2 research outputs found
Use of High Resolution Mass Spectrometry for Analysis of Polymeric Excipients in Drug Delivery Formulations
Two polymeric excipients, typically used in enabling
drug delivery
approaches, are Gelucire 44/14 (a product of Gattefosse s.a, St Priest,
France) and polysorbate 80; these are known to improve solubility
of poorly water-soluble drugs and, hence, increase their effective
bioavailability. In addition to the use of Gelucire 44/14 and polysorbate
80 as excipients in drugs, they are also widely used as cosmetic and
food additives. In general, complex structures and compositions of
drug excipients impact performance of the formulation in vivo and
consequently affect drug absorption. Therefore, a comparison between
excipients from different suppliers and batches to batch would provide
an indication of the impact on drug product performance and also the
study of the effectiveness of the system and any problems associated
with the formulation. In this study, high resolution Fourier transform
ion cyclotron resonance mass spectrometry (FTICR MS) is used to compare
two different batches of Gelucire 44/14 and polysorbate 80. With the
high resolving power of FTICR MS, it was possible to differentiate
between batches of excipients from differences in the identified components.
The improved resolution offered by FTICR MS allowed assignment of
four polymeric series differences in the two batches of polysorbate
80 and the presence of one compound and three polymeric series differences
in the two batches of Gelucire 44/14. The increase in the number of
components assigned in the excipients batch using FTICR-MS, compared
to the numbers previously assigned by lower resolution TOF MS, underlines
the importance of high resolution techniques in analysis of highly
complex mixtures
Iridium N-Heterocyclic Carbene Complexes as Efficient Catalysts for Magnetization Transfer from <i>para</i>-Hydrogen
While the characterization of materials by NMR is hugely important in the physical and biological sciences, it also plays a vital role in medical imaging. This success is all the more impressive because of the inherently low sensitivity of the method. We establish here that [Ir(H)<sub>2</sub>(IMes)(py)<sub>3</sub>]Cl undergoes both pyridine (py) loss as well as the reductive elimination of H<sub>2</sub>. These reversible processes bring <i>para</i>-H<sub>2</sub> and py into contact in a magnetically coupled environment, delivering an 8100-fold increase in <sup>1</sup>H NMR signal strength relative to non-hyperpolarized py at 3 T. An apparatus that facilitates signal averaging has been built to demonstrate that the efficiency of this process is controlled by the strength of the magnetic field experienced by the complex during the magnetization transfer step. Thermodynamic and kinetic data combined with DFT calculations reveal the involvement of [Ir(H)<sub>2</sub>(η<sup>2</sup>-H<sub>2</sub>)(IMes)(py)<sub>2</sub>]<sup>+</sup>, an unlikely yet key intermediate in the reaction. Deuterium labeling yields an additional 60% improvement in signal, an observation that offers insight into strategies for optimizing this approach