Your search keyword '"In situ amorphization"' showing total 36 results

1. In Situ Amorphization of Electrocatalysts.

Author

Meng, Huishan, Chen, Zhijie, Zhu, Jinliang, You, Bo, Ma, Tianyi, Wei, Wei, Vernuccio, Sergio, Xu, Juan, and Ni, Bing‐Jie

Subjects

*OXIDATION-reduction reaction, *CATALYST structure, *CHEMICAL synthesis, *ENERGY conversion, *AMORPHIZATION

Abstract

Electrocatalysis represents an efficient and eco‐friendly approach to energy conversion, enabling the sustainable synthesis of valuable chemicals and fuels. The deliberate engineering of electrocatalysts is crucial to improving the efficacy and scalability of electrocatalysis. Notably, the occurrence of in situ amorphization within electrocatalysts has been observed during various electrochemical processes, influencing the energy conversion efficiency and catalytic mechanism understanding. Of note, the dynamic transformation of catalysts into amorphous structures is complex, often leading to various amorphous configurations. Therefore, revealing this amorphization process and understanding the function of amorphous species are pivotal for elucidating the structure‐activity relationship of electrocatalysts, which will direct the creation of highly efficient catalysts. This review examines the mechanisms behind amorphous structure formation, summarizes characterization methods for detecting amorphous species, and discusses strategies for controlling (pre)catalyst properties and electrochemical conditions that influence amorphization. It also emphasizes the importance of spontaneously formed amorphous species in electrochemical oxidation and reduction reactions. Finally, it addresses challenges in the in situ amorphization of electrocatalysts. aiming to guide the synthesis of electrocatalysts for efficient, selective, and stable electrochemical reactions, and to inspire future advancements in the field. [ABSTRACT FROM AUTHOR]

Published

2024

2. From design to application: Iron oxide nanoparticles for imaging and therapeutics in inflammatory and infectious diseases

Author

Ansari, Shaquib Rahman and Ansari, Shaquib Rahman

Abstract

Superparamagnetic iron oxide nanoparticles (SPIONs) are a promising advancement in nanomedicine, demonstrating remarkable potential in both diagnostic and therapeutic applications. They can be magnetized in a magnetic field and do not show permanent magnetization, allowing precise localization within the body. Under an alternating magnetic field, SPIONs generate heat, which can be used for magnetic hyperthermia therapy against cancer or to trigger drug release. Diagnostically, they are widely used as contrast agents for magnetic resonance imaging (MRI), while magnetic particle imaging (MPI) is an emerging preclinical diagnostic technique using SPIONs as tracers. Despite these promising applications, the clinical utility of SPIONs is hindered by challenges related to scalable and reproducible manufacturing. Focused efforts are also needed to improve MPI resolution. Moreover, the application of magnetic hyperthermia for treating inflammatory and infectious conditions remains relatively underexplored. Therefore, the primary objective of this thesis was to develop SPIONs tailored for imaging and therapy of inflammatory and infectious diseases through scalable manufacturing techniques. The first part of the study involved a systematic review to examine the most pertinent research on use of SPIONs for diagnosing and treating chronic inflammatory diseases. MRI was identified as the predominant application of SPIONs. However, there was limited exploration of MPI and magnetic hyperthermia for imaging and treating inflammatory diseases, respectively. In the second project, a risk-based pharmaceutical quality by design approach was used to optimize SPIONs for magnetic hyperthermia. The effect of nanoparticle properties on MPI performance was systematically investigated in the third project. Additionally, these projects established flame spray pyrolysis as a scalable and reproducible technique, for synthesizing nanoparticles with complex stoichiometry for magnetic hyperthermia

Published

2024

3. Use of solid thermolytic salts to facilitate microwave-induced in situ amorphization

Author

Qiang, Wei, Zhang, Meng, Löbmann, Korbinian, McCoy, Colin P., Andrews, Gavin P., Zhao, Min, Qiang, Wei, Zhang, Meng, Löbmann, Korbinian, McCoy, Colin P., Andrews, Gavin P., and Zhao, Min

Abstract

Moisture was frequently used as dielectric heating source in classical microwave-able systems to facilitate microwave-induced in situ amorphization, however such systems may face the potential of drug hydrolysis. In this study, solid thermolytic salts were proposed to function as moisture substitutes and their feasibility and impacts on microwave-induced in situ amorphization were investigated. It was found that NH4HCO3 was a promising solid alkaline salt to facilitate both microwave-induced in situ amorphization and in situ salt formation of acidic indomethacin (IND). Moreover, it could improve the chemical stability of the drug and the dissolution performance of compacts relative to classical moisture-based compacts upon microwaving. Further mechanistic study suggested that the in situ amorphization occurred prior to the in situ salt formation, especially in formulations with low drug loadings and high solid salt mass ratios. For compacts with low polymer ratios, in situ salt formation took place subsequently, where the previously amorphized IND within compacts could interact with the NH3 gas produced in situ by the decomposition of NH4HCO3 and form the ammonium IND salt. Microwaving time showed great impacts on the decomposition of NH4HCO3 and the in situ generation of water and NH3, which indirectly affected the amorphization and salt formation of IND. In comparison to the moisture-based systems, the NH4HCO3-based system showed a number of advantages, including the reduced potential of IND hydrolysis due to the absence of absorbed moisture, a wider category of applicable polymeric carriers other than hygroscopic polymers, and an increase in drug loading up to 50% (w/w).

Published

2024

4. Microwave-Induced in Situ Drug Amorphization Using a Mixture of Polyethylene Glycol and Polyvinylpyrrolidone.

Author

Hempel, Nele-Johanna, Knopp, Matthias M., Zeitler, J. Axel, Berthelsen, Ragna, and Löbmann, Korbinian

Subjects

*POLYETHYLENE glycol, *DRUG utilization, *POLYMER blends, *AMORPHOUS substances, *AMORPHIZATION, *POVIDONE

Abstract

The use of a mixture of polyethylene glycol (PEG) and polyvinylpyrrolidone (PVP) was investigated for microwave-induced in situ amorphization of celecoxib (CCX) inside compacts. Such amorphization requires the presence of a dipolar excipient in the formulation to ensure heating of the compact by absorption of the microwaves. Previously, the hygroscopic nature of PVP was exploited for this purpose. By exposing PVP-based compacts for set time intervals at defined relative humidity, controlled water sorption into the compacts was achieved. In the present study, PEG was proposed as the microwave absorbing excipient instead of water, to avoid the water sorption step. However, it was found that PEG alone melted upon exposure to microwave radiation and caused the compact to deform. Furthermore, CCX was found to recrystallize upon cooling in PEG-based formulations. Hence, a mixture of PEG and PVP was used, where the presence of PVP preserved the physical shape of the compact, and the physical state of the amorphous solid dispersion. To study the impact of the polymer mixture, different compact compositions of CCX, PEG and PVP were prepared. When exposing the compacts to microwave radiation, it was found that the PEG:PVP ratio was critical for in situ amorphization and that complete amorphization was only achieved above a certain temperature threshold. Microwave-induced in situ amorphization was achieved using compact containing a physical mixture of the model drug celecoxib and the polymers, polyethylene glycol and polyvinylpyrrolidone. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2021

5. The Use of Glycerol as an Enabling Excipient for Microwave-Induced In Situ Drug Amorphization.

Author

Hempel, Nele-Johanna, Morsch, Flemming, Knopp, Matthias Manne, Berthelsen, Ragna, and Löbmann, Korbinian

Subjects

*AMORPHIZATION, *AMORPHOUS substances, *HIGH temperatures, *SUPERSATURATION, *RADIATION exposure, *GLYCERIN

Abstract

Microwave-induced in situ amorphization is a promising approach to circumvent stability and manufacturing issues associated with amorphous solid dispersions (ASD). Using in situ amorphization, the crystalline state of the drug is converted into its amorphous form inside the dosage form, e.g. a compact, upon exposure to microwave radiation. The study aimed to investigate the feasibility of using glycerol as an enabling excipient in compacts prepared from mixtures of indomethacin and Soluplus®. Additionally, the possibility to form a supersaturated ASD upon exposure to microwave radiation due to elevated temperatures was investigated. It was found that glycerol i) acts as a dielectric heating source absorbing the microwaves, ii) plasticizes the polymer Soluplus® and iii) increases the solubility of the drug indomethacin in the polymer Soluplus®. Additionally, it was found that fully amorphous ASDs could be achieved with drug loadings below -, and slightly above the saturation solubility of indomethacin in the Soluplus®/glycerol mixtures, after exposure to 20 min of microwave radiation. Hence, glycerol was a feasible excipient for the microwave-induced in situ amorphization and allowed the preparation of a, at room temperature, supersaturated ASD, due to the elevated temperatures obtained during exposure to microwave radiation. [ABSTRACT FROM AUTHOR]

Published

2021

6. The influence of drug and polymer particle size on the in situ amorphization using microwave irradiation.

Author

Hempel, Nele-Johanna, Knopp, Matthias M., Berthelsen, Ragna, Zeitler, J. Axel, and Löbmann, Korbinian

