Mary S. Kleppe scite author profile

Solution-mediated phase transformation (SMPT) can reduce the high drug concentration expected from amorphous formulations, eliminating the improvement in drug absorption one hoped to gain from this high energy drug state. The differences in SMPT of a supersaturating system were compared in biorelevant media (fasted state simulated intestinal fluid and fed state simulated intestinal fluid) and United States Pharmacopeia compendial medium, simulated intestinal fluid without pancreatin. Amorphous spironolactone underwent SMPT to the same hydrate of spironolactone in all 3 media which was confirmed by the decrease in dissolution rates assessed in a flow-through dissolution apparatus, as well as by the appearance of crystals on the amorphous solid surface detected by polarized light microscopy. Longer duration of supersaturation which may lead to greater in vivo oral drug absorption was found in both biorelevant media, compared to compendial (average > 90 vs. 20 min), indicating that the presence of surfactants in biorelevant media delays crystal growth. Surface profiles and polarized light micrographs suggest that (1) a significant increase in surface area due to 3D crystal formation, (2) amorphous areas remaining exposed on the surface, and (3) a lower nucleation rate are potential reasons for an elevated dissolution rate even after SMPT.

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Mathematical Models to Explore Potential Effects of Supersaturation and Precipitation on Oral Bioavailability of Poorly Soluble Drugs

Kleppe

Forney-Stevens

Haskell

et al. 2015

AAPS J

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Abstract. Poorly soluble drugs are increasingly formulated into supersaturating drug delivery systems which may precipitate during oral delivery. The link between in vitro drug concentration profiles and oral bioavailability is under intense investigation. The objective of the present work was to develop closedform analytical solutions that relate in vitro concentration profiles to the amount of drug absorbed using several alternate assumptions and only six parameters. Three parameters define the key features of the in vitro drug concentration-time profile. An additional three parameters focus on physiological parameters. Absorption models were developed based on alternate assumptions; the drug concentration in the intestinal fluid: (1) peaks at the same time and concentration as in vitro, (2) peaks at the same time as in vitro, or (3) reaches the same peak concentration as in vitro. The three assumptions provide very different calculated values of bioavailability. Using Case 2 assumptions, bioavailability enhancement was found to be less than proportional to in silico examples of dissolution enhancement. Case 3 assumptions lead to bioavailability enhancements that are more than proportional to dissolution enhancements. Using Case 1 predicts drug absorption amounts that fall in between Case 2 and 3. The equations developed based on the alternate assumptions can be used to quickly evaluate the potential improvement in bioavailability due to intentional alteration of the in vitro drug concentration vs. time curve by reformulation. These equations may be useful in making decisions as to whether reformulation is expected to provide sufficient bioavailability enhancement to justify the effort.

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Nuances in the Calculation of Amorphous Solubility Enhancement Ratio

Manchanda

Kleppe

Bogner

2019

Journal of Pharmaceutical Sciences

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Mary S. Kleppe

Biorelevant Media Slows the Solution-Mediated Phase Transformation of Amorphous Spironolactone

Mathematical Models to Explore Potential Effects of Supersaturation and Precipitation on Oral Bioavailability of Poorly Soluble Drugs

Nuances in the Calculation of Amorphous Solubility Enhancement Ratio

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