The use of mechanical circulatory support devices (MCSD) has experienced a dramatic rise during the past decades, due to the increasing number of patients developing end-stage heart failure.

In terms of therapy duration, we can distinguish two types of ventricular assist devices (VAD): temporary or short-term, commonly indicated in acute heart failure patients, and durable or long-term devices, usually implanted as a bridging therapy for transplant (BTT) or as a destination therapy.

Temporary mechanical circulatory support, such as the Extracorporeal Membrane Oxigenator (ECMO), has been widely used in both adult and paediatric population; but when it comes to long-term VAD (ltVAD), its use on infants, young children and even adolescents, despite the international and multicentric registries, still has some lack of evidence.

Whereas ltVAD is a well established therapy in adults,1–3 the experience in children (specially young infants) is still scarce.

On the one hand, paediatric cardiac population includes a large range of physiological and anatomical variations; consequently, it is more difficult to determine the right timing and candidacy for ltVAD implantation. On the other hand, patient size can be an issue since most devices have been initially developed for adult population.

Nevertheless, and according to the last data obtained from studies, such as PediMACS, VAD as BTT has proved to reduce up to 50% the mortality while on the waiting list,4 with post-transplant results comparable to those patients not requiring MCSD.5

The Great Ormond Street Hospital for Children, in London, is one of the only two centres in the UK implanting ltVAD in paediatric patients, with a great experience over the past 15 years.

The multidisciplinary VAD team at the Great Ormond Street Hospital comprises a large number of highly-trained and experienced professionals, including nurses, intensivists, cardiologists and cardiothoracic surgeons.

Despite the increasing number of centres performing VAD implants in children, MCS in paediatric population still offers many challenges to be solved.

The Pediatric Interagency Registry for Mechanical Circulatory Support (PediMACS), provides periodic reports, offering a multicentre perspective on the paediatric ventricular assist device outlook.

The results seem promising so far: paediatric survival on long-term VAD is 81% at 6 months.6 Being bridge to transplant the primary indication for durable VAD in children in the vast majority of cases (more than 85%), the success rate of bridging the patient to transplant on support is 86%.5 The last report, published in 2018, states that 50% of patients underwent heart transplant within the first 6 months after the device implant. Furthermore, results of patients being bridged to transplant on VAD are comparable to those undergoing transplant without requiring support.7 Death rate among patients on VAD who are listed and waiting for transplant has been recently reported to be 16% in the current era,8 while the peak hazard for death is 2 weeks after VAD implantation.5

This mortality risk while being on VAD support is directly related to the underlying cardiac diagnosis: patients with congenital heart disease present worse outcomes. Although most patients in end-stage heart failure receiving durable MCS are diagnosed with cardiomyopathy (in our experience, DCM is the most common indication for VAD), the CHD group still remains an outstanding challenge for implantation surgical strategy as well as for postoperative management.8,9 It is extremely important to assess correctly the anatomy and physiology of the patient prior to the implant, paying special attention to previous cardiac procedures and palliations. Hence, single ventricle physiology poses a particularly difficult situation. Weinstein et al. reported their experience with Berlin Heart EXCOR in patients with functionally single ventricle,10 obtaining very poor outcomes in babies after palliation stage I, and getting better results after Glenn and TCPC stage palliations. However, special considerations need to be taken when implanting any support device in these patients, as they may require to take down the TCPC circulation and separate the systemic venous return from the pulmonary circulation.11 Other cardiac diagnosis may require further interventions prior to the assist device implant: severe aortic regurgitation, for example, is a formal contraindication for LVAD, therefore it needs to be addressed before the implantation. In our series, the only patient presenting with aortic valve disease (both regurgitation and stenosis), underwent an aortic valve replacement; but other solutions, as aortic exclusion, have been proposed.12

In addition to having a potentially more complex anatomy and physiology in paediatric population compared to adults, patient size can also be an issue. Most assist devices have been developed for adult population, which makes impossible its use in small infants. Currently, only paracorporeal pulsatile devices such as Berlin Heart EXCOR, which offers a range of cannulae and pump sizes, are widely used in small children. In fact, the median weight of patients receiving BH support at GOSH is 12.8kg, being the lowest 3.9kg. The disposition of this device (paracorporeal, with cannulae connecting the patient to an external pump), makes it possible to exchange BH support to ECMO or Levitronix when needed, until the patient gets proper stabilization.