Subjects

*AMORPHIZATION, *PARTICLES, *AMORPHOUS substances, *SIZE reduction of materials, *GLASS transition temperature

Abstract

In this study, the impact of drug and polymer particle size on the in situ amorphization using microwave irradiation at a frequency of 2.45 GHz were investigated. Using ball milling and sieve fractioning, the crystalline drug celecoxib (CCX) and the polymer polyvinylpyrrolidone (PVP) were divided into two particle size fractions, i.e. small (<71 µm) and large (>71 µm) particles. Subsequently, compacts containing a drug load of 30% (w/w) crystalline CCX in PVP were prepared and subjected to microwave radiation for an accumulated duration of 600 sec in intervals of 60 sec as well as continuously for 600 sec. It was found that the compacts containing small CCX particles displayed faster rates of amorphization and a higher degree of amorphization during microwave irradiation as compared to the compacts containing large CCX particles. For compacts with small CCX particles, interval exposure to microwave radiation resulted in a maximum degree of amorphization of 24%, whilst a fully amorphous solid dispersion (100%) was achieved after 600 sec of continuous exposure to microwave radiation. By monitoring the temperature in the core of the compacts during exposure to microwave radiation using a fiber optic temperature probe, it was found that the total exposure time above the glass transition temperature (T g) was shorter for the interval exposure method compared to continuous exposure to microwave radiation. Therefore, it is proposed that the in situ formation of an amorphous solid dispersion is governed by the dissolution of drug into the polymer, which most likely is accelerated above the T g of the compacts. Hence, prolonging the exposure time above the T g , and increasing the surface area of the drug by particle size reduction will increase the dissolution rate and thus, rate and degree of amorphization of CCX during exposure to microwave radiation. [ABSTRACT FROM AUTHOR]

Published

2020

7. The effects of surfactants on the performance of polymer-based microwave-induced in situ amorphization

Author

Qiang, Wei, Löbmann, Korbinian, McCoy, Colin P., Andrews, Gavin P., Zhao, Min, Qiang, Wei, Löbmann, Korbinian, McCoy, Colin P., Andrews, Gavin P., and Zhao, Min

Abstract

Microwave-induced in situ amorphization is a novel technology for preparing amorphous solid dispersions (ASDs) to address the challenges of their long-term physical stability and downstream processing. To date, only few types of dielectric materials have been reported for microwave-induced in situ amorphization, which restricted the extensive research of this technology. This study aimed to investigate the feasibility and mechanisms of utilizing the non-ionic surfactants, i.e. Kollisolv P124, Kolliphor RH40, D-ɑ-tocopheryl polyethylene glycol succinate (TPGS), Tween (T) 60 (T60), T65, T80 and T85, as plasticizers to facilitate microwave-induced in situ amorphization. It was found that the successful application of surfactants could be related with their low Tm, low Mw and high HLB. Kolliphor RH40 was selected as a typical surfactant due to its excellent dielectric heating ability, plasticizing effect and solubilizing effect when facilitating amorphization. Then, the dissolution-mediated in situ amorphization mechanism was investigated and intuitively demonstrated. For the most promising formulation, i.e. microwaved systems with Korlliphor RH40 at 1.5 (w/w) plasticizer/polymer ratio, a complete and fast in vitro dissolution was observed relative to the untreated systems. In conclusion, non-ionic surfactants had the potential to facilitate microwave-induced in situ amorphization, which provided a new direction in the formulation designation for microwave-able systems.

Published

2023

8. Recent Technologies for Amorphization of Poorly Water-Soluble Drugs

Author

Dohyun Kim, Youngwoo Kim, Yee-Yee Tin, Mya-Thet-Paing Soe, Byounghyen Ko, Sunjae Park, and Jaehwi Lee

Subjects

amorphous formulation, solid dispersion, co-amorphous, co-amorphization, in situ amorphization, microwave, Pharmacy and materia medica, RS1-441

Abstract

Amorphization technology has been the subject of continuous attention in the pharmaceutical industry, as a means to enhance the solubility of poorly water-soluble drugs. Being in a high energy state, amorphous formulations generally display significantly increased apparent solubility as compared to their crystalline counterparts, which may allow them to generate a supersaturated state in the gastrointestinal tract and in turn, improve the bioavailability. Conventionally, hydrophilic polymers have been used as carriers, in which the amorphous drugs were dispersed and stabilized to form polymeric amorphous solid dispersions. However, the technique had its limitations, some of which include the need for a large number of carriers, the tendency to recrystallize during storage, and the possibility of thermal decomposition of the drug during preparation. Therefore, emerging amorphization technologies have focused on the investigation of novel amorphous-stabilizing carriers and preparation methods that can improve the drug loading and the degree of amorphization. This review highlights the recent pharmaceutical approaches utilizing drug amorphization, such as co-amorphous systems, mesoporous particle-based techniques, and in situ amorphization. Recent updates on these technologies in the last five years are discussed with a focus on their characteristics and commercial potential.

Published

2021

9. The Effect of the Molecular Weight of Polyvinylpyrrolidone and the Model Drug on Laser-Induced In Situ Amorphization

Author

Nele-Johanna Hempel, Padryk Merkl, Matthias Manne Knopp, Ragna Berthelsen, Alexandra Teleki, Anders Kragh Hansen, Georgios A. Sotiriou, and Korbinian Löbmann

Subjects

in situ amorphization, near-IR laser radiation, amorphous solid dispersion, plasmonic photothermal nanoparticles, dissolution kinetics, Organic chemistry, QD241-441

Abstract

Laser radiation has been shown to be a promising approach for in situ amorphization, i.e., drug amorphization inside the final dosage form. Upon exposure to laser radiation, elevated temperatures in the compacts are obtained. At temperatures above the glass transition temperature (Tg) of the polymer, the drug dissolves into the mobile polymer. Hence, the dissolution kinetics are dependent on the viscosity of the polymer, indirectly determined by the molecular weight (Mw) of the polymer, the solubility of the drug in the polymer, the particle size of the drug and the molecular size of the drug. Using compacts containing 30 wt% of the drug celecoxib (CCX), 69.25 wt% of three different Mw of polyvinylpyrrolidone (PVP: PVP12, PVP17 or PVP25), 0.25 wt% plasmonic nanoaggregates (PNs) and 0.5 wt% lubricant, the effect of the polymer Mw on the dissolution kinetics upon exposure to laser radiation was investigated. Furthermore, the effect of the model drug on the dissolution kinetics was investigated using compacts containing 30 wt% of three different drugs (CCX, indomethacin (IND) and naproxen (NAP)), 69.25 wt% PVP12, 0.25 wt% PN and 0.5 wt% lubricant. In perfect correlation to the Noyes–Whitney equation, this study showed that the use of PVP with the lowest viscosity, i.e., the lowest Mw (here PVP12), led to the fastest rate of amorphization compared to PVP17 and PVP25. Furthermore, NAP showed the fastest rate of amorphization, followed by IND and CCX in PVP12 due to its high solubility and small molecular size.

Published

2021

10. Use of solid thermolytic salts to facilitate microwave-induced in situ amorphization.

Author

Qiang W, Zhang M, Löbmann K, McCoy CP, Andrews GP, and Zhao M

Subjects

Drug Stability, Crystallization, Polymers chemistry, Solubility, Salts, Microwaves

Abstract

Moisture was frequently used as dielectric heating source in classical microwave-able systems to facilitate microwave-induced in situ amorphization, however such systems may face the potential of drug hydrolysis. In this study, solid thermolytic salts were proposed to function as moisture substitutes and their feasibility and impacts on microwave-induced in situ amorphization were investigated. It was found that NH 4 HCO 3 was a promising solid alkaline salt to facilitate both microwave-induced in situ amorphization and in situ salt formation of acidic indomethacin (IND). Moreover, it could improve the chemical stability of the drug and the dissolution performance of compacts relative to classical moisture-based compacts upon microwaving. Further mechanistic study suggested that the in situ amorphization occurred prior to the in situ salt formation, especially in formulations with low drug loadings and high solid salt mass ratios. For compacts with low polymer ratios, in situ salt formation took place subsequently, where the previously amorphized IND within compacts could interact with the NH 3 gas produced in situ by the decomposition of NH 4 HCO 3 and form the ammonium IND salt. Microwaving time showed great impacts on the decomposition of NH 4 HCO 3 and the in situ generation of water and NH 3 , which indirectly affected the amorphization and salt formation of IND. In comparison to the moisture-based systems, the NH 4 HCO 3 -based system showed a number of advantages, including the reduced potential of IND hydrolysis due to the absence of absorbed moisture, a wider category of applicable polymeric carriers other than hygroscopic polymers, and an increase in drug loading up to 50% (w/w)., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

11. Studying the Impact of the Temperature and Sorbed Water during Microwave-Induced In Situ Amorphization: A Case Study of Celecoxib and Polyvinylpyrrolidone

Author

Nele-Johanna Hempel, Matthias M. Knopp, Korbinian Löbmann, and Ragna Berthelsen

Subjects

in situ amorphization, microwave radiation, amorphous solid dispersion, dissolution, celecoxib, polyvinylpyrrolidone, Pharmacy and materia medica, RS1-441

