs. We developed binary KinetiSol ASDs (KSDs) using both polymers and oligomers. For the first time, we reported that KinetiSol can process hydroxypropyl-β-cyclodextrin (HPBCD), a low molecular-weight oligomer. Upon X-ray diffractometry and modulated differential scanning calorimetry analysis, we found the KSDs to be amorphous. In vitro dissolution analysis revealed that maximum abiraterone dissolution enhancement was achieved using a HPBCD binary KSD. However, the KSD showed significant abiraterone precipitation in fasted state simulated intestinal fluid (FaSSIF) media. Hence, hypromellose acetate succinate (HPMCAS126G) was selected as an abiraterone precipitation inhibitor and an optimized ternary KSD was developed. A pharmacokinetic study revealed that HPBCD based binary and ternary KSDs enhanced abiraterone bioavailability by 12.4-fold and 13.8-fold, respectively, compared to a generic abiraterone acetate tablet. Thus, this study is the first to demonstrate the successful production of an abiraterone ASD that exhibited enhanced dissolution and bioavailability.

Published

2020

17. Formulation Composition and Process Affect Counterion for CSP7 Peptide

Author

Sawittree Sahakijpijarn, Chaeho Moon, John J. Koleng, and Robert O. Williams

Subjects

counterion, counterion volatilization, volatile compounds, lyophilization, bulking agent, peptide aggregation, Pharmacy and materia medica, RS1-441

Abstract

Counterions commonly remain with peptides in salt form after peptide purification. In animal and human studies, acetate counterions are a safer and more acceptable choice for peptides than others (e.g., trifluoroacetate counterions). Various salt forms of caveolin-1 scaffolding domain (CSP7) affect counterion volatilization. The development of lyophilized formulations containing volatile compounds is a challenge because these compounds sublimate away during the process. This work aims to investigate the effect of excipients and lyophilization parameters on the preservation of volatile compounds after lyophilization. The peak areas obtained from 1H and 19F NMR spectra were used to calculate the molar ratio of counterions to CSP7. We found that the pH modifier excipient had the greatest impact on the loss of counterions. By optimizing the molar ratio of bulking agent to CSP7, volatile compounds can be preserved after lyophilization. Higher chamber pressure during lyophilization can lower the sublimation rate of volatile compounds. Moreover, the loss of volatile compounds affects the stability of CSP7 due to the pH shift of reconstituted solutions, thereby causing peptide aggregation. The optimization of the formulation and processing helps preserve volatile compounds, thus minimizing the pH change of reconstituted solutions and maintaining the stability of peptide.

Published

2019

18. Sustained Release Drug Delivery Applications of Polyurethanes

Author

Michael B. Lowinger, Stephanie E. Barrett, Feng Zhang, and Robert O. Williams

Subjects

polyurethane, isocyanate, long-acting, sustained release, drug delivery, Pharmacy and materia medica, RS1-441

Abstract

Since their introduction over 50 years ago, polyurethanes have been applied to nearly every industry. This review describes applications of polyurethanes to the development of modified release drug delivery. Although drug delivery research leveraging polyurethanes has been ongoing for decades, there has been renewed and substantial interest in the field in recent years. The chemistry of polyurethanes and the mechanisms of drug release from sustained release dosage forms are briefly reviewed. Studies to assess the impact of intrinsic drug properties on release from polyurethane-based formulations are considered. The impact of hydrophilic water swelling polyurethanes on drug diffusivity and release rate is discussed. The role of pore formers in modulating drug release rate is examined. Finally, the value of assessing mechanical properties of the dosage form and approaches taken in the literature are described.

Published

2018

19. Aggregation of Lactoferrin Caused by Droplet Atomization Process via a Two-Fluid Nozzle: The Detrimental Effect of Air–Water Interfaces

Author

Huy M. Dao, Sawittree Sahakijpijarn, Robert R. Chrostowski, Chaeho Moon, Filippo Mangolini, Zhengrong Cui, and Robert O. Williams

Subjects

Lactoferrin, Freeze Drying, Immunoglobulin G, Drug Discovery, Animals, Water, Pharmaceutical Science, Molecular Medicine, Cattle, Particle Size, Powders, beta-Galactosidase

