BACKGROUND: To evaluate the effect of plasminogen activator inhibitor type 1 (PAI-1) levels on the clearance of total tissue plasminogen activator (TPA) antigen, we studied the clearance of active TPA and TPA/PAI-1 complex in subjects with low (181+/-109 pmol/L; n=7) and high (1166+/-322 pmol/L; n=4) baseline active PAI-1. METHODS AND RESULTS: A 5-microg/kg bolus of TPA was infused over a 15-second period followed by measurement of TPA activity, TPA antigen, TPA/PAI-1, TPA/C1 inhibitor, PAI-1 activity, and PAI-1 antigen over a 4-hour period. alpha-Phase clearance of total TPA antigen was faster in subjects with low PAI-1 (t(1/2) of 3.5+/-0.7 minutes) versus high PAI-1 (t(1/2) of 5.3+/-0.9 minutes) (P=.006). Clearance of all factors was best fit by a two-compartment pharmacokinetic model based on a computer-simulated human circulatory system. The average hepatic clearance fraction in the two-compartment model was greater for active TPA (89+/-10%, t(1/2) of 2.4+/-0.3 minutes) than for TPA/PAI-1 complex (48+/-17%, t(1/2) of 5.0+/-1.8 minutes) (P=.0006). CONCLUSIONS: Plasma clearance of active TPA was faster than clearance of TPA/PAI-1 complex. High levels of active PAI-1 converted more TPA into TPA/PAI-1 complex, effectively slowing the clearance of total TPA antigen and explaining in part why high levels of PAI-1 activity are associated with increases in total TPA antigen.
BACKGROUND: To evaluate the effect of plasminogen activator inhibitor type 1 (PAI-1) levels on the clearance of total tissue plasminogen activator (TPA) antigen, we studied the clearance of active TPA and TPA/PAI-1 complex in subjects with low (181+/-109 pmol/L; n=7) and high (1166+/-322 pmol/L; n=4) baseline active PAI-1. METHODS AND RESULTS: A 5-microg/kg bolus of TPA was infused over a 15-second period followed by measurement of TPA activity, TPA antigen, TPA/PAI-1, TPA/C1 inhibitor, PAI-1 activity, and PAI-1 antigen over a 4-hour period. alpha-Phase clearance of total TPA antigen was faster in subjects with low PAI-1 (t(1/2) of 3.5+/-0.7 minutes) versus high PAI-1 (t(1/2) of 5.3+/-0.9 minutes) (P=.006). Clearance of all factors was best fit by a two-compartment pharmacokinetic model based on a computer-simulated human circulatory system. The average hepatic clearance fraction in the two-compartment model was greater for active TPA (89+/-10%, t(1/2) of 2.4+/-0.3 minutes) than for TPA/PAI-1 complex (48+/-17%, t(1/2) of 5.0+/-1.8 minutes) (P=.0006). CONCLUSIONS: Plasma clearance of active TPA was faster than clearance of TPA/PAI-1 complex. High levels of active PAI-1 converted more TPA into TPA/PAI-1 complex, effectively slowing the clearance of total TPA antigen and explaining in part why high levels of PAI-1 activity are associated with increases in total TPA antigen.
Authors: Ananth K Vellimana; Chester K Yarbrough; Spiros Blackburn; Russell G Strom; Thomas K Pilgram; Jin-Moo Lee; Robert L Grubb; Keith M Rich; Michael R Chicoine; Ralph G Dacey; Colin P Derdeyn; Gregory J Zipfel Journal: Neurosurgery Date: 2014-03 Impact factor: 4.654
Authors: T A Tomsick; P Khatri; T Jovin; B Demaerschalk; T Malisch; A Demchuk; M D Hill; E Jauch; J Spilker; J P Broderick Journal: Neurology Date: 2010-03-30 Impact factor: 9.910
Authors: Xiangmei May Wu; Rupa Basu; Brian Malig; Rachel Broadwin; Keita Ebisu; Ellen B Gold; Lihong Qi; Carol Derby; Rochelle S Green Journal: Environ Int Date: 2017-07-26 Impact factor: 9.621
Authors: Ananth K Vellimana; Chad W Washington; Chester K Yarbrough; Thomas K Pilgram; Brian L Hoh; Colin P Derdeyn; Gregory J Zipfel Journal: Neurosurgery Date: 2018-11-01 Impact factor: 4.654