Discovering the Solid-State Secrets of Lorlatinib by NMR Crystallography: To Hydrogen Bond or not to Hydrogen Bond.

Lorlatinib is an active pharmaceutical ingredient (API) used in the treatment of lung cancer. Here, an NMR crystallography analysis is presented whereby the single-crystal X-ray diffraction structure (CSD: 2205098) determination is complemented by multinuclear (1H, 13C, 14/15N, 19F) magic-angle spinning (MAS) solid-state NMR and gauge-including projector augmented wave (GIPAW) calculation of NMR chemical shifts. Lorlatinib crystallises in the P21 space group, with two distinct molecules in the asymmetric unit cell, Z' = 2. Three of the four NH2 hydrogen atoms form intermolecular hydrogen bonds, N30-H…N15 between the two distinct molecules and N30-H…O2 between two equivalent molecules. This is reflected in one of the NH21H chemical shifts being significantly lower, 4.0 ppm compared to 7.0 ppm. Two-dimensional 1H-13C, 14N-1H and 1H (double-quantum, DQ)-1H (single-quantum, SQ) MAS NMR spectra are presented. The 1H resonances are assigned and specific HH proximities corresponding to the observed DQ peaks are identified. The resolution enhancement at a 1H Larmor frequency of 1 GHz as compared to 500 or 600 MHz is demonstrated.

Evolution of the microstructure and the drug release upon annealing the drug loaded lipid-surfactant microspheres.

The present study investigates the drug release-governing microstructural properties of melt spray congealed microspheres encapsulating the drug crystals in the matrix of glyceryl behenate and poloxamer (pore former). The solid-state, morphology, and micromeritics of the microspheres were characterized, before and after annealing, using calorimetry, X-ray scattering, porosimetry, scanning electron microscopy, and, NMR diffusometry. The in vitro drug release from and water uptake by the microspheres were obtained. The extent and the rate of drug release from the microspheres increased with a high poloxamer content and at higher annealing temperature and RH. All the drug release profiles were describable using the Higuchi release kinetics pointing towards the diffusion controlled release, both before and after annealing. The annealing process led to the polymorphic conversion of lipid and the increase in the pore size, predominantly at a higher temperature and humidity and for a high poloxamer content. The poloxamer domain increased from an initial 300 nm, up to 2000 nm upon annealing. The water diffusion rate inside the annealed microsphere was twice as fast as for unannealed counterparts. The findings relate the overall phase and pore structure change of the microsphere to the increased drug release induced by annealing. This work serves as a basis for the rational understanding of the modification of the in vitro performance by annealing, a widely used post-process for solid lipid products.