Abstract

Biological macromolecules, especially therapeutic proteins, are delicate and highly sensitive to denaturation from stresses encountered during the manufacture of dosage forms. Thin-film freeze-drying (TFFD) and spray freeze-drying (SFD) are two processes used to convert liquid forms of protein into dry powders. In the production of inhalable dry powders that contain proteins, these potential stressors fall into three categories based on their occurrence during the primary steps of the process: (1) droplet formation (e.g., the mechanism of droplet formation, including spray atomization), (2) freezing, and (3) frozen water removal (e.g., sublimation). This study compares the droplet formation mechanism used in TFFD and SFD by investigating the effects of spraying on the stability of proteins, using lactoferrin as a model. This study considers various perspectives on the denaturation (e.g., conformation) of lactoferrin after subjecting the protein solution to the atomization process using a pneumatic two-fluid nozzle (employed in SFD) or a low-shear drop application through the nozzle. The surface activity of lactoferrin was examined to explore the interfacial adsorption tendency, diffusion, and denaturation process. Subsequently, this study also investigates the secondary and tertiary structure of lactoferrin and the quantification of monomers, oligomers, and, ultimately, aggregates. The spraying process affected the tertiary structure more negatively than the tightly woven secondary structure, resulting in the peak position corresponding to the tryptophan (Trp) residues red-shifting by 1.5 nm. This conformational change can either (a) be reversed at low concentrations via relaxation or (b) proceed to form irreversible aggregates at higher concentrations. Interestingly, when the sample was allowed to progress into micrometer-sized aggregates, such a dramatic change was not detected using methods such as size-exclusion chromatography, polyacrylamide gel electrophoresis, and dynamic light scattering at 173°. A more complete understanding of the heterogeneous protein sample was achieved only through a combination of 173 and 13° backward and forward scattering, a combination of derived count rate measurements, and microflow imaging (MFI). After studying the impact of droplet formation mechanisms on aggregation tendency of lactoferrin, we further investigated two additional model proteins with different surface activity: bovine IgG (serving as a non surface-active negative reference), and β-galactosidase (another surface-active protein). The results corroborated the lactoferrin findings that spray-atomization-related stress-induced protein aggregation was much more pronounced for proteins that are surface active (lactoferrin and β-galactosidase), but it was minimal for non-surface-active protein (bovine IgG). Finally, compared to the low-shear dripping used in the TFFD process, lactoferrin underwent a relatively fast conformational change upon exposure to the high air-water interface of the two-fluid atomization nozzle used in the SFD process as compared to the low shear dripping used in the TFFD process. The interfacial-induced denaturation that occurred during spraying was governed primarily by the size of the atomized droplets, regardless of the duration of exposure to air. The percentage of denatured protein population and associated activity loss, in the case of β-galactosidase, was determined to range from 2 to 10% depending on the air-flow rate of the spraying process.

Published

2022

20. The Development of Thin-Film Freezing and Its Application to Improve Delivery of Biologics as Dry Powder Aerosols

Author

Chaeho Moon, Sawittree Sahakijpijarn, Stephanie Hufnagel, Zhengrong Cui, and Robert O. Williams

Subjects

Materials science, Dry powder, General Chemical Engineering, Metallurgy, General Engineering, General Materials Science, General Chemistry, Thin film

Published

2022

21. Aerosolizable Plasmid DNA Dry Powders Engineered by Thin-film Freezing

Author

Haiyue Xu, Chaeho Moon, Sawittree Sahakijpijarn, Huy M. Dao, Riyad F. Alzhrani, Jie-liang Wang, Robert O. Williams, and Zhengrong Cui

Subjects

Pharmacology, Organic Chemistry, Pharmaceutical Science, Molecular Medicine, Pharmacology (medical), Biotechnology

Abstract

This study was designed to test the feasibility of using thin-film freezing (TFF) to prepare aerosolizable dry powders of plasmid DNA (pDNA) for pulmonary delivery. Dry powders of pDNA formulated with mannitol/leucine (70/30, w/w) at various of drug loadings, solid contents, and solvents were prepared using TFF, their aerosol properties (i.e., mass median aerodynamic diameter (MMAD) and fine particle fraction (FPF)) determined, and selected powders were used for further characterization. Of the nine dry powders prepared, their MMAD values were about 1-2 mm, with FPF values (delivered) of 40-80%. The aerosol properties of the powders were inversely correlated with the pDNA loading and the solid content in the pDNA solution before thin-film freezing. Powders prepared with Tris-EDTA (TE) buffer or cosolvents (i.e., 1,4 dioxane or t-butanol in water), instead of water, showed slightly reduced aerosol properties. Ultimately, powders prepared with pDNA loading at 5% (w/w), 0.25% of solid content, with or without TE were selected for further characterization due to their overall good aerosol performance. The pDNA powders exhibited a porous matrix, crystalline structure, with a moisture content of

Published

2023

22. Manufacturing Stable Bacteriophage Powders by Including Buffer System in Formulations and Using Thin Film Freeze-drying Technology

Author

Melissa Soto, Robert O. Williams, Yajie Zhang, and Debadyuti Ghosh

Subjects

Pharmacology, Tris, Materials science, biology, T7 phage, viruses, Organic Chemistry, Pharmaceutical Science, Excipient, biology.organism_classification, Dosage form, Matrix (chemical analysis), Bacteriophage, chemistry.chemical_compound, Freeze-drying, chemistry, Chemical engineering, medicine, Molecular Medicine, Particle, Pharmacology (medical), Biotechnology, medicine.drug

Abstract

Bacteriophage (phage) therapy has re-gained attention lately given the ever-increasing prevalence of multi-drug resistance ‘super-bugs’. To develop therapeutic phage into clinically usable drug products, the strategy of solidifying phage formulations has been implemented to diversify the dosage forms and to overcome the storage condition limitations for liquid phage formulations. In our work, we hypothesize and tested that an advanced technology, thin film freeze-drying (TFFD), can be used to produce phage containing dry powders without significantly losing phage viability. Here we selected T7 phage as our model phage in a preliminary screening study. We found that a binary excipient matrix of sucrose and leucine at ratios of 90:10 or 75:25 by weight, protected phage from the stresses encountered during the TFFD process. In addition, we confirmed that incorporating a buffer system in the formulation significantly improved the survival of phage during the initial freezing step and subsequent sublimation step in the solidifying processes. The titer loss of phage in SM buffer (Tris/NaCl/MgSO4) containing formulation was as low as 0.19 log plaque forming units, which indicated that phage function was well preserved after the TFFD process. The presence of buffers markedly reduced the geometric particle sizes as determined by a dry dispersion method using laser diffraction, which indicated that the TFFD phage powder formulations were easily sheared into smaller powder aggregates, an ideal property for facilitating a variety of topical drug delivery routes including pulmonary delivery through dry powder inhalers, nebulization after reconstitution, and intranasal or wound therapy, etc. From these findings, we show that introducing buffer system can stabilize phage during dehydration processes, and TFFD, as a novel particle engineering method, can successfully produce phage containing powders that possess the desired properties for bioactivity and potentially for inhalation therapy.

