# Prediction of solid-to-solid phase transition for risk assessment of solid forms using quantum mechanical solid-state computations

**Authors:** Satish Iyemperumal, Charlene Tsay, Monika Warzecha, Ales Medek, Kevin Gagnon, Jiahui Chen

PMC · DOI: 10.1063/4.0000920 · 2025-10-27

## TL;DR

This paper uses quantum mechanical computations to predict solid-to-solid phase transitions in pharmaceutical compounds, helping assess risks and improve API form selection.

## Contribution

The study introduces integrated computational workflows combining CSP and DFT to predict and validate solid form stability and desolvation trends.

## Key findings

- Crystal structure prediction revealed additional polymorphs with similar stability to the lead form.
- DFT-based predictions of desolvation energies helped identify solvent systems with easier desolvation.
- Experimental validation confirmed computational predictions for two different forms.

## Abstract

Solid form discovery and characterization are critical in pharmaceutical development, as they influence API form selection which can directly impact stability, bioavailability, and manufacturability. In this study, we utilize orthogonal tools to evaluate (i) the risk profile of the stability of a lead crystalline form of an API and (ii) to help prioritize isostructural solvate families that are easier to desolvate to make the desired neat form, since the API is a prolific solvate former. Solid-state computations are leveraged here to improve our understanding of the solid-to-solid phase transition likelihood and impact on their stabilities. For both these assessments, we demonstrate how we integrated computational materials science tools, crystal structures (predicted and experimental), and experimental solid form characterization methods to better understand our material through structure-property relationships.

Firstly, using crystal structure prediction (CSP), we found that there were additional predicted polymorphs similar in stability to our lead form. Density functional theory (DFT)-based predictions showed that the new forms could be made at higher pressures, which was experimentally confirmed. Secondly, since the primary mechanism of making the neat desired form involved desolvation, we wanted to understand if methods such as DFT-based desolvation energies from the crystal structures can help predict general trends of certain solvent systems having an easier/faster desolvation than other solvent systems. We were able to validate the predictions for two different forms.

Overall, given the utility of predictive computational materials science tools, we built workflows to streamline future requests where we can more systematically validate and improve error metrics over a longer period of validation.

---
Source: https://tomesphere.com/paper/PMC12585384