Abstract

Microwave-induced in situ amorphization of a drug into a polymeric amorphous solid dispersion (ASD) has been suggested to follow a dissolution process of the drug into the polymeric network, at temperatures above the glass transition temperature (Tg) of the polymer. Thus, increasing the compact temperature, above the Tg of the polymer, is expected to increase the rate of drug dissolution in the mobile polymer, i.e., the rate of amorphization, in a direct proportional fashion. To test this hypothesis, the present study aimed at establishing a linear correlation between the compact temperature and the rate of drug amorphization using celecoxib (CCX) and the polymers polyvinylpyrrolidone (PVP) 12 and PVP17 as the model systems. Water sorbed into the drug–polymer compacts during 2 weeks of storage at 75% relative humidity was used as the dielectric heating source for the present drug amorphization process, and therefore directly affected the compact temperature during exposure to microwave radiation; the loss of water during heating was also studied. For this, compacts prepared with 30 wt% CCX, 69.5 wt% PVP12 or PVP17 and 0.5 wt% magnesium stearate (lubricant) were conditioned to have a final water content of approx. 20 wt%. The conditioned compacts were exposed to microwave radiation for 10 min at variable power outputs to achieve different compact temperatures. For compacts containing CCX in both PVP12 and PVP17, a linear correlation was established between the measured compact end temperature and the rate of drug amorphization during 10 min of exposure to microwave radiation. For compacts containing CCX in PVP12, a fully amorphous ASD was obtained after 10 min of exposure to microwave radiation with a measured compact end temperature of 71 °C. For compacts containing CCX in PVP17, it was not possible to obtain a fully amorphous ASD. The reason for this is most likely that a fast evaporation of the sorbed water increased the Tg of the conditioned drug–polymer compacts to temperatures above the highest reachable compact temperature during exposure to microwave radiation in the utilized experimental setup. Supporting this conclusion, evaporation of the sorbed water was observed to be faster for compacts containing PVP17 compared to compacts containing PVP12.

Published

2021

12. The Influence of Temperature and Viscosity of Polyethylene Glycol on the Rate of Microwave-Induced In Situ Amorphization of Celecoxib

Author

Nele-Johanna Hempel, Tra Dao, Matthias M. Knopp, Ragna Berthelsen, and Korbinian Löbmann

Subjects

in situ amorphization, microwave radiation, polyethylene glycol, viscosity, temperature, dissolution, Organic chemistry, QD241-441

Abstract

Microwaved-induced in situ amorphization of a drug in a polymer has been suggested to follow a dissolution process, with the drug dissolving into the mobile polymer at temperatures above the glass transition temperature (Tg) of the polymer. Thus, based on the Noyes–Whitney and the Stoke–Einstein equations, the temperature and the viscosity are expected to directly impact the rate and degree of drug amorphization. By investigating two different viscosity grades of polyethylene glycol (PEG), i.e., PEG 3000 and PEG 4000, and controlling the temperature of the microwave oven, it was possible to study the influence of both, temperature and viscosity, on the in situ amorphization of the model drug celecoxib (CCX) during exposure to microwave radiation. In this study, compacts containing 30 wt% CCX, 69 wt% PEG 3000 or PEG 4000 and 1 wt% lubricant (magnesium stearate) were exposed to microwave radiation at (i) a target temperature, or (ii) a target viscosity. It was found that at the target temperature, compacts containing PEG 3000 displayed a faster rate of amorphization as compared to compacts containing PEG 4000, due to the lower viscosity of PEG 3000 compared to PEG 4000. Furthermore, at the target viscosity, which was achieved by setting different temperatures for compacts containing PEG 3000 and PEG 4000, respectively, the compacts containing PEG 3000 displayed a slower rate of amorphization, due to a lower target temperature, than compacts containing PEG 4000. In conclusion, with lower viscosity of the polymer, at temperatures above its Tg, and with higher temperatures, both increasing the diffusion coefficient of the drug into the polymer, the rate of amorphization was increased allowing a faster in situ amorphization during exposure to microwave radiation. Hereby, the theory that the microwave-induced in situ amorphization process can be described as a dissolution process of the drug into the polymer, at temperatures above the Tg, is further strengthened.

Published

2020

13. Microwave-Induced In Situ Amorphization: A New Strategy for Tackling the Stability Issue of Amorphous Solid Dispersions

Author

Wei Qiang, Korbinian Löbmann, Colin P. McCoy, Gavin P. Andrews, and Min Zhao

Subjects

microwave irradiation, amorphous solid dispersions, poorly soluble drugs, in situ amorphization, physical stability, Pharmacy and materia medica, RS1-441

Abstract

The thermodynamically unstable nature of amorphous drugs has led to a persistent stability issue of amorphous solid dispersions (ASDs). Lately, microwave-induced in situ amorphization has been proposed as a promising solution to this problem, where the originally loaded crystalline drug is in situ amorphized within the final dosage form using a household microwave oven prior to oral administration. In addition to circumventing issues with physical stability, it can also simplify the problematic downstream processing of ASDs. In this review paper, we address the significance of exploring and developing this novel technology with an emphasis on systemically reviewing the currently available literature in this pharmaceutical arena and highlighting the underlying mechanisms involved in inducing in situ amorphization. Specifically, in order to achieve a high drug amorphicity, formulations should be composed of drugs with high solubility in polymers, as well as polymers with high hygroscopicity and good post-plasticized flexibility of chains. Furthermore, high microwave energy input is considered to be a desirable factor. Lastly, this review discusses challenges in the development of this technology including chemical stability, selection criteria for excipients and the dissolution performance of the microwave-induced ASDs.

Published

2020

14. Convection-Induced vs. Microwave Radiation-Induced in situ Drug Amorphization

Author

Nele-Johanna Hempel, Matthias M. Knopp, Ragna Berthelsen, and Korbinian Löbmann

Subjects

in situ amorphization, microwave heating, convection heating, amorphous solid dispersion, glass solution, Organic chemistry, QD241-441

Abstract

The aim of the study was to investigate the suitability of a convection oven to induce in situ amorphization. The study was conducted using microwave radiation-induced in situ amorphization as reference, as it has recently been shown to enable the preparation of a fully (100%) amorphous solid dispersion of celecoxib (CCX) in polyvinylpyrrolidone (PVP) after 10 min of continuous microwaving. For comparison, the experimental setup of the microwave-induced method was mimicked for the convection-induced method. Compacts containing crystalline CCX and PVP were prepared and either pre-conditioned at 75% relative humidity or kept dry to investigate the effect of sorbed water on the amorphization kinetics. Subsequently, the compacts were heated for 5, 10, 15, 20, or 30 min in the convection oven at 100 °C. The degree of amorphization of CCX in the compacts was subsequently quantified using transmission Raman spectroscopy. Using the convection oven, the maximum degree of amorphization achieved was 96.1% ± 2.1% (n = 3) for the conditioned compacts after 30 min of heating and 14.3% ± 1.4% (n = 3) for the dry compacts after 20 min of heating, respectively. Based on the results from the convection and the microwave oven, it was found that the sorbed water acts as a plasticizer in the conditioned compacts (i.e., increasing molecular mobility), which is advantageous for in situ amorphization in both methods. Since the underlying mechanism of heating between the convection oven and microwave oven differs, it was found that convection-induced in situ amorphization is inferior to microwave radiation-induced in situ amorphization in terms of amorphization kinetics with the present experimental setup.

Published

2020

15. Influence of PVP molecular weight on the microwave assisted in situ amorphization of indomethacin.

Author

Doreth, Maria, Löbmann, Korbinian, Priemel, Petra, Grohganz, Holger, Taylor, Robert, Holm, René, Lopez de Diego, Heidi, and Rades, Thomas

Subjects

*POVIDONE, *MOLECULAR weights, *AMORPHIZATION, *INDOMETHACIN, *DRUG administration

Abstract

In situ amorphization is an approach that enables a phase transition of a crystalline drug to its amorphous form immediately prior to administration. In this study, three different polyvinylpyrrolidones (PVP K12, K17 and K25) were selected to investigate the influence of the molecular weight of the polymer on the degree of amorphization of the model drug indomethacin (IND) upon microwaving. Powder mixtures of crystalline IND and the respective PVP were compacted at 1:2 (w/w) IND:PVP ratios, stored at 54% RH and subsequently microwaved with a total energy input of 90 or 180 kJ. After storage, all compacts had a similar moisture content (∼10% (w/w)). Upon microwaving with an energy input of 180 kJ, 58 ± 4% of IND in IND:PVP K12 compacts was amorphized, whereas 31 ± 8% of IND was amorphized by an energy input of 90 kJ. The drug stayed fully crystalline in all IND:PVP K17 and IND:PVP K25 compacts. After plasticization by moisture, PVP K12 reached a T g below ambient temperature (16 ± 2 °C) indicating that the T g of the plasticized polymer is a key factor for the success of in situ amorphization. DSC analysis showed that the amorphized drug was part of a ternary glass solution consisting of IND, PVP K12 and water. In dissolution tests, IND:PVP K12 compacts showed a delayed initial drug release due to a lack of compact disintegration, but reached a higher total drug release eventually. In summary, this study showed that the microwave assisted in situ amorphization was highly dependent on the T g of the plasticized polymer. [ABSTRACT FROM AUTHOR]