Published

2021

23. Thin-Film Freeze-Drying Process for Versatile Particles for Inhalation Drug Delivery

Author

Chaeho Moon, Sawittree Sahakijpijarn, and Robert O. Williams

Published

2022

24. Feasibility of intranasal delivery of thin-film freeze-dried, mucoadhesive vaccine powders

Author

Yu-Sheng Yu, Khaled AboulFotouh, Haiyue Xu, Gerallt Williams, Julie Suman, Chris Cano, Zachary N. Warnken, Kevin C.-W. Wu, Robert O. Williams, and Zhengrong Cui

Subjects

Pharmaceutical Science

Published

2023

25. The effect of drug loading on the properties of abiraterone–hydroxypropyl beta cyclodextrin solid dispersions processed by solvent free KinetiSol® technology

Author

Angela Spangenberg, Yongchao Su, Urvi Gala, Robert O. Williams, and Dave A. Miller

Subjects

Drug, Recrystallization (geology), Chemistry, Pharmaceutical, Drug Compounding, media_common.quotation_subject, Biological Availability, Pharmaceutical Science, 02 engineering and technology, 030226 pharmacology & pharmacy, Excipients, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Differential scanning calorimetry, Pharmacokinetics, In vivo, Dissolution, media_common, Abiraterone acetate, General Medicine, 021001 nanoscience & nanotechnology, 2-Hydroxypropyl-beta-cyclodextrin, Bioavailability, Drug Liberation, chemistry, Androstenes, 0210 nano-technology, Biotechnology, Nuclear chemistry

Abstract

Abiraterone is a poorly water-soluble drug used in the treatment of prostate cancer. In our previous study, we reported that KinetiSol® processed solid dispersions (KSDs) based on hydroxypropyl β-cyclodextrin (HPBCD) showed improved dissolution and pharmacokinetics of abiraterone. However, the nature of abiraterone-HPBCD interaction within the KSDs or the effect of drug loading on the physicochemical properties and in vivo performance of HPBCD-based KSDs remain largely unknown. We hypothesize that KinetiSol technology can prepare abiraterone-HPBCD complexes within KSDs and that increasing the drug loading beyond an optimal point reduces the in vitro and in vivo performance of these KSDs. To confirm our hypothesis, we developed KSDs with 10-50% w/w drug loading and analyzed them using X-ray diffractometry and modulated differential scanning calorimetry. We found that KSDs containing 10-30% drug were amorphous. Interestingly, two-dimensional solid-state nuclear magnetic resonance and Raman spectroscopy indicated that the abiraterone-HPBCD complexes were formed. At elevated temperatures, the 10% and 20% drug-loaded KSDs were physically stable, while the 30% drug-loaded KSD showed recrystallization of abiraterone. In vitro dissolution and in vivo pharmacokinetic performances improved as the drug loading decreased; we attribute this to increased noncovalent interactions between abiraterone and HPBCD at lower drug loadings. Overall, the 10% drug loaded KSD showed a dissolution enhancement of 15.7-fold compared to crystalline abiraterone, and bioavailability enhancement of 3.9-fold compared to the commercial abiraterone acetate tablet Zytiga®. This study is first to confirm that KinetiSol, a high-energy, solvent-free technology, is capable of forming abiraterone-HPBCD complexes. Furthermore, in terms of in vitro and in vivo performance, a 10% drug load is optimal.

Published

2021

26. Specific mechanical energy – An essential parameter in the processing of amorphous solid dispersions

Author

Stephen A. Thompson and Robert O. Williams

Subjects

0303 health sciences, Materials science, business.industry, Chemistry, Pharmaceutical, Drug Compounding, Temperature, Process (computing), Pharmaceutical Science, 02 engineering and technology, Specific mechanical energy, 021001 nanoscience & nanotechnology, Screw speed, Amorphous solid, Processing methods, 03 medical and health sciences, Drug Delivery Systems, Pharmaceutical Preparations, Humans, Extrusion, 0210 nano-technology, Process engineering, business, Dispersion (chemistry), Design space, 030304 developmental biology

Abstract

Specific mechanical energy (SME) is a frequently overlooked but essential parameter of hot-melt extrusion (HME). It can determine whether an amorphous solid dispersion (ASD) can be successfully processed. A minimum combination of thermal input and SME is required to convert a crystalline active pharmaceutical product (API) into its amorphous form. A maximum combination is allowed before it or the carrier polymer chemically degrades. This has important implications on design space. SME input during HME provides information on the totality of the effect of various independent processing parameters such as screw speed, feed rate, and complex viscosity. If only these independent processing parameters are considered separately instead of SME, then important information would be lost regarding the interaction of these parameters and their ability to affect ASD formulation. A complete understanding of the HME process requires an analysis of SME. This paper provides a review of SME use in the pharmaceutical processing of ASDs, the importance of SME in terms of a variety of formulation qualities, and novel future uses of SME. Theoretical background is discussed, along with the relative importance of thermal and mechanical input on various nonsolvent ASD processing methods.

