The physico-chemical properties of spiramycin and clarithromycin / Rodé van Eeden

Van Eeden, Rodé

January 2012

In most cases, organic materials exist in the solid phase as polymorphs, solvatomorphs or amorphous forms. Physico-chemical properties in the solid-state are all affected primarily in terms of dissolution, solubility, bioavailability, stability and processability. Therefore investigation into the polymorphic behaviour of APIs has become a mandatory part of drug characterisation studies by pharmaceutical companies (Giron, 2001). The influence polymorphism has on bioavailability and the need for the development of drugs in the amorphous form have instigated regulatory bodies such as the FDA to require solid-state characterisation of pharmaceuticals (Strachan et al., 2005). Subsequently a study was conducted to determine the physico-chemical properties of two poorly watersoluble macrolides; clarithromycin and spiramycin. Characterisation methods included: XRPD, IR, TGA, DSC, SEM, Karl Fischer titration, solubility and stability studies. Recrystallisations of spiramycin from various solvents indicated that this API mainly exists in the amorphous form. The DSC proved to be of little value in the characterisation of this particular macromolecular antibiotic, since wide inter-sample variations were mostly obtained. TGA results showed higher solvent uptake than expected. This was ascribed to the amorphous, sponge-like character of this drug. For the sake of reproducibility and quality of the results, characterisation of spiramycin was more reliant on spectroscopic and crystallographic methods. Samples generated from 2- butanol, chloroform, ethyl acetate, 1.4-dioxane, methanol, n-propanol, iso-propanol and tetrahydrofuran showed characteristic peaks in the range of 2000-2400 cm-1 that were not present in the IR spectrum of the raw material. Conversely, the XRPD patterns were all identical, exhibiting a characteristic “halo” pattern with no detectable Bragg diffraction peaks. A solubility assessment showed no significant differences between the raw material and the recrystallisation products. In fact the raw material seemed to be the form with the highest solubility, albeit it only by a small margin. According to the literature, clarithromycin exists in five forms. Form 0 exists as a solvate, form I is a metastable form, form II is the stable form (Liu & Riley 1998; Deshpande et al., 2006), form III is a solvate of acetonitrile (Liu et al., 2003; Liang & Yao, 2008) and form IV is a hydrate (Avrutov et al., 2003). The stable form II is used in formulations currently on the market. A follow-up study was done relating to a study performed by De Jager (2005). The raw material (form II) was recrystallised from acetonitrile, chloroform and ethyl acetate. Two new crystal forms were prepared from chloroform and acetonitrile. With the necessary driving force, both of these crystals forms are able to convert to the thermodynamically stable form II. In addition, a solvate recrystallised from chloroform together with its corresponding desolvate, showed a 4 and 1.5 fold respective increase in solubility when compared to the raw material. The recrystallisations from ethyl acetate delivered crystals with an XRPD pattern similar to form II. This proved that clarithromycin can be recrystallised directly from this solvent without the need of an additional conversion step, as was the case in the study done by De Jager (2005). / MSc (Pharmaceutics), North-West University, Potchefstroom Campus, 2013

Polymorphism

Macrolides

Solvatomorphs

Amorphous

Solubility

Polimorfisme

Makroliede

Solvate

Amorfe

Oplosbaarheid

The physico-chemical properties of spiramycin and clarithromycin / Rodé van Eeden

Van Eeden, Rodé

January 2012

In most cases, organic materials exist in the solid phase as polymorphs, solvatomorphs or amorphous forms. Physico-chemical properties in the solid-state are all affected primarily in terms of dissolution, solubility, bioavailability, stability and processability. Therefore investigation into the polymorphic behaviour of APIs has become a mandatory part of drug characterisation studies by pharmaceutical companies (Giron, 2001). The influence polymorphism has on bioavailability and the need for the development of drugs in the amorphous form have instigated regulatory bodies such as the FDA to require solid-state characterisation of pharmaceuticals (Strachan et al., 2005). Subsequently a study was conducted to determine the physico-chemical properties of two poorly watersoluble macrolides; clarithromycin and spiramycin. Characterisation methods included: XRPD, IR, TGA, DSC, SEM, Karl Fischer titration, solubility and stability studies. Recrystallisations of spiramycin from various solvents indicated that this API mainly exists in the amorphous form. The DSC proved to be of little value in the characterisation of this particular macromolecular antibiotic, since wide inter-sample variations were mostly obtained. TGA results showed higher solvent uptake than expected. This was ascribed to the amorphous, sponge-like character of this drug. For the sake of reproducibility and quality of the results, characterisation of spiramycin was more reliant on spectroscopic and crystallographic methods. Samples generated from 2- butanol, chloroform, ethyl acetate, 1.4-dioxane, methanol, n-propanol, iso-propanol and tetrahydrofuran showed characteristic peaks in the range of 2000-2400 cm-1 that were not present in the IR spectrum of the raw material. Conversely, the XRPD patterns were all identical, exhibiting a characteristic “halo” pattern with no detectable Bragg diffraction peaks. A solubility assessment showed no significant differences between the raw material and the recrystallisation products. In fact the raw material seemed to be the form with the highest solubility, albeit it only by a small margin. According to the literature, clarithromycin exists in five forms. Form 0 exists as a solvate, form I is a metastable form, form II is the stable form (Liu & Riley 1998; Deshpande et al., 2006), form III is a solvate of acetonitrile (Liu et al., 2003; Liang & Yao, 2008) and form IV is a hydrate (Avrutov et al., 2003). The stable form II is used in formulations currently on the market. A follow-up study was done relating to a study performed by De Jager (2005). The raw material (form II) was recrystallised from acetonitrile, chloroform and ethyl acetate. Two new crystal forms were prepared from chloroform and acetonitrile. With the necessary driving force, both of these crystals forms are able to convert to the thermodynamically stable form II. In addition, a solvate recrystallised from chloroform together with its corresponding desolvate, showed a 4 and 1.5 fold respective increase in solubility when compared to the raw material. The recrystallisations from ethyl acetate delivered crystals with an XRPD pattern similar to form II. This proved that clarithromycin can be recrystallised directly from this solvent without the need of an additional conversion step, as was the case in the study done by De Jager (2005). / MSc (Pharmaceutics), North-West University, Potchefstroom Campus, 2013

Polymorphism

Macrolides

Solvatomorphs

Amorphous

Solubility

Polimorfisme

Makroliede

Solvate

Amorfe

Oplosbaarheid