Published

2018

16. Studying the impact of the temperature and sorbed water during microwave-induced In Situ amorphization:A case study of celecoxib and polyvinylpyrrolidone

Author

Hempel, Nele Johanna, Knopp, Matthias M., Löbmann, Korbinian, Berthelsen, Ragna, Hempel, Nele Johanna, Knopp, Matthias M., Löbmann, Korbinian, and Berthelsen, Ragna

Abstract

Microwave-induced in situ amorphization of a drug into a polymeric amorphous solid dispersion (ASD) has been suggested to follow a dissolution process of the drug into the polymeric network, at temperatures above the glass transition temperature (Tg ) of the polymer. Thus, increasing the compact temperature, above the Tg of the polymer, is expected to increase the rate of drug dissolution in the mobile polymer, i.e., the rate of amorphization, in a direct proportional fashion. To test this hypothesis, the present study aimed at establishing a linear correlation between the compact temperature and the rate of drug amorphization using celecoxib (CCX) and the polymers polyvinylpyrrolidone (PVP) 12 and PVP17 as the model systems. Water sorbed into the drug–polymer compacts during 2 weeks of storage at 75% relative humidity was used as the dielectric heating source for the present drug amorphization process, and therefore directly affected the compact temperature during exposure to microwave radiation; the loss of water during heating was also studied. For this, compacts prepared with 30 wt% CCX, 69.5 wt% PVP12 or PVP17 and 0.5 wt% magnesium stearate (lubricant) were conditioned to have a final water content of approx. 20 wt%. The conditioned compacts were exposed to microwave radiation for 10 min at variable power outputs to achieve different compact temperatures. For compacts containing CCX in both PVP12 and PVP17, a linear correlation was established between the measured compact end temperature and the rate of drug amorphization during 10 min of exposure to microwave radiation. For compacts containing CCX in PVP12, a fully amorphous ASD was obtained after 10 min of exposure to microwave radiation with a measured compact end temperature of 71◦C. For compacts containing CCX in PVP17, it was not possible to obtain a fully amorphous ASD. The reason for this is most likely that a fast evaporation of the sorbed water increased the Tg

Published

2021

17. The Effect of the Molecular Weight of Polyvinylpyrrolidone and the Model Drug on Laser-Induced In Situ Amorphization

Author

Hempel, Nele-Johanna, Merkl, Padryk, Knopp, Matthias Manne, Berthelsen, Ragna, Teleki, Alexandra, Hansen, Anders Kragh, Sotiriou, Georgios A., Löbmann, Korbinian, Hempel, Nele-Johanna, Merkl, Padryk, Knopp, Matthias Manne, Berthelsen, Ragna, Teleki, Alexandra, Hansen, Anders Kragh, Sotiriou, Georgios A., and Löbmann, Korbinian

Abstract

Laser radiation has been shown to be a promising approach for in situ amorphization, i.e., drug amorphization inside the final dosage form. Upon exposure to laser radiation, elevated temperatures in the compacts are obtained. At temperatures above the glass transition temperature (T-g) of the polymer, the drug dissolves into the mobile polymer. Hence, the dissolution kinetics are dependent on the viscosity of the polymer, indirectly determined by the molecular weight (M-w) of the polymer, the solubility of the drug in the polymer, the particle size of the drug and the molecular size of the drug. Using compacts containing 30 wt% of the drug celecoxib (CCX), 69.25 wt% of three different M-w of polyvinylpyrrolidone (PVP: PVP12, PVP17 or PVP25), 0.25 wt% plasmonic nanoaggregates (PNs) and 0.5 wt% lubricant, the effect of the polymer M-w on the dissolution kinetics upon exposure to laser radiation was investigated. Furthermore, the effect of the model drug on the dissolution kinetics was investigated using compacts containing 30 wt% of three different drugs (CCX, indomethacin (IND) and naproxen (NAP)), 69.25 wt% PVP12, 0.25 wt% PN and 0.5 wt% lubricant. In perfect correlation to the Noyes-Whitney equation, this study showed that the use of PVP with the lowest viscosity, i.e., the lowest M-w (here PVP12), led to the fastest rate of amorphization compared to PVP17 and PVP25. Furthermore, NAP showed the fastest rate of amorphization, followed by IND and CCX in PVP12 due to its high solubility and small molecular size.

Published

2021

18. The effect of the molecular weight of polyvinylpyrrolidone and the model drug on laser-induced in situ amorphization

Author

Hempel, Nele Johanna, Merkl, Padryk, Knopp, Matthias Manne, Berthelsen, Ragna, Teleki, Alexandra, Hansen, Anders Kragh, Sotiriou, Georgios A., Löbmann, Korbinian, Hempel, Nele Johanna, Merkl, Padryk, Knopp, Matthias Manne, Berthelsen, Ragna, Teleki, Alexandra, Hansen, Anders Kragh, Sotiriou, Georgios A., and Löbmann, Korbinian

Abstract

Laser radiation has been shown to be a promising approach for in situ amorphization, i.e., drug amorphization inside the final dosage form. Upon exposure to laser radiation, elevated temperatures in the compacts are obtained. At temperatures above the glass transition temperature (Tg) of the polymer, the drug dissolves into the mobile polymer. Hence, the dissolution kinetics are dependent on the viscosity of the polymer, indirectly determined by the molecular weight (Mw) of the polymer, the solubility of the drug in the polymer, the particle size of the drug and the molecular size of the drug. Using compacts containing 30 wt% of the drug celecoxib (CCX), 69.25 wt% of three different Mw of polyvinylpyrrolidone (PVP: PVP12, PVP17 or PVP25), 0.25 wt% plasmonic nanoaggregates (PNs) and 0.5 wt% lubricant, the effect of the polymer Mw on the dissolution kinetics upon exposure to laser radiation was investigated. Furthermore, the effect of the model drug on the dissolution kinetics was investigated using compacts containing 30 wt% of three different drugs (CCX, indomethacin (IND) and naproxen (NAP)), 69.25 wt% PVP12, 0.25 wt% PN and 0.5 wt% lubricant. In perfect correlation to the Noyes–Whitney equation, this study showed that the use of PVP with the lowest viscosity, i.e., the lowest Mw (here PVP12), led to the fastest rate of amorphization compared to PVP17 and PVP25. Furthermore, NAP showed the fastest rate of amorphization, followed by IND and CCX in PVP12 due to its high solubility and small molecular size.

Published

2021

19. Microwave-Induced in Situ Drug Amorphization Using a Mixture of Polyethylene Glycol and Polyvinylpyrrolidone

Author

Hempel, Nele Johanna, Knopp, Matthias M., Zeitler, J. Axel, Berthelsen, Ragna, Löbmann, Korbinian, Hempel, Nele Johanna, Knopp, Matthias M., Zeitler, J. Axel, Berthelsen, Ragna, and Löbmann, Korbinian

Abstract

The use of a mixture of polyethylene glycol (PEG) and polyvinylpyrrolidone (PVP) was investigated for microwave-induced in situ amorphization of celecoxib (CCX) inside compacts. Such amorphization requires the presence of a dipolar excipient in the formulation to ensure heating of the compact by absorption of the microwaves. Previously, the hygroscopic nature of PVP was exploited for this purpose. By exposing PVP-based compacts for set time intervals at defined relative humidity, controlled water sorption into the compacts was achieved. In the present study, PEG was proposed as the microwave absorbing excipient instead of water, to avoid the water sorption step. However, it was found that PEG alone melted upon exposure to microwave radiation and caused the compact to deform. Furthermore, CCX was found to recrystallize upon cooling in PEG-based formulations. Hence, a mixture of PEG and PVP was used, where the presence of PVP preserved the physical shape of the compact, and the physical state of the amorphous solid dispersion. To study the impact of the polymer mixture, different compact compositions of CCX, PEG and PVP were prepared. When exposing the compacts to microwave radiation, it was found that the PEG:PVP ratio was critical for in situ amorphization and that complete amorphization was only achieved above a certain temperature threshold.