Published

2021

27. Pharmaceutical dry powders of small molecules prepared by thin-film freezing and their applications - A focus on the physical and aerosol properties of the powders

Author

Tuangrat Praphawatvet, Zhengrong Cui, and Robert O. Williams

Subjects

Aerosols, Freezing, Administration, Inhalation, Pharmaceutical Science, Dry Powder Inhalers, Powders, Particle Size

Abstract

Thin-film freeze-drying is a dry powder engineering technology that involves in a rapid thin-film freezing (TFF) process followed by lyophilization to remove solvent. TFF process has been successfully used to produce pharmaceutical powders of the small and large molecule drugs as well as live organisms. This paper provides a comprehensive review of the pharmaceutical applications of TFF powders of small molecule drugs intended for pulmonary delivery or oral administration. The powders produced by the TFF process often exhibited unique physical properties such as amorphous morphology, high porosity, brittle matrix structure, and high specific surface area, and the powders also often contain loosely connected micron or submicron particles or aggregates. The TFF process parameters and formulation compositions directly affect the physical properties of the powders. These physical properties render TFF powders desirable aerodynamic properties for efficient pulmonary delivery by oral inhalation and help enhance the dissolution of poorly water-soluble small molecule drugs in the powders and thus improve their bioavailability after oral administration.

Published

2022

28. Selective Laser Sintering 3-Dimensional Printing as a Single Step Process to Prepare Amorphous Solid Dispersion Dosage Forms for Improved Solubility and Dissolution Rate

Author

Yongchao Su, Rishi Thakkar, Dan Davis, Robert O. Williams, and Mohammed Maniruzzaman

Subjects

Materials science, Scattering, Drug Compounding, Lasers, Pharmaceutical Science, 02 engineering and technology, 021001 nanoscience & nanotechnology, Laser, 030226 pharmacology & pharmacy, Dosage form, Amorphous solid, law.invention, 03 medical and health sciences, Selective laser sintering, 0302 clinical medicine, Solubility, Chemical engineering, law, Printing, Three-Dimensional, Crystallization, 0210 nano-technology, Dispersion (chemistry), Dissolution, Tablets

Abstract

This study reports the development of ritonavir-copovidone amorphous solid dispersions (ASDs) and dosage forms thereof using selective laser sintering (SLS) 3-dimensional (3-D) printing in a single step, circumventing the post-processing steps required in common techniques employed to make ASDs. For this study, different drug loads of ritonavir with copovidone were processed at varying processing conditions to understand the impact, range, and correlation of these parameters for successful ASD formation. Further, ASDs characterized using conventional and advanced solid-state techniques including wide-angle X-ray scattering (WAXS), solid-state nuclear magnetic resonance (ssNMR), revealed the full conversion of the crystalline drug to its amorphous form as a function of laser-assisted selective fusion in a layer-by-layer manner. It was observed that an optimum combination of the powder flow properties, surface temperature, chamber temperature, laser speed, and hatch spacing was crucial for successful ASD formation, any deviations resulted in print failures or only partial amorphous conversion. Moreover, a 21-fold increase in solubility was demonstrated by the SLS 3-D printed tablets. The results confirmed that SLS 3-D printing can be used as a single-step platform for creating ASD-based pharmaceutical dosage forms with a solubility advantage.

Published

2021

29. Fixed-dose dry powder for inhalation of nintedanib, pirfenidone and mycophenolic acid by thin-film freezing (TFF) technology

Author

Tuangrat Praphawatvet, Sawittree Sahakijpijarn, Chaeho Moon, Jay I. Peters, and Robert O. Williams

Subjects

Pharmaceutical Science

Published

2023

30. Corrigendum to 'Development of (Inhalable) Dry Powder Formulations of AS01B-Containing Vaccines Using Thin-Film Freeze-Drying' [Int. J. Pharm. 622 (2022) 121825]

Author

Khaled AboulFotouh, Haiyue Xu, Chaeho Moon, Robert O. Williams, and Zhengrong Cui

Subjects

Pharmaceutical Science

Published

2023

31. Accelerated mass transfer from frozen thin films during thin-film freeze-drying

Author

Jie-Liang Wang, Manlei Kuang, Haiyue Xu, Robert O. Williams, and Zhengrong Cui

Abstract

Freeze-drying, or lyophilization, is widely used to produce pharmaceutical solids from temperature-sensitive materials but the process is time and energy inefficient. Herein, using E. coli as a model live organism, whose viability in dry powders is highly sensitive to the water content in the powders, we demonstrated that the drying rate of thin-film freeze-drying (TFFD) is significantly higher than that of the conventional shelf freeze-drying, likely because the large total surface area from the loosely stacked frozen thin films and the low thickness of the thin-films enable faster and more efficient mass transfer during freeze-drying. The highly porous nature and high specific surface area of the thin-film freeze-dried powders may have contributed to the faster mass transfer as well. Moreover, we demonstrated that TFFD can be applied to produce dry powders of E. coli and L. acidophilus with minimum bacterial viability loss (i.e., within one log reduction), and the L. acidophilus dry powder is suitable for intranasal delivery. It is concluded that TFFD technology is promising in addressing the time-and cost-inefficient issue of conventional shelf freeze-drying.

