Development of a Transnasal Delivery System for Recombinant Human Growth Hormone (rhGH): Effects of the Concentration and Molecular Weight of Poly-L-arginine on the Nasal Absorption of rhGH in Rats.

A novel system for delivering recombinant human growth hormone (rhGH) that is noninvasive and has a simple method of administration is strongly desired to improve the compliance of children. The aim of this study was to investigate the potential for the intranasal (i.n.) co-administration of rhGH with poly-L-arginine (PLA) as a novel delivery system by evaluating the effects of the concentration and molecular weight of PLA on the nasal absorption of rhGH. The influence of the formation of insoluble aggregates and a soluble complex in the dosage formulation on nasal rhGH absorption was also evaluated by size-exclusion chromatography and ultrafiltration. PLA enhanced the nasal absorption of rhGH at each concentration and molecular weight examined. Nasal rhGH absorption increased dramatically when the PLA concentration was 1.0 % (w/v) due to the improved solubility of rhGH in the formulation. A delay in rhGH absorption was observed when the molecular weight of PLA was increased. This appeared to be because the increase in molecular weight caused the formation of a soluble complex. It seems that the PLA concentration affects the absorption-enhancing effect on rhGH, while the molecular weight of PLA affects the time when the maximum plasma rhGH concentration was reached (Tmax) of rhGH after i.n. administration, mainly because of the interactions among rhGH, PLA, and additives. Therefore, the transnasal rhGH delivery system using PLA is considered to be a promising alternative to subcutaneous (s.c.) injection if these interactions are sufficiently controlled.

Restricted Delivery of Talazoparib Across the Blood-Brain Barrier Limits the Sensitizing Effects of PARP Inhibition on Temozolomide Therapy in Glioblastoma.

Poly ADP-ribose polymerase (PARP) inhibitors, including talazoparib, potentiate temozolomide efficacy in multiple tumor types; however, talazoparib-mediated sensitization has not been evaluated in orthotopic glioblastoma (GBM) models. This study evaluates talazoparib ± temozolomide in clinically relevant GBM models. Talazoparib at 1-3 nmol/L sensitized T98G, U251, and GBM12 cells to temozolomide, and enhanced DNA damage signaling and G2-M arrest in vitroIn vivo cyclical therapy with talazoparib (0.15 mg/kg twice daily) combined with low-dose temozolomide (5 mg/kg daily) was well tolerated. This talazoparib/temozolomide regimen prolonged tumor stasis more than temozolomide alone in heterotopic GBM12 xenografts [median time to endpoint: 76 days versus 50 days temozolomide (P = 0.005), 11 days placebo (P < 0.001)]. However, talazoparib/temozolomide did not accentuate survival beyond that of temozolomide alone in corresponding orthotopic xenografts [median survival 37 vs. 30 days with temozolomide (P = 0.93), 14 days with placebo, P < 0.001]. Average brain and plasma talazoparib concentrations at 2 hours after a single dose (0.15 mg/kg) were 0.49 ± 0.07 ng/g and 25.5±4.1 ng/mL, respectively. The brain/plasma distribution of talazoparib in Bcrp-/- versus wild-type (WT) mice did not differ, whereas the brain/plasma ratio in Mdr1a/b-/- mice was higher than WT mice (0.23 vs. 0.02, P < 0.001). Consistent with the in vivo brain distribution, overexpression of MDR1 decreased talazoparib accumulation in MDCKII cells. These results indicate that talazoparib has significant MDR1 efflux liability that may restrict delivery across the blood-brain barrier, and this may explain the loss of talazoparib-mediated temozolomide sensitization in orthotopic versus heterotopic GBM xenografts. Mol Cancer Ther; 16(12); 2735-46. ©2017 AACR.