Published

2021

20. The Influence of Temperature and Viscosity of Polyethylene Glycol on the Rate of Microwave-Induced In Situ Amorphization of Celecoxib

Author

Hempel, Nele-Johanna, Dao, Tra, Knopp, Matthias M., Berthelsen, Ragna, Lobmann, Korbinian, Hempel, Nele-Johanna, Dao, Tra, Knopp, Matthias M., Berthelsen, Ragna, and Lobmann, Korbinian

Abstract

Microwaved-induced in situ amorphization of a drug in a polymer has been suggested to follow a dissolution process, with the drug dissolving into the mobile polymer at temperatures above the glass transition temperature (T-g) of the polymer. Thus, based on the Noyes-Whitney and the Stoke-Einstein equations, the temperature and the viscosity are expected to directly impact the rate and degree of drug amorphization. By investigating two different viscosity grades of polyethylene glycol (PEG), i.e., PEG 3000 and PEG 4000, and controlling the temperature of the microwave oven, it was possible to study the influence of both, temperature and viscosity, on the in situ amorphization of the model drug celecoxib (CCX) during exposure to microwave radiation. In this study, compacts containing 30 wt% CCX, 69 wt% PEG 3000 or PEG 4000 and 1 wt% lubricant (magnesium stearate) were exposed to microwave radiation at (i) a target temperature, or (ii) a target viscosity. It was found that at the target temperature, compacts containing PEG 3000 displayed a faster rate of amorphization as compared to compacts containing PEG 4000, due to the lower viscosity of PEG 3000 compared to PEG 4000. Furthermore, at the target viscosity, which was achieved by setting different temperatures for compacts containing PEG 3000 and PEG 4000, respectively, the compacts containing PEG 3000 displayed a slower rate of amorphization, due to a lower target temperature, than compacts containing PEG 4000. In conclusion, with lower viscosity of the polymer, at temperatures above its T-g, and with higher temperatures, both increasing the diffusion coefficient of the drug into the polymer, the rate of amorphization was increased allowing a faster in situ amorphization during exposure to microwave radiation. Hereby, the theory that the microwave-induced in situ amorphization process can be described as a dissolution process of the drug into the polymer, at temperatures above the T-g, is further strengthened.

Published

2021

21. Recent Technologies for Amorphization of Poorly Water-Soluble Drugs

Author

Yee-Yee Tin, Byounghyen Ko, Jaehwi Lee, Young-Woo Kim, Mya-Thet-Paing Soe, Sunjae Park, and Dohyun Kim

Subjects

solid dispersion, Materials science, microwave, mesoporous particles, in situ amorphization, Pharmaceutical Science, Nanotechnology, Review, Mesoporous silica, Amorphous solid, Preparation method, RS1-441, Hydrophilic polymers, Water soluble, Pharmacy and materia medica, co-amorphous, amorphous formulation, mesoporous silica, Solubility, co-amorphization

Abstract

Amorphization technology has been the subject of continuous attention in the pharmaceutical industry, as a means to enhance the solubility of poorly water-soluble drugs. Being in a high energy state, amorphous formulations generally display significantly increased apparent solubility as compared to their crystalline counterparts, which may allow them to generate a supersaturated state in the gastrointestinal tract and in turn, improve the bioavailability. Conventionally, hydrophilic polymers have been used as carriers, in which the amorphous drugs were dispersed and stabilized to form polymeric amorphous solid dispersions. However, the technique had its limitations, some of which include the need for a large number of carriers, the tendency to recrystallize during storage, and the possibility of thermal decomposition of the drug during preparation. Therefore, emerging amorphization technologies have focused on the investigation of novel amorphous-stabilizing carriers and preparation methods that can improve the drug loading and the degree of amorphization. This review highlights the recent pharmaceutical approaches utilizing drug amorphization, such as co-amorphous systems, mesoporous particle-based techniques, and in situ amorphization. Recent updates on these technologies in the last five years are discussed with a focus on their characteristics and commercial potential.

Published

2021

22. Studying the Impact of the Temperature and Sorbed Water during Microwave-Induced In Situ Amorphization: A Case Study of Celecoxib and Polyvinylpyrrolidone

Author

Ragna Berthelsen, Korbinian Löbmann, Matthias Manne Knopp, and Nele-Johanna Hempel

Subjects

Materials science, Evaporation, Pharmaceutical Science, dissolution, 02 engineering and technology, polyvinylpyrrolidone, 030226 pharmacology & pharmacy, Article, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Pharmacy and materia medica, amorphous solid dispersion, Dielectric heating, medicine, Amorphous solid dispersion, Dissolution testing, Magnesium stearate, Dissolution, In situ amorphization, in situ amorphization, Polyvinylpyrrolidone, celecoxib, 021001 nanoscience & nanotechnology, Microwave radiation, Amorphous solid, RS1-441, microwave radiation, Chemical engineering, chemistry, Celecoxib, 0210 nano-technology, Glass transition, medicine.drug

Abstract

Microwave-induced in situ amorphization of a drug into a polymeric amorphous solid dispersion (ASD) has been suggested to follow a dissolution process of the drug into the polymeric network, at temperatures above the glass transition temperature (Tg) of the polymer. Thus, increasing the compact temperature, above the Tg of the polymer, is expected to increase the rate of drug dissolution in the mobile polymer, i.e., the rate of amorphization, in a direct proportional fashion. To test this hypothesis, the present study aimed at establishing a linear correlation between the compact temperature and the rate of drug amorphization using celecoxib (CCX) and the polymers polyvinylpyrrolidone (PVP) 12 and PVP17 as the model systems. Water sorbed into the drug–polymer compacts during 2 weeks of storage at 75% relative humidity was used as the dielectric heating source for the present drug amorphization process, and therefore directly affected the compact temperature during exposure to microwave radiation, the loss of water during heating was also studied. For this, compacts prepared with 30 wt% CCX, 69.5 wt% PVP12 or PVP17 and 0.5 wt% magnesium stearate (lubricant) were conditioned to have a final water content of approx. 20 wt%. The conditioned compacts were exposed to microwave radiation for 10 min at variable power outputs to achieve different compact temperatures. For compacts containing CCX in both PVP12 and PVP17, a linear correlation was established between the measured compact end temperature and the rate of drug amorphization during 10 min of exposure to microwave radiation. For compacts containing CCX in PVP12, a fully amorphous ASD was obtained after 10 min of exposure to microwave radiation with a measured compact end temperature of 71 °C. For compacts containing CCX in PVP17, it was not possible to obtain a fully amorphous ASD. The reason for this is most likely that a fast evaporation of the sorbed water increased the Tg of the conditioned drug–polymer compacts to temperatures above the highest reachable compact temperature during exposure to microwave radiation in the utilized experimental setup. Supporting this conclusion, evaporation of the sorbed water was observed to be faster for compacts containing PVP17 compared to compacts containing PVP12.

Published

2021

23. The Effect of the Molecular Weight of Polyvinylpyrrolidone and the Model Drug on Laser-Induced In Situ Amorphization

Author

Anders Kragh Hansen, Ragna Berthelsen, Matthias Manne Knopp, Nele Johanna Hempel, Georgios A. Sotiriou, Alexandra Teleki, Korbinian Löbmann, and Padryk Merkl

Subjects

Naproxen, Materials science, Infrared Rays, Pharmaceutical Science, 02 engineering and technology, 030226 pharmacology & pharmacy, Article, Dosage form, Analytical Chemistry, Pharmaceutical Sciences, 03 medical and health sciences, QD241-441, 0302 clinical medicine, amorphous solid dispersion, Drug Stability, Drug Discovery, medicine, Physical and Theoretical Chemistry, Solubility, Dissolution, chemistry.chemical_classification, Polyvinylpyrrolidone, Viscosity, in situ amorphization, Lasers, Organic Chemistry, Anti-Inflammatory Agents, Non-Steroidal, near-IR laser radiation, Povidone, Polymer, Farmaceutiska vetenskaper, 021001 nanoscience & nanotechnology, plasmonic photothermal nanoparticles, chemistry, Chemistry (miscellaneous), Celecoxib, Molecular Medicine, Nanoparticles, Particle size, 0210 nano-technology, Glass transition, dissolution kinetics, medicine.drug, Nuclear chemistry

Abstract

Laser radiation has been shown to be a promising approach for in situ amorphization, i.e., drug amorphization inside the final dosage form. Upon exposure to laser radiation, elevated temperatures in the compacts are obtained. At temperatures above the glass transition temperature (Tg) of the polymer, the drug dissolves into the mobile polymer. Hence, the dissolution kinetics are dependent on the viscosity of the polymer, indirectly determined by the molecular weight (Mw) of the polymer, the solubility of the drug in the polymer, the particle size of the drug and the molecular size of the drug. Using compacts containing 30 wt% of the drug celecoxib (CCX), 69.25 wt% of three different Mw of polyvinylpyrrolidone (PVP: PVP12, PVP17 or PVP25), 0.25 wt% plasmonic nanoaggregates (PNs) and 0.5 wt% lubricant, the effect of the polymer Mw on the dissolution kinetics upon exposure to laser radiation was investigated. Furthermore, the effect of the model drug on the dissolution kinetics was investigated using compacts containing 30 wt% of three different drugs (CCX, indomethacin (IND) and naproxen (NAP)), 69.25 wt% PVP12, 0.25 wt% PN and 0.5 wt% lubricant. In perfect correlation to the Noyes–Whitney equation, this study showed that the use of PVP with the lowest viscosity, i.e., the lowest Mw (here PVP12), led to the fastest rate of amorphization compared to PVP17 and PVP25. Furthermore, NAP showed the fastest rate of amorphization, followed by IND and CCX in PVP12 due to its high solubility and small molecular size.