Published

2022

32. Development of (Inhalable) Dry Powder Formulations of AS01

Author

Khaled, AboulFotouh, Haiyue, Xu, Chaeho, Moon, Robert O, Williams, and Zhengrong, Cui

Subjects

Vaccines, Freeze Drying, Adjuvants, Immunologic, Ovalbumin, Administration, Inhalation, Liposomes, Antigens, Desiccation, Particle Size, Powders, Adjuvants, Pharmaceutic

Abstract

AS01

Published

2022

33. Development of Dry Powder Formulations of AS01Bcontaining vaccines using Thin-Film Freeze-Drying

Author

Khaled AboulFotouh, Haiyue Xu, Robert O. Williams, and Zhengrong Cui

Abstract

AS01Bis a liposomal formulation of two immunostimulants namely 3-O-desacyl-4’-monophosphoryl lipid A (MPL) and QS-21. The liposomal formulation of AS01Breduces the endotoxicity of MPL and the lytic activity of QS-21; however, it renders the adjuvant sensitive to accidental slow freezing. The liposomal formulation also represents a major challenge towards the formulation of dry powders of vaccines containing AS01B. In the present study, we tested the feasibility of applying thin-film freeze-drying (TFFD) to engineer dry powders of the AS01Bliposomal adjuvant alone or vaccines containing AS01Bas an adjuvant. Initially, we showed that after the AS01Bliposomal adjuvant was subjected to TFFD using sucrose as a stabilizer at 4%w/v, the particle size distribution of AS01Bliposomes reconstituted from the dry powder was identical to the liquid adjuvant before drying. We then showed using ovalbumin (OVA) as a model antigen adjuvanted with AS01B(AS01B/OVA) that subjecting the AS01B/OVA vaccine to TFFD and subsequent reconstitution did not negatively affect the AS01Bliposome integrity, nor the immunogenicity of the vaccine. Importantly, the thin-film freeze-dried vaccine was not sensitive to repeated freezing-and-thawing. Finally, the feasibility of using TFFD to prepare dry powders of AS01B-adjuvanted vaccines was further confirmed using AS01B-adjuvanted Fluzone Quadrivalent and Shingrix, which contains AS01B. It is concluded that the TFFD technology can enable the formulation of AS01B-adjuvanted vaccines as freezing-insensitive dry powders in single-vial presentation.

Published

2022

34. Immunogenicity of Antigen Adjuvanted with AS04 and Its Deposition in the Upper Respiratory Tract after Intranasal Administration

Author

Mingtao Zeng, Zachary N. Warnken, Sachin G. Thakkar, Zhengrong Cui, Hugh D. C. Smyth, Riyad F. Alzhrani, Robert O. Williams, and Haiyue Xu

Subjects

Ovalbumin, medicine.medical_treatment, Respiratory System, Pharmaceutical Science, Monophosphoryl Lipid A, Aluminum Hydroxide, Mice, Subcutaneous injection, Immunogenicity, Vaccine, Immune system, Adjuvants, Immunologic, Antigen, Drug Discovery, medicine, Animals, Humans, Antigens, Immunity, Mucosal, Administration, Intranasal, Mice, Inbred BALB C, Vaccines, biology, business.industry, Immunogenicity, Vaccination, Immunity, respiratory system, Lipid A, Antibody Formation, Immunology, biology.protein, Cytokines, Molecular Medicine, Female, Immunization, Nasal administration, business, Adjuvant

Abstract

Adjuvant system 04 (AS04) is in injectable human vaccines. AS04 contains two known adjuvants, 3-O-desacyl-4'-monophosphoryl lipid A (MPL) and insoluble aluminum salts. Data from previous studies showed that both MPL and insoluble aluminum salts have nasal mucosal vaccine adjuvant activity. The present study was designed to test the feasibility of using AS04 as an adjuvant to help nasally administered antigens to induce specific mucosal and systemic immunity as well as to evaluate the deposition of antigens in the upper respiratory tract when adjuvanted with AS04. Alhydrogel, an aluminum (oxy)hydroxide suspension, was mixed with MPL to form AS04, which was then mixed with ovalbumin (OVA) or 3× M2e-HA2, a synthetic influenza virus hemagglutinin fusion protein, as an antigen to prepare OVA/AS04 and 3× M2e-HA2/AS04 vaccines, respectively. In mice, AS04 enabled antigens, when given intranasally, to induce specific IgA response in nasal and lung mucosal secretions as well as specific IgG response in the serum samples of the immunized mice, whereas subcutaneous injection of the same vaccine induced specific antibody responses only in the serum samples but not in the mucosal secretions. Splenocytes isolated from mice intranasally immunized with the OVA/AS04 also proliferated and released cytokines (i.e., IL-4 and IFN-γ) after in vitro stimulation with the antigen. In the immunogenicity test, intranasal OVA/AS04 was not more effective than intranasal OVA/MPL at the dosing regimens tested. However, when compared to OVA/MPL, OVA/AS04 showed a different atomized droplet size distribution and more importantly a more favorable OVA deposition profile when atomized into a nasal cast that was 3-D printed based on the computer tomography scan of the nose of a child. It is concluded that AS04 has mucosal adjuvant activity when given intranasally. In addition, there is a reason to be optimistic about using AS04 as an adjuvant to target an antigen of interest to the right region of the nasal cavity in humans for immune response induction.

