Sreenivas R. Lingireddy scite author profile

Cocrystals have become an established and adopted approach for creating crystalline solids with improved physical properties, but incorporating cocrystals into enabling pre-clinical formulations suitable for animal dosing has received limited attention. The dominant approach to in vivo evaluation of cocrystals has focused on deliberately excluding additional formulation in favor of "neat" aqueous suspensions of cocrystals or loading neat cocrystal material into capsules. However, this study demonstrates that, in order to take advantage of the improved solubility of a 1:1 danazol:vanillin cocrystal, a suitable formulation was required. The neat aqueous suspension of the danazol:vanillin cocrystal had a modest in vivo improvement of 1.7 times higher area under the curve compared to the poorly soluble crystal form of danazol dosed under identical conditions, but the formulated aqueous suspension containing 1% vitamin E-TPGS (TPGS) and 2% Klucel LF Pharm hydroxypropylcellulose improved the bioavailability of the cocrystal by over 10 times compared to the poorly soluble danazol polymorph. In vitro powder dissolution data obtained under non-sink biorelevant conditions correlate with in vivo data in rats following 20 mg/kg doses of danazol. In the case of the danazol:vanillin cocrystal, using a combination of cocrystal, solubilizer, and precipitation inhibitor in a designed supersaturating drug delivery system resulted in a dramatic improvement in the bioavailability. When suspensions of neat cocrystal material fail to return the anticipated bioavailability increase, a supersaturating formulation may be able to create the conditions required for the increased cocrystal solubility to be translated into improved in vivo absorption at levels competitive with existing formulation approaches used to overcome solubility limited bioavailability.

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A molecular picture of the problems in ensuring structural purity of tazofelone

Price

McMahon

Lingireddy

et al. 2014

Journal of Molecular Structure

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Unraveling Complexity in the Solid Form Screening of a Pharmaceutical Salt: Why so Many Forms? Why so Few?

Braun

Lingireddy

Beidelschies³

et al. 2017

Crystal Growth & Design

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The solid form landscape of 5-HT2a antagonist 3-(4-(benzo[d]isoxazole-3-yl)piperazin-1-yl)-2,2-dimethylpropanoic acid hydrochloride (B5HCl) proved difficult to establish. Many crystalline materials were produced by solid form screening, but few forms readily grew high quality crystals to afford a clear picture or understanding of the solid form landscape. Careful control of crystallization conditions, a range of experimental methods, computational modeling of solvate structures, and crystal structure prediction were required to see potential arrangements of the salt in its crystal forms. Structural diversity in the solid form landscape of B5HCl was apparent in the layer structures for the anhydrate polymorphs (Forms I and II), dihydrate and a family of solvates with alcohols. The alcohol solvates, which provided a distinct packing from the neat forms and the dihydrate, form layers with conserved hydrogen bonding between B5HCl and the solvent, as well as stacking of the aromatic rings. The ability of the alcohol hydrocarbon moieties to efficiently pack between the layers accounted for the difficulty in growing some solvate crystals and the inability of other solvates to crystallize altogether. Through a combination of experiment and computation, the crystallization problems, form stability, and desolvation pathways of B5HCl have been rationalized at a molecular level.

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