Published

2021

24. The effects of surfactants on the performance of polymer-based microwave-induced in situ amorphization.

Author

Qiang W, Löbmann K, McCoy CP, Andrews GP, and Zhao M

Subjects

Microwaves, Solubility, Polysorbates, Plasticizers, Surface-Active Agents, Polymers

Abstract

Microwave-induced in situ amorphization is a novel technology for preparing amorphous solid dispersions (ASDs) to address the challenges of their long-term physical stability and downstream processing. To date, only few types of dielectric materials have been reported for microwave-induced in situ amorphization, which restricted the extensive research of this technology. This study aimed to investigate the feasibility and mechanisms of utilizing the non-ionic surfactants, i.e. Kollisolv P124, Kolliphor RH40, D-ɑ-tocopheryl polyethylene glycol succinate (TPGS), Tween (T) 60 (T60), T65, T80 and T85, as plasticizers to facilitate microwave-induced in situ amorphization. It was found that the successful application of surfactants could be related with their low T m , low M w and high HLB. Kolliphor RH40 was selected as a typical surfactant due to its excellent dielectric heating ability, plasticizing effect and solubilizing effect when facilitating amorphization. Then, the dissolution-mediated in situ amorphization mechanism was investigated and intuitively demonstrated. For the most promising formulation, i.e. microwaved systems with Korlliphor RH40 at 1.5 (w/w) plasticizer/polymer ratio, a complete and fast in vitro dissolution was observed relative to the untreated systems. In conclusion, non-ionic surfactants had the potential to facilitate microwave-induced in situ amorphization, which provided a new direction in the formulation designation for microwave-able systems., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022. Published by Elsevier B.V.)

Published

2023

25. Solid-state properties and dissolution behaviour of tablets containing co-amorphous indomethacin–arginine.

Author

Lenz, Elisabeth, Jensen, Katrine Tarp, Blaabjerg, Lasse Ingerslev, Knop, Klaus, Grohganz, Holger, Löbmann, Korbinian, Rades, Thomas, and Kleinebudde, Peter

Subjects

*DRUG solubility, *DRUG tablets, *INDOMETHACIN, *ARGININE, *SOLID state chemistry, *EXCIPIENTS

Abstract

Co-amorphous drug formulations provide the possibility to stabilize a drug in its amorphous form by interactions with low molecular weight compounds, e.g. amino acids. Recent studies have shown the feasibility of spray drying as a technique to manufacture co-amorphous indomethacin–arginine in a larger production scale. In this work, a tablet formulation was developed for a co-amorphous salt, namely spray dried indomethacin–arginine (SD IND–ARG). The effects of compaction pressure on tablet properties, physical stability and dissolution profiles under non-sink conditions were examined. Dissolution profiles of tablets with SD IND–ARG (TAB SD IND–ARG) were compared to those of tablets containing a physical mixture of crystalline IND and ARG (TAB PM IND–ARG) and to the dissolution of pure spray dried powder. Concerning tableting, the developed formulation allowed for the preparation of tablets with a broad range of compaction pressures resulting in different porosities and tensile strengths. XRPD results showed that, overall, no crystallization occurred neither during tableting nor during long-term storage. Dissolution profiles of TAB SD IND–ARG showed an immediate release of IND by erosion. The solubility of crystalline IND was exceeded by a factor of about 4, which was accompanied by a slow crystallization. For TAB PM IND–ARG, an in situ amorphization of IND in the presence of ARG was observed. As a result, a supersaturation was obtained, too, followed by a faster crystallization compared to TAB SD IND–ARG. In conclusion, the AUC 24h of TAB SD IND–ARG was twofold higher than the AUC 24h of TAB PM IND–ARG. Interestingly, different plateaus were obtained for TAB SD IND–ARG, TAB PM IND–ARG and pure SD IND–ARG after 24 h dissolution, which could be explained by the formation of different polymorphic forms of indomethacin. [ABSTRACT FROM AUTHOR]

Published

2015

26. Microwave-Induced In Situ Amorphization:A New Strategy for Tackling the Stability Issue of Amorphous Solid Dispersions

Author

Qiang, Wei, Lobmann, Korbinian, McCoy, Colin P., Andrews, Gavin P., Zhao, Min, Qiang, Wei, Lobmann, Korbinian, McCoy, Colin P., Andrews, Gavin P., and Zhao, Min

Abstract

The thermodynamically unstable nature of amorphous drugs has led to a persistent stability issue of amorphous solid dispersions (ASDs). Lately, microwave-induced in situ amorphization has been proposed as a promising solution to this problem, where the originally loaded crystalline drug is in situ amorphized within the final dosage form using a household microwave oven prior to oral administration. In addition to circumventing issues with physical stability, it can also simplify the problematic downstream processing of ASDs. In this review paper, we address the significance of exploring and developing this novel technology with an emphasis on systemically reviewing the currently available literature in this pharmaceutical arena and highlighting the underlying mechanisms involved in inducing in situ amorphization. Specifically, in order to achieve a high drug amorphicity, formulations should be composed of drugs with high solubility in polymers, as well as polymers with high hygroscopicity and good post-plasticized flexibility of chains. Furthermore, high microwave energy input is considered to be a desirable factor. Lastly, this review discusses challenges in the development of this technology including chemical stability, selection criteria for excipients and the dissolution performance of the microwave-induced ASDs.

Published

2020

27. The influence of drug and polymer particle size on the in situ amorphization using microwave irradiation

Author

Hempel, Nele Johanna, Knopp, Matthias M., Berthelsen, Ragna, Zeitler, J. Axel, Löbmann, Korbinian, Hempel, Nele Johanna, Knopp, Matthias M., Berthelsen, Ragna, Zeitler, J. Axel, and Löbmann, Korbinian

Abstract

In this study, the impact of drug and polymer particle size on the in situ amorphization using microwave irradiation at a frequency of 2.45 GHz were investigated. Using ball milling and sieve fractioning, the crystalline drug celecoxib (CCX) and the polymer polyvinylpyrrolidone (PVP) were divided into two particle size fractions, i.e. small (<71 µm) and large (>71 µm) particles. Subsequently, compacts containing a drug load of 30% (w/w) crystalline CCX in PVP were prepared and subjected to microwave radiation for an accumulated duration of 600 sec in intervals of 60 sec as well as continuously for 600 sec. It was found that the compacts containing small CCX particles displayed faster rates of amorphization and a higher degree of amorphization during microwave irradiation as compared to the compacts containing large CCX particles. For compacts with small CCX particles, interval exposure to microwave radiation resulted in a maximum degree of amorphization of 24%, whilst a fully amorphous solid dispersion (100%) was achieved after 600 sec of continuous exposure to microwave radiation. By monitoring the temperature in the core of the compacts during exposure to microwave radiation using a fiber optic temperature probe, it was found that the total exposure time above the glass transition temperature (Tg) was shorter for the interval exposure method compared to continuous exposure to microwave radiation. Therefore, it is proposed that the in situ formation of an amorphous solid dispersion is governed by the dissolution of drug into the polymer, which most likely is accelerated above the Tg of the compacts. Hence, prolonging the exposure time above the Tg, and increasing the surface area of the drug by particle size reduction will increase the dissolution rate and thus, rate and degree of amorphization of CCX during exposure to microwave radiation.

Published

2020

28. Microwave-Induced in Situ Drug Amorphization Using a Mixture of Polyethylene Glycol and Polyvinylpyrrolidone

Author

Nele-Johanna Hempel, Matthias Manne Knopp, Korbinian Löbmann, Ragna Berthelsen, and J. Axel Zeitler

Subjects

Materials science, Polyethylene glycol, Transmission Raman spectroscopy, Pharmaceutical Science, Excipient, 02 engineering and technology, Ternary phase diagram, Drug loading, 030226 pharmacology & pharmacy, Polyethylene Glycols, Excipients, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, PEG ratio, medicine, Amorphous solid dispersion, Microwaves, Microwave irradiation, In situ amorphization, Polyvinylpyrrolidone, Povidone, 021001 nanoscience & nanotechnology, Amorphous solid, chemistry, Chemical engineering, Solubility, Celecoxib, Polymer blend, Absorption (chemistry), 0210 nano-technology, Dispersion (chemistry), medicine.drug

Abstract

The use of a mixture of polyethylene glycol (PEG) and polyvinylpyrrolidone (PVP) was investigated for microwave-induced in situ amorphization of celecoxib (CCX) inside compacts. Such amorphization requires the presence of a dipolar excipient in the formulation to ensure heating of the compact by absorption of the microwaves. Previously, the hygroscopic nature of PVP was exploited for this purpose. By exposing PVP-based compacts for set time intervals at defined relative humidity, controlled water sorption into the compacts was achieved. In the present study, PEG was proposed as the microwave absorbing excipient instead of water, to avoid the water sorption step. However, it was found that PEG alone melted upon exposure to microwave radiation and caused the compact to deform. Furthermore, CCX was found to recrystallize upon cooling in PEG-based formulations. Hence, a mixture of PEG and PVP was used, where the presence of PVP preserved the physical shape of the compact, and the physical state of the amorphous solid dispersion. To study the impact of the polymer mixture, different compact compositions of CCX, PEG and PVP were prepared. When exposing the compacts to microwave radiation, it was found that the PEG:PVP ratio was critical for in situ amorphization and that complete amorphization was only achieved above a certain temperature threshold.

