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Abstract

Background

Right ventricular failure (RVF) is one of the major complications during LVAD. Apart from drug therapy, the most reliable option is the implantation of RVAD. However, BIVAD have a poor prognosis and increased complications. Experiments have been conducted on alternative approaches, such as the creation of an atrial septal defect (ASD), a cavo-aortic shunt (CAS) including the LVAD and a cavo-pulmonary connection (CPC). This work aims at realizing a lumped parameter model (LPM) to compare the acute hemodynamic effects of ASD, CPC, CAS, RVAD in LVAD pediatric patients with RVF.

Methods

Data of 5 pediatric patients undergoing LVAD were retrospectively collected to reproduce patients baseline hemodynamics with the LPM. The effects of continuous flow LVAD implantation complicated by RVF was simulated and then the effects of ASD, CPC, CAS and RVAD treatments were simulated for each patient.

Results

The model successfully reproduced patients' baseline and the hemodynamic effects of the surgical strategies. Simulating the different surgical strategies, an unloading of the right ventricle and an increment of left ventricular preload were observed with an improvement of the hemodynamics (total cardiac output: ASD +15%, CPC +10%, CAS +70% RVAD +20%; right ventricular external work: ASD -19%, CPC -46%, CAS -76%, RVAD -32%; left ventricular external work: ASD +12%, CPC +28%, RVAD +64%).

Conclusions

The use of numerical model could offer an additional support for clinical decision-making, also potentially reducing animal experiments, to compare the outcome of different surgical strategies to treat RVF in LVAD.

Keywords

LVAD Right ventricular failure Pediatrics Lumped parameter model

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References

Succi

G.M.

, Moreira

L.F.P.

, Leirner

A.A.

, Silva

R.S.

, Stolf

N.A.G.

Cavopulmonary anastomosis improves left ventricular assist device support in acute biventricular failure.

Eur J Cardiothorac Surg. 2009; 35(3): 528–533.

Santos

L.A.

, Benício

, Mattos

Júnior Ed

Cavo-pulmonary anastomosis associated with left ventricular in comparison with biventricular circulatory support in acute heart failure.

Rev Bras Cir Cardiovasc. 2012; 27(4): 552–561.

Karimova

, Pockett

C.R.

, Lasuen

Right ventricular dysfunction in children supported with pulsatile ventricular assist devices.

J Thorac Cardiovasc Surg. 2014; 147(5): 1691–1697. e1.

Vikholm

, Schiller

, Johansson

, Hellgren

A modified Glenn shunt improves haemodynamics in acute right ventricular failure in an experimental model.

Eur J Cardiothorac Surg. 2013; 43(3): 612–618.

Drakos

S.G.

, Janicki

, Horne

B.D.

Risk factors predictive of right ventricular failure after left ventricular assist device implantation.

Am J Cardiol. 2010; 105(7): 1030–1035.

Grant

A.D.M.

, Smedira

N.G.

, Starling

R.C.

, Marwick

T.H.

Independent and incremental role of quantitative right ventricular evaluation for the prediction of right ventricular failure after left ventricular assist device implantation.

J Am Coll Cardiol. 2012; 60(6): 521–528.

Raina

, Rammohan

H.R.S.

, Gertz

Z.M.

, Rame

J.E.

, Woo

Y.J.

, Kirkpatrick

J.N.

Postoperative Right Ventricular Failure After Left Ventricular Assist Device Placement is Predicted by Pre-Operative Echocardiographic Structural, Hemodynamic, and Functional Parameters.

J Cardiac Fail. 2013; 19: 16–24.

Danton

M.H.

, Byrne

J.G.

, Flores

K.Q.

Modified Glenn connection for acutely ischemic right ventricular failure reverses secondary left ventricular dysfunction.

J Thorac Cardiovasc Surg. 2001; 122(1): 80–91.

Vikholm

, Schiller

, Johansson

, Hellgren

Cavoaortic shunt improves hemodynamics with preserved oxygen delivery in experimental right ventricular failure during left ventricular assist device therapy.

J Thorac Cardiovasc Surg. 2014; 147: 625–631.

10.

Saito

, Toda

, Takewa

, Tsukiya

, Mizuno

, Taenaka

, Tatsumi

Alternative approach for right ventricular failure after left ventricular assist device placement in animal model.

Eur J Cardiothorac Surg. 2014; 48(1): 98–103.

11.

Di Molfetta

, Jacobs

, Fresiello

Simulation of apical and atrio-aortic VAD in patients with transposition or congenitally corrected transposition of the great arteries.

Int J Artif Organs. 2014; 37(1): 58–70.

12.

Di Molfetta

, Amodeo

, Fresiello

, Trivella

M.G.

, Iacobelli

, Pilati

, Ferrari

Simulation of ventricular, cavo-pulmonary and biventricular VADs in Failing Fontan.

Artif Organs. 2015; 39(7): 550–558.

13.

Wei

, Li

Pre-clinical evaluation of the infant Jarvik 2000 heart in a neonate piglet model.

J Heart Lung Transplant. 2013; 32(1): 112–119.

14.

Sagawa

, Maughan

, Suga

, Sunagawa

Cardiac contraction and the Pressure-Volume relationships. New York: Oxford University Press; 1998.

15.

Migliavacca

, Dubini

, Pennati

Computational model of the fluid dynamics in systemic-to-pulmonary shunts.

J Biomech. 2000; 33(5): 549–557.

16.

Di Molfetta

, Santini

, Forleo

G.B.

, Cesario

, Tota

, Sgueglia

, Sergi

, Ferrari

, Romeo

Use of a comprehensive numerical model to improve biventricular pacemaker temporization in patients affected by heart failure undergoing to CRT-D therapy.

Med Biol Eng Comput. 2010; 48(8): 755–764.

17.

Kinoshita

, Long

J.W.

Jr. , Pantalos

, Burns

G.L.

, Olsen

D.B.

Hemodynamic influence of LVAD on right ventricular failure.

ASAIO Trans. 1990; 36(3): M538–M541.

Simulation of Acute Haemodynamic Outcomes of the Surgical Strategies for the Right Ventricular Failure Treatment in Pediatric LVAD

Abstract

Background

Methods

Results

Conclusions

Keywords

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