Published

2020

35. Hydrophilic Poly(urethanes) Are an Effective Tool for Gastric Retention Independent of Drug Release Rate

Author

Esther Y. Maier, Michael Lowinger, Feng Zhang, and Robert O. Williams

Subjects

Drug, media_common.quotation_subject, Administration, Oral, Biological Availability, Pharmaceutical Science, 02 engineering and technology, Urethane, 030226 pharmacology & pharmacy, Dosage form, 03 medical and health sciences, Drug Delivery Systems, 0302 clinical medicine, medicine, media_common, Chromatography, Chemistry, Stomach, digestive, oral, and skin physiology, Drug release rate, Area under the curve, 021001 nanoscience & nanotechnology, Pylorus, Controlled release, Drug Liberation, medicine.anatomical_structure, Delayed-Action Preparations, Swelling, medicine.symptom, 0210 nano-technology, Tablets

Abstract

Acyclovir is a poorly permeable, short half-life drug with poor colonic absorption, and current conventional controlled release formulations are unable to decrease the frequency of administration. We designed acyclovir dosage forms to be administered less frequently by being retained in the stomach and releasing drug over an extended duration. We developed a conventional modified-release matrix tablet to sustain the release of acyclovir and surrounded it with a hydrophilic poly(urethane) layer. When hydrated, the porous poly(urethane) swells to a size near or beyond that of the relaxed pylorus diameter and does not affect drug release rate. We demonstrated that the formulation is retained in the stomach for extended durations as it slowly releases drug, allowing for similar area under the curve but delayed tmax relative to a nongastroretentive control tablet. Unlike many other gastroretentive formulations, this dosage form design decouples drug release rate from gastric retention time, allowing them to be modulated independently. It also effectively retains in the stomach regardless of the prandial state, differentiating from other approaches. Our direct observation of excised rat stomachs allowed for a rigorous assessment of the impact of polymer swelling extent and the prandial state on both the dosage form integrity and retention time.

Published

2020

36. Perfluorochemical‐facilitated plasminogen activator delivery to the airways: A novel treatment for inhalational smoke‐induced acute lung injury

Author

Gennaro Calendo, Krishna Sarva, Perenlei Enkhbaatar, Galina Florova, Steven Idell, Robert O. Williams, Sawittree Sahakijpijarn, Christina Nelson, Satoshi Fukuda, Soraya Hengsawas Surasarang, Thomas H. Shaffer, Marla R. Wolfson, and Andrey A. Komissarov

Subjects

0301 basic medicine, medicine.medical_treatment, Smoke inhalation, Medicine (miscellaneous), Lung injury, Tissue plasminogen activator, 03 medical and health sciences, 0302 clinical medicine, medicine, Research Articles, Mechanical ventilation, lcsh:R5-920, Lung, medicine.diagnostic_test, business.industry, perfluorochemicals, medicine.disease, airway casts, 030104 developmental biology, Bronchoalveolar lavage, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Anesthesia, Molecular Medicine, inhalational acute lung injury, plasminogen activators, lcsh:Medicine (General), business, Airway, Plasminogen activator, Research Article, medicine.drug

Abstract

Background Effective clinical management of airway clot and fibrinous cast formation of severe inhalational smoke‐induced acute lung injury (ISALI) is lacking. Aerosolized delivery of tissue plasminogen activator (tPA) is confounded by airway bleeding; single‐chain urokinase plasminogen activator (scuPA) moderated this adverse effect and supported transient improvement in gas exchange and lung mechanics. However, neither aerosolized plasminogen activator (PA) yielded durable improvements in physiologic responses or reduction in cast burden. Here, we hypothesized that perfluorochemical (PFC) liquids would facilitate PA distribution and sustain improvements in physiologic outcomes in ISALI. Methods Spontaneously breathing adult sheep (n = 36) received anesthesia and analgesia and were instrumented, exposed to cotton smoke inhalation, and supported by mechanical ventilation for 48 h. Groups (n = 6/group) were studied without supplemental treatment, or, starting 4 h post injury, they received intratracheal low volume (8 mL) PFC liquid alone or a dose range of tPA/PFC or scuPA/PFC suspensions (4 or 8 mg in 8 mL PFC) every 8 h. Outcomes were evaluated by sequential measurements of cardiopulmonary parameters, lung histomorphology, and biochemical analyses of bronchoalveolar lavage fluid. Results Dose‐response and PA‐type comparisons of outcomes demonstrated sustained superiority with low‐volume PFC suspensions of scuPA over tPA or PFC alone, favoring the highest dose of scuPA/PFC suspension over lower doses, without airway bleeding. Conclusions We propose that this improved profile over previously reported aerosolized delivery is likely related to improved dose distribution. Sustained salutary responses to scuPA/PFC suspension delivery in this translational model are encouraging and support the possibility that the observed outcomes could be of clinical importance.

Published

2020

37. Pharmaceutical Cryogenic Technologies

Author

Sawittree Sahakijpijarn, Chaeho Moon, and Robert O. Williams

Published

2022

38. Precipitation Technologies for Nanoparticle Production

Author

Tuangrat Praphawatvet and Robert O. Williams

Published

2022

39. Lipid-Based Formulations

Author

Daniel A. Davis, Han-Hsuan Peng, and Robert O. Williams

Published

2022

40. Solid-State Techniques for Improving Solubility

Author

Miguel O. Jara, Justin R. Hughey, Siyuan Huang, and Robert O. Williams

Published

2022

41. Cosolvent and Complexation Systems

Author

Junhuang Jiang and Robert O. Williams

Published

2022

42. Optimizing the Formulation of Poorly Water-Soluble Drugs

Author

Xiangyu Ma, Daniel Ellenberger, Kevin P. O’Donnell, and Robert O. Williams

Published

2022

43. Impact Assessment of the Variables Affecting the Drug Release and Extraction of Polyethylene Oxide Based Abuse Deterrent Tablets

