Constructing and evaluating the effect of micron-scale structures on von Willebrand factor damage.

The incidence of clinical complication gastrointestinal bleeding has been proved as consequence of von Willebrand factor (VWF) damage after mechanical circulatory support in clinic. Many studies have been conducted to evaluate VWF damage, of which the most studied influencing factors are mechanical factors such as shear stress. However, in addition to mechanical factors, VWF damage may also be affected by interface factors. To address this issue, a roller pump circulation platform was established to investigate the effect of material surface micron-scale structures distribution on VWF damage in flow state. A composite micro-structure combining microngrating and micronpost was designed and constructed on the surface of Si wafer by lithography and reactive ion etching, and detailed characterization of material surfaces was also performed. Then the changes of VWF antigen, VWF ristocetin cofactor activity, and the degradation of high molecular weight VWF on these surfaces were investigated and compared. The results showed that, with the encryption of surface micro-structures arrangement, the material surface tends to be more hydrophobic, which is beneficial to reduce VWF damage. Therefore, in the design of material surface inside the mechanical circulatory support devices, it can be considered to add some surface micro-structures with a certain distribution density to change the hydrophilicity and hydrophobicity, so as to minimize the VWF damage. These results can provide important references for the evaluation of VWF damage caused by interface factors, and aid in designing material surface inside the mechanical circulatory support devices.

In vitro comparative study of red blood cell and VWF damage on 3D printing biomaterials under different blood-contacting conditions.

Mechanical circulatory support devices (MCSDs) are often associated with hemocompatible complications such as hemolysis and gastrointestinal bleeding when treating patients with end-stage heart failure. Shear stress and exposure time have been identified as the two most important mechanical factors causing blood damage. However, the materials of MCSDs may also induce blood damage when contacting with blood. In this study, the red blood cell and von Willebrand Factor (VWF) damage caused by four 3D printing biomaterials were investigated, including acrylic, PCISO, Somos EvoLVe 128, and stainless steel. A roller pump circulation experimental platform and a rotor blood-shearing experimental platform were constructed to mimic static and dynamic blood-contacting conditions of materials in MCSDs, respectively. Free hemoglobin assay and VWF molecular weight analysis were performed on the experimental blood samples. It indicated that different 3D printing materials and technology could induce different levels of damage to red blood cells and VWF, with acrylic causing the least damage under both static and dynamic conditions. In addition, it was found that blood damage measured for the same material differed on the two platforms. Therefore, a combination of static and dynamic experiments should be used to comprehensively investigate the effects of blood damage caused by the material. It can provide a reference for the design and evaluation of materials in different components of MCSDs.

A comprehensive comparison of the in vitro hemocompatibility of extracorporeal centrifugal blood pumps.

Purpose: Blood damage has been associated with patients under temporary continuous-flow mechanical circulatory support. To evaluate the side effects caused by transit blood pumping, in vitro hemocompatibility testing for blood damage in pumps is considered a necessary reference before clinical trials. Methods: The hemocompatibility of five extracorporeal centrifugal blood pumps was investigated comprehensively, including four commercial pumps (the Abbott CentriMag, the Terumo Capiox, the Medos DP3, and the Medtronic BPX-80) and a pump in development (the magAssist MoyoAssist®). In vitro, hemolysis was tested with heparinized porcine blood at nominal operating conditions (5 L/min, 160 mmHg) and extreme operating conditions (1 L/min, 290 mmHg) using a circulation flow loop. Hematology analyses concerning the blood cell counts and the degradation of high-molecular-weight von Willebrand factor (VWF) during 6-h circulation were also evaluated. Results: Comparing the in vitro hemocompatibility of blood pumps at different operations, the blood damage was significantly more severe at extreme operating conditions than that at nominal operating conditions. The performance of the five blood pumps was arranged in different orders at these two operating conditions. The results also demonstrated superior hemocompatibility of CentriMag and MoyoAssist® at two operating conditions, with overall low blood damage at hemolysis level, blood cell counts, and degradation of high-molecular-weight VWF. It suggested that magnetic bearings have an advantage in hemocompatibility compared to the mechanical bearing of blood pumps. Conclusion: Involving multiple operating conditions of blood pumps in in vitro hemocompatibility evaluation will be helpful for clinical application. In addition, the magnetically levitated centrifugal blood pump MoyoAssist® shows great potential in the future as it demonstrated good in vitro hemocompatibility.