RoseE.A., MoskowitzA.J., PackerM.The REMATCH trial: rationale, design, and end points. Randomized Evaluation of Mechanical Assistance for the Treatment of Congestive Heart Failure. Ann Thorac Surg.1999; 67(3): 723–730.
3.
SlaughterM.S., RogersJ.G., MilanoC.A.; HeartMate II Investigators. Advanced heart failure treated with continuous-flow left ventricular assist device. N Engl J Med.2009; 361(23): 2241–2251.
4.
McMurrayJ.J., AdamopoulosS., AnkerS.D.; ESC Committee for Practice Guidelines. ESC Guidelines for the diagnosis and treatment of acute and chronic heart failure 2012: The Task Force for the Diagnosis and Treatment of Acute and Chronic Heart Failure 2012 of the European Society of Cardiology. Developed in collaboration with the Heart Failure Association (HFA) of the ESC. Eur Heart J.2012; 33(14): 1787–1847.
5.
PaganiF., MilanoC., TatoolesA.Heartware HVAD for the Treatment of Patients with Advanced Heart Failure Ineligible for Cardiac Transplantation: Results of the ENDURANCE Destination Therapy Trial. ISHLT Conference, Nice, 2015.
6.
EstepJ.D., StarlingR.C., HorstmanshofD.A. et al; ROADMAP Study Investigators. Risk Assessment and Comparative Effectiveness of Left Ventricular Assist Device and Medical Management in Ambulatory Heart Failure Patients: Results From the ROADMAP Study. J Am Coll Cardiol.2015; 66(16): 1747–1761.
7.
NetukaI., SoodP., PyaY.Fully Magnetically Levitated Left Ventricular Assist System for Treating Advanced HF: A Multicenter Study. J Am Coll Cardiol.2015; 66(23): 2579–2589.
8.
NunesA.J., MacArthurR.G.G., KimD.A Systematic Review of the Cost-Effectiveness of Long-Term Mechanical Circulatory Support. Value Heal.2015. doi: 10.1016/j.jval.2014.12.020.
9.
KamenevaM.V., AntakiJ.F.Mechanical Trauma to Blood. In: BaskurtO.K., HardemanM.R., RamplingM.W., MeiselmanH.J., eds. Handbook of Hemorheology and Hemodynamics.Amsterdam: IOS Press2007; 206–227.
10.
OliaS.E., MaulT.M., AntakiJ.F., KamenevaM.V.Mechanical blood trauma in assisted circulation: sublethal RBC damage preceding hemolysis. Int J Artif Organs.2016; 39(4): 150–159.
11.
PoorkhalilA., AmoabedinyG., TabeshH., BehbahaniM., MottaghyK.A new approach for semiempirical modeling of mechanical blood trauma. Int J Artif Organs.2016; 39(4): 171–177.
12.
WatanabeN., UedaS., NagashimaK., OguriT., MitaT.Ratio of surface roughness to flow scale as additional parameter for shear-induced hemolysis. Int J Artif Organs.2016; 39(4): 205–210.
13.
HeuserG., OpitzR.A Couette viscometer for short time shearing of blood. Biorheology.1980; 17(1-2): 17–24.
14.
GiersiepenM., WurzingerU., OpitzR., ReulH.Estimation of shear stress-related blood damage in heart valve prostheses in vitro comparison of 25 aortic valves. Int J Artif Organs.1990; 13(5): 300–306.
15.
GesenhuesL., PauliL., BehrM.Strain-based blood damage estimation for computational design of ventricular assist devices. Int J Artif Organs.2016; 39(4): 166–170.
16.
KamenevaM.V., BurgreenG.W., KonoK., RepkoB., AntakiJ.F., UmezuM.Effects of turbulent stresses upon mechanical hemolysis: experimental and computational analysis. ASAIO J.2004; 50(5): 418–423.
17.
GoubergritsL., OsmanJ., MevertR., KertzscherU., PöthkowK., HegeH.C.Turbulence in blood damage modeling. Int J Artif Organs.2016; 39(4): 160–165.
18.
AntakiJ.F., DiaoC.G., ShuF.J., WuJ.C., ZhaoR., KamenevaM.V.Microhaemodynamics within the blade tip clearance of a centrifugal turbodynamic blood pump. Proc Inst Mech Eng H.2008; 222(4): 573–581.
19.
MaruyamaO., KosakaR., NishidaM., YamaneT., TatsumiE., TaenakaY.In vitro thrombogenesis resulting from decreased shear rate and blood coagulability. Int J Artif Organs.2016; 39(4): 194–199.
20.
CasaL.D., DeatonD.H., KuD.N.Role of high shear rate in thrombosis. J Vasc Surg.2015; 61(4): 1068–80.
21.
HastingsS.M., DeshpandeS.R., WagonerS., MaherK., KuD.N.Thrombosis in centrifugal pumps: location and composition in clinical and in vitro circuits. Int J Artif Organs.2016; 39(4): 200–204.
22.
ConsoloF., DimasiA., RasponiM.Microfluidic approaches for the assessment of blood cell trauma: a focus on thrombotic risk in mechanical circulatory support devices. Int J Artif Organs.2016; 39(4): 184–193.
23.
ThamsenB., MevertR., LommelM.A two-stage rotary blood pump design with potentially lower blood trauma: a computational study. Int J Artif Organs.2016; 39(4): 178–183.
24.
BashirJ., LegareJ.F., FreedD.H., CheungA., RaoV., TomaM.Multicentre Canadian experience with the HeartWare ventricular assist device: concerns about adverse neurological outcomes. Can J Cardiol.2014; 30(12): 1662–1667.
25.
MieraO., KirkR., BuchholzH.A multicenter study of the HeartWare ventricular assist device in small children. J Heart Lung Transplant.2016; 35(5): 679–681.