Author

Salma Salem, Stephen R. Byrn, Daniel Smith, Vadim J. Gurvich, Stephen W. Hoag, Feng Zhang, Robert O. Williams III, and Kari L. Clase

Subjects

History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering

Published

2022

44. Emerging Technologies to Increase the Bioavailability of Poorly Water-Soluble Drugs

Author

Daniel A. Davis, Rishi Thakkar, Mohammed Maniruzzaman, Dave A. Miller, and Robert O. Williams

Published

2022

45. Melt Extrusion

Author

Stephen A. Thompson, Daniel A. Davis, James C. DiNunzio, Charlie Martin, Robert O. Williams, and Feng Zhang

Published

2022

46. Accelerated water removal from frozen thin films containing bacteria

Author

Jie-Liang, Wang, Manlei, Kuang, Haiyue, Xu, Robert O, Williams, and Zhengrong, Cui

Subjects

Pharmaceutical Science

Abstract

Freeze-drying, or lyophilization, is widely used to produce pharmaceutical solids that contain temperature-sensitive materials. Herein, using Escherichia coli as a model live organism, whose viability in dry powders is highly sensitive to the water content in the powders, we demonstrated that the drying rate from the frozen thin films generated by thin-film freezing (TFF) is significantly faster than from the bulk frozen solids in conventional shelf freeze-drying. This is likely because the loosely stacked frozen thin films provided a larger solid-air interface and the low thickness of the thin films provided a low mass transfer resistance. The highly porous microstructure and high specific surface area of the thin-film freeze-dried powders may also be related to the faster drying observed. Moreover, we demonstrated that TFF can be applied to produce dry powders of E. coli, a Gram-negative bacterium, or Lactobacillus acidophilus, a Gram-positive bacterium, with minimum bacterial viability loss (i.e., within one log reduction). It is concluded that the TFF technology is promising in accelerating water removal from frozen samples.

Published

2023

47. Increasing Drug Loading of Weakly Acidic Telmisartan in Amorphous Solid Dispersions through pH Modification during Hot-Melt Extrusion

Author

Stephen A. Thompson, Dan Davis, Robert O. Williams, and Chaeho Moon

Subjects

Active ingredient, Supersaturation, Chemistry, Drug Compounding, Hot Melt Extrusion Technology, Pharmaceutical Science, Hydrogen-Ion Concentration, Dosage form, Drug Liberation, Chemical engineering, Drug Discovery, medicine, Molecular Medicine, Extrusion, Dissolution testing, Telmisartan, Solubility, Dissolution, medicine.drug

Abstract

Oral drug therapy requiring large quantities of active pharmaceutical ingredients (APIs) can cause a substantial pill burden, which can increase nonadherence and worsen healthcare outcomes. Maximizing the drug loading of APIs in oral dosage forms is essential to reduce pill burden. This can be challenging for poorly water-soluble APIs without compromising performance. We show a promising strategy for maximizing the drug loading of pH-dependent APIs in amorphous solid dispersions (ASDs) produced by hot-melt extrusion (HME) without compromising their dissolution performance. We examine potential increases in the drug loading (w/w) of telmisartan in ASDs by incorporating bases to modify pH during HME. Telmisartan is a weakly acidic, poorly water-soluble API with pH-dependent solubility. It is practically insoluble at physiological pH, but its solubility increases exponentially at pH values above 10. Telmisartan was extruded with the polymer Soluplus and various bases. With no base, the maximum drug loading achieved by extrusion was only 5% before crystalline telmisartan was detected. Including a strong, water-soluble base (NaOH or KOH) increased the maximum amorphous drug loading to 50%. These results indicate that telmisartan has pH-dependent solubility in a molten polymer, similar to that in an aqueous solution. We also examine the stability of Soluplus when extruded with a strong base, using solid-state nuclear magnetic resonance (ssNMR) to determine that NaOH (but not KOH) causes degradation by hydrolysis. Supersaturation was maintained for at least 20 h during dissolution testing of a 50% telmisartan ASD in biorelevant media.

Published

2021

48. In vivo pharmacokinetic study of remdesivir dry powder for inhalation in hamsters

Author

Esther Y. Maier, Chaeho Moon, Sawittree Sahakijpijarn, Jennie E. DeVore, Dale J. Christensen, Zachary N. Warnken, Robert O. Williams, and John J. Koleng

Subjects

Lung, Thin film freezing, Inhalation, Chemistry, SARS-CoV-2, Cmax, Remdesivir, Pharmaceutical Science, COVID-19, Absorption (skin), Pharmacology, Dosage form, RS1-441, medicine.anatomical_structure, Dry powder for inhalation, Pharmacy and materia medica, Pharmacokinetics, Dry powder, In vivo, medicine, Research Paper