In fact, ECMO support prior to BH implant is a common practice: 34.65% of our patients went on ECMO before going to BH. Almond et al. reported in 20139 that early mortality after BH implantation was directly related to lower body weight, higher bilirubin and BiVAD support, whereas late mortality was related to both liver and kidney dysfunction; therefore, end-organ failure at the moment of the implant is associated to a poor prognosis. Consequently, two strategies should be adopted at this point: a correct timing for implant before end-organ dysfunction occurs, and ECMO support for organ recovery before going into durable VAD support. High volume and experienced centres are more likely to get better outcomes, mostly due to a better timing and candidacy decision.

Furthermore, BH offers the possibility of BiVAD support, in case of associated right heart failure. In our case, 32.65% of patients on BH required biventricular support. Right ventricle failure after LVAD implant, such as HeartWare, can be a major problem, and it has been reported to happen in 7–30% of the patients having initially only left heart support.13,14 The perioperative management should then include the initiation of iNO prior to weaning off bypass during the LVAD implant, and continuation in the immediate postoperative course.15

Still, the main burden of BH support is the high rate of associated complications: specially neurological insult and significant bleeding. Cassidy et al. published in 2013 the experience with BH in 2 UK high volume centres: GOSH and Newcastle.16 Even though survival results were excellent (84% of patients in BH made it to transplant or recovery and explant), 25.4% of patients had a stroke while receiving BH support. This percentage can even be higher in some series (up to 30%), while in ours, the rate of neurological damage is 30.61%. This needs a deep consideration, as one of three patients receiving a BH device might experience any kind of neurological adverse event.

The risk for developing any neurological or haemorrhagic complication while on support, has been reported to be higher in pulsatile than in continuous flow devices. Even Dipchand et al. recently published that survival at 2 years after implant is lower for pulsatile devices.8 Not to mention other intracorporeal devices advantages: patients are able to be discharged home while waiting for transplant (Fraser et al. have recently reported a discharge home rate of 85% since 200417), and, although rarely, they can be used as destination therapy in adolescents with fatal prognosis systemic disease, such as Duchenne's myopathy18 (despite this last indication is not currently commissioned in the UK). As a consequence of this, the overall trend is to increase the number of implants of CF devices in detriment of pulsatile flow ones.19

Although it has been used for many years in children,20 the main issue related to the use of HVAD is the size: its intended use is for adult population, therefore, it can be only used in adolescents or large children with a BSA greater than 1m2. In fact, according to the last PediMACS report,21 including 432 devices implanted in 364 patients, the median age for paracorporeal devices was 1.7 years old, while this was 15 years old for continuous flow devices. Miera et al.,14 though, reported a multicentre study of HVAD in children with a median BSA of 0.8m2, with a survival rate of 92.3%, similar to older patients. Nevertheless, being an intracorporeal device, it makes very challenging to implant it in small infants.

Having this in mind, the National Heart, Lung and Blood Institute (NHLBI), launched the PumpKIN (Pumps for Kids, Infants and Neonates) program and subsequently developed the Infant Jarvik 2015 device,22 with promising perspectives in the future of VAD in children.

However, it is crucial to involve patients and their families in the whole process of the decision making and post-implant device management. Gilmore et al. reported in 2011 the experience of parents and children who had been bridged to transplant with VAD.23 The overall feeling was that, although parents reassured they had made the right decision by accepting the treatment, there was an inadequate information at the time of giving consent, specially when considering it's a psychologically stressful situation. Children are frequently left out of the equation, not involving them in the explanations about the long-term plan and how VAD will possibly change their lives. That's why a solid VAD unit requires a large and multidisciplinary team, who can help families and patients deal with this big change, and inform about the benefits and possible complications that may appear along the way to transplant.

Long-term VAD has been increasing on use and popularity for end-stage heart failure in paediatric population for the past years. Its success lies on the high percentage of these patients being safely bridged to transplant and the high survival after this. However, there are many challenges that still need to be solved. Outcomes are directly related to the patient's baseline condition, like underlying congenital cardiac disease, end-organ failure, or weight at the time of the implant. However, they are also related to the device-related adverse events that might occur while being on support. Paracorporeal pulsatile-flow devices, such as Berlin Heart, which are the most commonly used for infants due to the small-sized cannulae and pump availability, still present a vascular neurological complication rate up to 30%. Therefore, is essential to give the patients and their relatives the adequate amount of information, and get all these potential candidates referred to a high experienced centre, with a well-trained multidisciplinary team, in order to get the best results

None.