Published

2021

29. The Influence of Temperature and Viscosity of Polyethylene Glycol on the Rate of Microwave-Induced In Situ Amorphization of Celecoxib

Author

Matthias Manne Knopp, Tra Dao, Ragna Berthelsen, Nele-Johanna Hempel, and Korbinian Löbmann

Subjects

Diffusion, PVP, Pharmaceutical Science, dissolution, 02 engineering and technology, 030226 pharmacology & pharmacy, Analytical Chemistry, Polyethylene Glycols, Viscosity, chemistry.chemical_compound, 0302 clinical medicine, amorphous solid dispersion, Drug Discovery, Transition Temperature, Magnesium stearate, DRUG, Microwaves, Dissolution, chemistry.chemical_classification, RELEVANT, Communication, Anti-Inflammatory Agents, Non-Steroidal, Polymer, 021001 nanoscience & nanotechnology, MOLECULAR-WEIGHT, Chemistry (miscellaneous), polyethylene glycol, Molecular Medicine, DIELECTRIC-PROPERTIES, 0210 nano-technology, Glass transition, Crystallization, Materials science, RELAXATION, Polyethylene glycol, lcsh:QD241-441, Excipients, 03 medical and health sciences, lcsh:Organic chemistry, PEG ratio, Physical and Theoretical Chemistry, in situ amorphization, Organic Chemistry, technology, industry, and agriculture, temperature, Drug Liberation, microwave radiation, chemistry, Chemical engineering, Solubility, Celecoxib, viscosity, monotecticum

Abstract

Microwaved-induced in situ amorphization of a drug in a polymer has been suggested to follow a dissolution process, with the drug dissolving into the mobile polymer at temperatures above the glass transition temperature (Tg) of the polymer. Thus, based on the Noyes–Whitney and the Stoke–Einstein equations, the temperature and the viscosity are expected to directly impact the rate and degree of drug amorphization. By investigating two different viscosity grades of polyethylene glycol (PEG), i.e., PEG 3000 and PEG 4000, and controlling the temperature of the microwave oven, it was possible to study the influence of both, temperature and viscosity, on the in situ amorphization of the model drug celecoxib (CCX) during exposure to microwave radiation. In this study, compacts containing 30 wt% CCX, 69 wt% PEG 3000 or PEG 4000 and 1 wt% lubricant (magnesium stearate) were exposed to microwave radiation at (i) a target temperature, or (ii) a target viscosity. It was found that at the target temperature, compacts containing PEG 3000 displayed a faster rate of amorphization as compared to compacts containing PEG 4000, due to the lower viscosity of PEG 3000 compared to PEG 4000. Furthermore, at the target viscosity, which was achieved by setting different temperatures for compacts containing PEG 3000 and PEG 4000, respectively, the compacts containing PEG 3000 displayed a slower rate of amorphization, due to a lower target temperature, than compacts containing PEG 4000. In conclusion, with lower viscosity of the polymer, at temperatures above its Tg, and with higher temperatures, both increasing the diffusion coefficient of the drug into the polymer, the rate of amorphization was increased allowing a faster in situ amorphization during exposure to microwave radiation. Hereby, the theory that the microwave-induced in situ amorphization process can be described as a dissolution process of the drug into the polymer, at temperatures above the Tg, is further strengthened.

Published

2020

30. Recent Technologies for Amorphization of Poorly Water-Soluble Drugs.

Author

Kim, Do-Hyun, Kim, Young-Woo, Tin, Yee-Yee, Soe, Mya-Thet-Paing, Ko, Byoung-Hyen, Park, Sun-Jae, and Lee, Jaeh-Wi

Subjects

*AMORPHIZATION, *AMORPHOUS substances, *GASTROINTESTINAL system, *ENERGY policy, *DRUG solubility, *SUPERSATURATION, *MESOPOROUS silica

Abstract

Amorphization technology has been the subject of continuous attention in the pharmaceutical industry, as a means to enhance the solubility of poorly water-soluble drugs. Being in a high energy state, amorphous formulations generally display significantly increased apparent solubility as compared to their crystalline counterparts, which may allow them to generate a supersaturated state in the gastrointestinal tract and in turn, improve the bioavailability. Conventionally, hydrophilic polymers have been used as carriers, in which the amorphous drugs were dispersed and stabilized to form polymeric amorphous solid dispersions. However, the technique had its limitations, some of which include the need for a large number of carriers, the tendency to recrystallize during storage, and the possibility of thermal decomposition of the drug during preparation. Therefore, emerging amorphization technologies have focused on the investigation of novel amorphous-stabilizing carriers and preparation methods that can improve the drug loading and the degree of amorphization. This review highlights the recent pharmaceutical approaches utilizing drug amorphization, such as co-amorphous systems, mesoporous particle-based techniques, and in situ amorphization. Recent updates on these technologies in the last five years are discussed with a focus on their characteristics and commercial potential. [ABSTRACT FROM AUTHOR]

Published

2021

31. Microwave-Induced In Situ Amorphization: A New Strategy for Tackling the Stability Issue of Amorphous Solid Dispersions

Author

Colin P. McCoy, Gavin Andrews, Wei Qiang, Korbinian Löbmann, and Min Zhao

Subjects

Materials science, PVP, lcsh:RS1-441, Pharmaceutical Science, Nanotechnology, Review, 02 engineering and technology, 030226 pharmacology & pharmacy, poorly soluble drugs, Dosage form, physical stability, lcsh:Pharmacy and materia medica, DELIVERY, 03 medical and health sciences, ENHANCEMENT, 0302 clinical medicine, TECHNOLOGY, Solubility, FORMULATION, microwave irradiation, Dissolution, DISSOLUTION RATE, Microwave irradiation, chemistry.chemical_classification, Flexibility (engineering), In situ amorphization, CHALLENGES, Physical stability, in situ amorphization, DRUG-POLYMER SOLUBILITY, Polymer, 021001 nanoscience & nanotechnology, Amorphous solid, chemistry, Poorly soluble drugs, Chemical stability, amorphous solid dispersions, CRYSTALLIZATION, Amorphous solid dispersions, 0210 nano-technology, Microwave

Abstract

The thermodynamically unstable nature of amorphous drugs has led to a persistent stability issue of amorphous solid dispersions (ASDs). Lately, microwave-induced in situ amorphization has been proposed as a promising solution to this problem, where the originally loaded crystalline drug is in situ amorphized within the final dosage form using a household microwave oven prior to oral administration. In addition to circumventing issues with physical stability, it can also simplify the problematic downstream processing of ASDs. In this review paper, we address the significance of exploring and developing this novel technology with an emphasis on systemically reviewing the currently available literature in this pharmaceutical arena and highlighting the underlying mechanisms involved in inducing in situ amorphization. Specifically, in order to achieve a high drug amorphicity, formulations should be composed of drugs with high solubility in polymers, as well as polymers with high hygroscopicity and good post-plasticized flexibility of chains. Furthermore, high microwave energy input is considered to be a desirable factor. Lastly, this review discusses challenges in the development of this technology including chemical stability, selection criteria for excipients and the dissolution performance of the microwave-induced ASDs.

Published

2020

32. Studying the Impact of the Temperature and Sorbed Water during Microwave-Induced In Situ Amorphization: A Case Study of Celecoxib and Polyvinylpyrrolidone.

Author

Hempel, Nele-Johanna, Knopp, Matthias M., Löbmann, Korbinian, and Berthelsen, Ragna

Subjects

*WATER temperature, *DISSOLUTION (Chemistry), *AMORPHIZATION, *GLASS transition temperature, *CELECOXIB, *POVIDONE

Abstract

Microwave-induced in situ amorphization of a drug into a polymeric amorphous solid dispersion (ASD) has been suggested to follow a dissolution process of the drug into the polymeric network, at temperatures above the glass transition temperature (Tg) of the polymer. Thus, increasing the compact temperature, above the Tg of the polymer, is expected to increase the rate of drug dissolution in the mobile polymer, i.e., the rate of amorphization, in a direct proportional fashion. To test this hypothesis, the present study aimed at establishing a linear correlation between the compact temperature and the rate of drug amorphization using celecoxib (CCX) and the polymers polyvinylpyrrolidone (PVP) 12 and PVP17 as the model systems. Water sorbed into the drug–polymer compacts during 2 weeks of storage at 75% relative humidity was used as the dielectric heating source for the present drug amorphization process, and therefore directly affected the compact temperature during exposure to microwave radiation; the loss of water during heating was also studied. For this, compacts prepared with 30 wt% CCX, 69.5 wt% PVP12 or PVP17 and 0.5 wt% magnesium stearate (lubricant) were conditioned to have a final water content of approx. 20 wt%. The conditioned compacts were exposed to microwave radiation for 10 min at variable power outputs to achieve different compact temperatures. For compacts containing CCX in both PVP12 and PVP17, a linear correlation was established between the measured compact end temperature and the rate of drug amorphization during 10 min of exposure to microwave radiation. For compacts containing CCX in PVP12, a fully amorphous ASD was obtained after 10 min of exposure to microwave radiation with a measured compact end temperature of 71 °C. For compacts containing CCX in PVP17, it was not possible to obtain a fully amorphous ASD. The reason for this is most likely that a fast evaporation of the sorbed water increased the Tg of the conditioned drug–polymer compacts to temperatures above the highest reachable compact temperature during exposure to microwave radiation in the utilized experimental setup. Supporting this conclusion, evaporation of the sorbed water was observed to be faster for compacts containing PVP17 compared to compacts containing PVP12. [ABSTRACT FROM AUTHOR]

Published

2021

33. The Effect of the Molecular Weight of Polyvinylpyrrolidone and the Model Drug on Laser-Induced In Situ Amorphization.