Abstract

Remdesivir dry powder for inhalation was previously developed using thin film freezing (TFF). A single-dose 24-h pharmacokinetic study in hamsters demonstrated that pulmonary delivery of TFF remdesivir can achieve plasma remdesivir and GS-441524 levels higher than the reported EC50s of both remdesivir and GS-441524 (in human epithelial cells) over 20 h. The half-life of GS-4412524 following dry powder insufflation was about 7 h, suggesting the dosing regimen would be twice-daily administration. Although the remdesivir-Captisol® (80/20 w/w) formulation showed faster and greater absorption of remdesivir and GS-4412524 in the lung, remdesivir-leucine (80/20 w/w) exhibited a greater Cmax with shorter Tmax and lower AUC of GS-441524, indicating lower total drug exposure is required to achieve a high effective concentration against SAR-CoV-2. In conclusion, remdesivir dry powder for inhalation would be a promising alternative dosage form for the treatment of COVID-19 disease., Graphical abstract Unlabelled Image

Published

2021

49. Dry Powders for Inhalation Containing Monoclonal Antibodies Made by Thin-Film Freeze-Drying

Author

Sawittree Sahakijpijarn, Laura Q.M. Chow, Stephanie Hufnagel, Zhengrong Cui, Chaeho Moon, Robert O. Williams, and Haiyue Xu

Subjects

Pharmaceutical Science, Lactose, Excipients, chemistry.chemical_compound, Freeze-drying, Antineoplastic Agents, Immunological, Leucine, Degree Celsius, Administration, Inhalation, medicine, Particle Size, Aerosols, Polyvinylpyrrolidone, Chemistry, Antibodies, Monoclonal, Dry Powder Inhalers, Trehalose, Immunoglobulin G, Drug delivery, Tumor Necrosis Factor Inhibitors, Composition (visual arts), Powders, medicine.drug, Nuclear chemistry

Abstract

Thin-film freeze-drying (TFFD) is a rapid freezing and then drying technique used to prepare inhalable dry powders from the liquid form for drug delivery to the lungs. We report the preparation of aerosolizable dry powders of monoclonal antibodies (mAbs) by TFFD. We first formulated IgG with lactose/leucine (60:40 w/w) or trehalose/leucine (75:25). IgG 1% (w/w) formulated with lactose/leucine (60:40 w/w) in phosphate buffered saline (PBS) (IgG-1-LL-PBS) and processed by TFFD was found to produce the powder with the most desirable aerosol properties. We then replaced IgG with a specific antibody, anti-programmed cell death protein (anti-PD-1 mAb), to prepare a dry powder (anti-PD1-1-LL-PBS), which performed similarly to the IgG-1-LL-PBS powder. The aerosol properties of anti-PD1-1-LL-PBS were significantly better when TFFD was used to prepare the powder as compared to conventional shelf freeze-drying (shelf FD). The dry powder had a porous structure with nanoaggregates. The dry powder had a Tg value between 39-50 °C. When stored at room temperature, the anti-PD-1 mAb in the TFFD powder was more stable than that of the same formulation stored as a liquid. The addition of polyvinylpyrrolidone (PVP) K40 in the formulation was able to raise the Tg to 152 °C, which is expected to further increase the storage stability of the mAbs. The PD-1 binding activities of the anti-PD-1 mAbs before and after TFFD were not different. While protein loss, likely due to protein binding to glass or plastic vials and the TFF apparatus, was identified, we were able to minimize the loss by increasing mAb content in the powders. Lastly, we show that another mAb, anti-TNF-α, can also be converted to a dry powder with a similar composition by TFFD. We conclude that TFFD can be applied to produce stable aerosolizable dry powders of mAbs for pulmonary delivery.

Published

2021

50. AUG-3387, a Human-Derived Monoclonal Antibody Neutralizes SARS-CoV-2 Variants and Reduces Viral Load from Therapeutic Treatment of Hamsters In Vivo

Author

Christian John Ventura, Philip J. Kuehl, Xammy Nguyenla, Marco Antonio Mena, Douglas M. Fox, Robert O. Williams, David Revelli, Chaeho Moon, Steven J Henry, Christopher J. Emig, Dale J. Christensen, Haiyue Xu, Zhengrong Cui, Adela Vitug, and Sawittree Sahakijjpijarn

Subjects

biology, Chemistry, medicine.drug_class, medicine.medical_treatment, Intraperitoneal injection, Monoclonal antibody, Virology, Virus, Neutralization, In vitro, In vivo, biology.protein, medicine, Antibody, Viral load

Abstract

Infections from the SARS-CoV-2 virus have killed over 4.6 million people since it began spreading through human populations in late 2019. In order to develop a therapeutic or prophylactic antibody to help mitigate the effects of the pandemic, a human monoclonal antibody (mAb) that binds to the SARS-CoV-2 spike protein was isolated from a convalescent patient following recovery from COVID-19 disease. This mAb, designated AUG-3387, demonstrates a high affinity for the spike protein of the original viral strains and all variants tested to date. In vitro pseudovirus neutralization and SARS-CoV-2 neutralization activity has been demonstrated in vitro. In addition, a dry powder formulation has been prepared using a Thin-Film Freezing (TFF) process that exhibited a fine particle fraction (FPF) of 50.95 ± 7.69% and a mass median aerodynamic diameter (MMAD) and geometric standard deviation (GSD) of 3.74 ± 0.73 µm and 2.73 ± 0.20, respectively. The dry powder is suitable for delivery directly to the lungs of infected patients using a dry powder inhaler device. Importantly, AUG-3387, administered as a liquid by intraperitoneal injection or the dry powder formulation delivered intratracheally into Syrian hamsters 24 hours after intranasal SARS-CoV-2 infection, demonstrated a dose-dependent reduction in the lung viral load of the virus. These data suggest that AUG-3387 formulated as a dry powder demonstrates potential to treat COVID-19.

Published

2021