Holger Grohganz scite author profile

One of the challenges in drug development today is that many new drug candidates are poorly water-soluble, and one of the approaches to overcome this problem is to transfer a crystalline drug into its amorphous form, thus increasing dissolution rate and apparent solubility of the compound. In this study, a coamorphous drug/drug combination between the two nonsteroidal anti-inflammatory drugs, naproxen and γ-indomethacin, was prepared and investigated. At molar ratios of 2:1, 1:1 and 1:2, the drugs were quench cooled in order to obtain a coamorphous binary phase. Physical stability was examined at 277.15 and 298.15 K under dry conditions (phosphorus pentoxide) and analyzed with X-ray powder diffraction (XRPD). Intrinsic dissolution testing was carried out to identify dissolution advantages of the coamorphous form over its crystalline counterparts or amorphous indomethacin. Fourier transform infrared spectroscopy (FTIR) was used for analyses at the molecular level to detect potential molecular interactions. Differential scanning calorimetry (DSC) thermograms were employed to assess the glass transition temperatures (T(g)), and the results were compared with predicted T(g)s from the Gordon-Taylor equation. Results showed that naproxen could be made amorphous in combination with indomethacin while this was not possible with naproxen alone. Peak shifts in the FTIR spectra indicated molecular interactions between both drugs, and it is suggested that the two drugs formed a heterodimer. Therefore, samples at the 1:2 and 2:1 ratios showed recrystallization of the excess drug upon storage whereas the 1:1 ratio samples remained amorphous. Intrinsic dissolution testing showed increased dissolution rate of both drugs in the coamorphous form as well as a synchronized release for the 1:1 coamorphous blend. All T(g)s displayed negative deviations from the Gordon-Taylor equation with the 1:1 ratio showing the largest deviation. In a novel approach of predicting the glass transition temperature, the 1:1 drug ratio was inserted as an individual component in the Gordon-Taylor equation with the excess drug representing the second compound. This approach resulted in a good fit to the experimentally determined T(g)s.

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Amino acids as co-amorphous stabilizers for poorly water soluble drugs – Part 1: Preparation, stability and dissolution enhancement

Löbmann

Grohganz

Laitinen

et al. 2013

European Journal of Pharmaceutics and Biopharmaceutics

253

216

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Co-amorphous simvastatin and glipizide combinations show improved physical stability without evidence of intermolecular interactions

Löbmann

Strachan

Grohganz

et al. 2012

European Journal of Pharmaceutics and Biopharmaceutics

201

137

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Glass-Transition Temperature of the β-Relaxation as the Major Predictive Parameter for Recrystallization of Neat Amorphous Drugs

et al. 2018

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Recrystallization of amorphous drugs is currently limiting the simple approach to improve solubility and bioavailability of poorly water-soluble drugs by amorphization of a crystalline form of the drug. In view of this, molecular mobility, α-relaxation and β-relaxation processes with the associated transition temperatures T and T, was investigated using dynamic mechanical analysis (DMA). The correlation between the transition temperatures and the onset of recrystallization for nine amorphous drugs, stored under dry conditions at a temperature of 296 K, was determined. From the results obtained, T does not correlate with the onset of recrystallization under the experimental storage conditions. However, a clear correlation between T and the onset of recrystallization was observed. It is shown that at storage temperature below T, amorphous nifedipine retains its amorphous form. On the basis of the correlation, an empirical correlation is proposed for predicting the onset of recrystallization for drugs stored at 0% RH and 296 K.

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Recent trends in stabilising peptides and proteins in pharmaceutical formulation – considerations in the choice of excipients

Jørgensen

Hostrup

Moeller

et al. 2009

Expert Opinion on Drug Delivery

111

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In the area of peptide and protein pharmaceuticals, both the physical and chemical stability of biopharmaceuticals are critical and need to be optimised when formulating a drug product, in order to optimise the outcome after processing and storage. This review focuses on the effects on the stability from various types of excipient and the choices that have to be made during formulation of drug products containing peptides or proteins. It is illustrated, through examples, how the choice of one excipient over another can affect the stability of a protein drug formulation, along with other problems linked to this choice. The excipients used in pharmaceutical preparations are limited and from an academic point of view there is a clear requirement for new excipients.

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Amino Acids as Co-amorphous Excipients for Simvastatin and Glibenclamide: Physical Properties and Stability

et al. 2014

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Co-amorphous drug mixtures with low-molecular-weight excipients have recently been shown to be a promising approach for stabilization of amorphous drugs and thus to be an alternative to the traditional amorphous solid dispersion approach using polymers. However, the previous studies are limited to a few drugs and amino acids. To facilitate the rational selection of amino acids, the practical importance of the amino acid coming from the biological target site of the drug (and associated intermolecular interactions) needs to be established. In the present study, the formation of co-amorphous systems using cryomilling and combinations of two poorly water-soluble drugs (simvastatin and glibenclamide) with the amino acids aspartic acid, lysine, serine, and threonine was investigated. Solid-state characterization with X-ray powder diffraction, differential scanning calorimetry, and Fourier-transform infrared spectroscopy revealed that the 1:1 molar combinations simvastatin-lysine, glibenclamide-serine, and glibenclamide-threonine and the 1:1:1 molar combination glibenclamide-serine-threonine formed co-amorphous mixtures. These were homogeneous single-phase blends with weak intermolecular interactions in the mixtures. Interestingly, a favorable effect by the excipients on the tautomerism of amorphous glibenclamide in the co-amorphous blends was seen, as the formation of the thermodynamically less stable imidic acid tautomer of glibenclamide was suppressed compared to that of the pure amorphous drug. Furthermore, the co-amorphous mixtures provided a physical stability advantage over the amorphous drugs alone.

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A theoretical and spectroscopic study of co-amorphous naproxen and indomethacin

Löbmann¹,

Laitinen²,

Grohganz³

et al. 2013

International Journal of Pharmaceutics

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Holger Grohganz

Recent advances in co-amorphous drug formulations

Coamorphous Drug Systems: Enhanced Physical Stability and Dissolution Rate of Indomethacin and Naproxen

Amino acids as co-amorphous stabilizers for poorly water soluble drugs – Part 1: Preparation, stability and dissolution enhancement

Co-amorphous simvastatin and glipizide combinations show improved physical stability without evidence of intermolecular interactions

Glass-Transition Temperature of the β-Relaxation as the Major Predictive Parameter for Recrystallization of Neat Amorphous Drugs

Recent trends in stabilising peptides and proteins in pharmaceutical formulation – considerations in the choice of excipients

Amino Acids as Co-amorphous Excipients for Simvastatin and Glibenclamide: Physical Properties and Stability

A theoretical and spectroscopic study of co-amorphous naproxen and indomethacin

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