RT Journal Article
SR Electronic
T1 Characterization of Protein Aggregating Tungstates: Electrospray Mass Spectrometry Analysis of Extracts from Pre-filled Syringes and from Tungsten Pins Used in the Manufacture of Syringes
JF PDA Journal of Pharmaceutical Science and Technology
JO PDA J Pharm Sci Technol
FD Parenteral Drug Association (PDA)
SP pdajpst.2015.005546
DO 10.5731/pdajpst.2015.005546
A1 Ronk, Michael
A1 Lee, Hans
A1 Fujimori, Kiyoshi
A1 Yeh, Ping
A1 Nashed-Samuel, Yasser
YR 2016
UL http://journal.pda.org/content/early/2016/01/14/pdajpst.2015.005546.abstract
AB Glass prefilled syringes (PFS) are increasingly becoming a container of choice for storing and administering therapeutic protein products to patients. Tungsten leaching from a PFS is known to induce protein particle formation and the source was traced to the tungsten pins used in the manufacturing process of the syringe barrels. Study of the tungstates present in extracts from both tungsten pins used in the syringe manufacturing process and from single syringes from various suppliers was undertaken. Electrospray mass spectrometry (ESI/MS) was chosen as a technique with the sensitivity to characterize tungstates at levels (~ 1 ppm of elemental tungsten) observed in single syringes. Extraction solvents were chosen to simulate the range (pH 4.0-7.0) typically used for therapeutic protein formulation. A commercial product formulation buffer was also used as an extraction solution to characterize tungstate species used for tungsten-spiking studies of protein. All pin and syringe extracts from various manufacturers were similar in regards to containing stable Na/K containing lacunary polytungstate ([W11O39]7-) species, which were the main species present in syringe extracts and are different than the metatungstate ([W12O39]6-) species identified in commercially available sodium polytungstate and as the main species in pin extracts. These stable Na/K containing polytungstates species present in pin and syringe extracts are likely formed during the glass manufacturing process at &gt;400°C and may have the capability to subsequently form larger polytungstate complexes.