Author

Hempel NJ, Merkl P, Knopp MM, Berthelsen R, Teleki A, Hansen AK, Sotiriou GA, and Löbmann K

Subjects

Anti-Inflammatory Agents, Non-Steroidal administration & dosage, Celecoxib administration & dosage, Drug Stability, Lasers, Viscosity, Anti-Inflammatory Agents, Non-Steroidal chemistry, Celecoxib chemistry, Infrared Rays, Nanoparticles chemistry, Povidone chemistry

Abstract

Laser radiation has been shown to be a promising approach for in situ amorphization, i.e., drug amorphization inside the final dosage form. Upon exposure to laser radiation, elevated temperatures in the compacts are obtained. At temperatures above the glass transition temperature ( T g ) of the polymer, the drug dissolves into the mobile polymer. Hence, the dissolution kinetics are dependent on the viscosity of the polymer, indirectly determined by the molecular weight ( M w ) of the polymer, the solubility of the drug in the polymer, the particle size of the drug and the molecular size of the drug. Using compacts containing 30 wt% of the drug celecoxib (CCX), 69.25 wt% of three different M w of polyvinylpyrrolidone (PVP: PVP12, PVP17 or PVP25), 0.25 wt% plasmonic nanoaggregates (PNs) and 0.5 wt% lubricant, the effect of the polymer M w on the dissolution kinetics upon exposure to laser radiation was investigated. Furthermore, the effect of the model drug on the dissolution kinetics was investigated using compacts containing 30 wt% of three different drugs (CCX, indomethacin (IND) and naproxen (NAP)), 69.25 wt% PVP12, 0.25 wt% PN and 0.5 wt% lubricant. In perfect correlation to the Noyes-Whitney equation, this study showed that the use of PVP with the lowest viscosity, i.e., the lowest M w (here PVP12), led to the fastest rate of amorphization compared to PVP17 and PVP25. Furthermore, NAP showed the fastest rate of amorphization, followed by IND and CCX in PVP12 due to its high solubility and small molecular size.

Published

2021

34. Microwave-Induced In Situ Amorphization: A New Strategy for Tackling the Stability Issue of Amorphous Solid Dispersions.

Author

Qiang, Wei, Löbmann, Korbinian, McCoy, Colin P., Andrews, Gavin P., and Zhao, Min

Subjects

*AMORPHOUS substances, *AMORPHIZATION, *DRUG solubility, *DISPERSION (Chemistry), *MICROWAVE ovens, *CHEMICAL stability

Abstract

The thermodynamically unstable nature of amorphous drugs has led to a persistent stability issue of amorphous solid dispersions (ASDs). Lately, microwave-induced in situ amorphization has been proposed as a promising solution to this problem, where the originally loaded crystalline drug is in situ amorphized within the final dosage form using a household microwave oven prior to oral administration. In addition to circumventing issues with physical stability, it can also simplify the problematic downstream processing of ASDs. In this review paper, we address the significance of exploring and developing this novel technology with an emphasis on systemically reviewing the currently available literature in this pharmaceutical arena and highlighting the underlying mechanisms involved in inducing in situ amorphization. Specifically, in order to achieve a high drug amorphicity, formulations should be composed of drugs with high solubility in polymers, as well as polymers with high hygroscopicity and good post-plasticized flexibility of chains. Furthermore, high microwave energy input is considered to be a desirable factor. Lastly, this review discusses challenges in the development of this technology including chemical stability, selection criteria for excipients and the dissolution performance of the microwave-induced ASDs. [ABSTRACT FROM AUTHOR]

Published

2020

35. Convection-Induced vs. Microwave Radiation-Induced in situ Drug Amorphization.

Author

Hempel, Nele-Johanna, Knopp, Matthias M., Berthelsen, Ragna, Löbmann, Korbinian, and Angelov, Borislav

Subjects

*AMORPHIZATION, *AMORPHOUS substances, *MICROWAVE ovens, *MICROWAVES, *HEAT convection, *HUMIDITY

Abstract

The aim of the study was to investigate the suitability of a convection oven to induce in situ amorphization. The study was conducted using microwave radiation-induced in situ amorphization as reference, as it has recently been shown to enable the preparation of a fully (100%) amorphous solid dispersion of celecoxib (CCX) in polyvinylpyrrolidone (PVP) after 10 min of continuous microwaving. For comparison, the experimental setup of the microwave-induced method was mimicked for the convection-induced method. Compacts containing crystalline CCX and PVP were prepared and either pre-conditioned at 75% relative humidity or kept dry to investigate the effect of sorbed water on the amorphization kinetics. Subsequently, the compacts were heated for 5, 10, 15, 20, or 30 min in the convection oven at 100 °C. The degree of amorphization of CCX in the compacts was subsequently quantified using transmission Raman spectroscopy. Using the convection oven, the maximum degree of amorphization achieved was 96.1% ± 2.1% (n = 3) for the conditioned compacts after 30 min of heating and 14.3% ± 1.4% (n = 3) for the dry compacts after 20 min of heating, respectively. Based on the results from the convection and the microwave oven, it was found that the sorbed water acts as a plasticizer in the conditioned compacts (i.e., increasing molecular mobility), which is advantageous for in situ amorphization in both methods. Since the underlying mechanism of heating between the convection oven and microwave oven differs, it was found that convection-induced in situ amorphization is inferior to microwave radiation-induced in situ amorphization in terms of amorphization kinetics with the present experimental setup. [ABSTRACT FROM AUTHOR]

Published

2020

36. The Influence of Temperature and Viscosity of Polyethylene Glycol on the Rate of Microwave-Induced In Situ Amorphization of Celecoxib.

Author

Hempel NJ, Dao T, Knopp MM, Berthelsen R, and Löbmann K

Subjects

Crystallization, Drug Liberation, Microwaves, Solubility, Transition Temperature, Viscosity, Anti-Inflammatory Agents, Non-Steroidal chemistry, Celecoxib chemistry, Excipients chemistry, Polyethylene Glycols chemistry

Abstract

Microwaved-induced in situ amorphization of a drug in a polymer has been suggested to follow a dissolution process, with the drug dissolving into the mobile polymer at temperatures above the glass transition temperature ( T ) of the polymer. Thus, based on the Noyes-Whitney and the Stoke-Einstein equations, the temperature and the viscosity are expected to directly impact the rate and degree of drug amorphization. By investigating two different viscosity grades of polyethylene glycol (PEG), i.e., PEG 3000 and PEG 4000, and controlling the temperature of the microwave oven, it was possible to study the influence of both, temperature and viscosity, on the in situ amorphization of the model drug celecoxib (CCX) during exposure to microwave radiation. In this study, compacts containing 30 wt% CCX, 69 wt% PEG 3000 or PEG 4000 and 1 wt% lubricant (magnesium stearate) were exposed to microwave radiation at ( g ) of the polymer. Thus, based on the Noyes-Whitney and the Stoke-Einstein equations, the temperature and the viscosity are expected to directly impact the rate and degree of drug amorphization. By investigating two different viscosity grades of polyethylene glycol (PEG), i.e., PEG 3000 and PEG 4000, and controlling the temperature of the microwave oven, it was possible to study the influence of both, temperature and viscosity, on the in situ amorphization of the model drug celecoxib (CCX) during exposure to microwave radiation. In this study, compacts containing 30 wt% CCX, 69 wt% PEG 3000 or PEG 4000 and 1 wt% lubricant (magnesium stearate) were exposed to microwave radiation at ( i ) a target temperature, or ( ii , and with higher temperatures, both increasing the diffusion coefficient of the drug into the polymer, the rate of amorphization was increased allowing a faster in situ amorphization during exposure to microwave radiation. Hereby, the theory that the microwave-induced in situ amorphization process can be described as a dissolution process of the drug into the polymer, at temperatures above the T g , and with higher temperatures, both increasing the diffusion coefficient of the drug into the polymer, the rate of amorphization was increased allowing a faster in situ amorphization during exposure to microwave radiation. Hereby, the theory that the microwave-induced in situ amorphization process can be described as a dissolution process of the drug into the polymer, at temperatures above the T g , is further strengthened.

Published

2020