Stress and Exposure Time on von Willebrand Factor Degradation.

Abstract

Despite the prevailing use of the continuous flow left ventricular assist devices (cf-LVAD), acquired von Willebrand syndrome (AvWS) associated with cf-LVAD still remains a major complication. As AvWS is known to be dependent on shear stress (τ) and exposure time (texp ), this study examined the degradation of high molecular weight multimers (HMWM) of von Willebrand factor (vWF) in terms of τ and texp . Two custom apparatus, i.e., capillary-tubing-type degrader (CTD) and Taylor-Couette-type degrader (TCD) were developed for short-term (0.033 sec≤texp ≤1.05s) and long-term (10s≤texp ≤10min) shear exposures of vWF, respectively. Flow conditions indexed by Reynolds number (Re) for CTD were 14≤Re≤288 with corresponding laminar stress level of 52≤ ≤1042dyne/cm2 . Flow conditions for TCD were 100≤Re≤2500 with corresponding rotor speed of 180≤o ≤4000RPM and laminar stress level of 50≤ ≤1114dyne/cm2 . Due to transitional and turbulent flows in TCD at Re>1117, total stress (i.e., =laminar+turbulent) was also calculated using a computational fluid dynamics (CFD) solver, Converge CFD (Converge Science Inc., Madison, WI, USA). Inhibition of ADAMTS13 with different concentration of EDTA (5mM and 10mM) was also performed to investigate the mechanism of cleavage in terms of mechanical and enzymatic aspects. Degradation of HMWM with CTD was negligible at all given testing conditions. Although no degradation of HMWM was observed with TCD at Re<1117 ( =1012dyne/cm2 ), increase in degradation of HMWM was observed beyond Re of 1117 for all given exposure times. At Re ~ 2500 ( =3070dyne/cm2 ) with texp =60s, a severe degradation of HMWM (90.7±3.8%, abnormal) was observed, and almost complete degradation of HMWM (96.1±1.9%, abnormal) was observed with texp =600s. The inhibition studies with 5mM EDTA at Re ~ 2500 showed that loss of HMWM was negligible (<10%, normal) for all given exposure times except for texp =10min (39.5±22.3%, borderline-abnormal). With 10mM EDTA, no degradation of HMWM was observed (11.1±4.4%, normal) even for texp =10min. This study investigated the effect of shear stress and exposure time on the HMWM of vWF in laminar and turbulent flows. The inhibition study by EDTA confirms that degradation of HMWM is initiated by shear-induced unfolding followed by enzymatic cleavage at given conditions. Determination of magnitude of each mechanism needs further investigation. It is also important to note that the degradation of vWF is highly dependent on turbulence regardless of the time exposed within our testing conditions.