According to the American Heart Association, Heart Disease and Stroke Statistics update 2020 (1), the most recent year available at the time of this publication, cardiovascular disorders accounted for 859,125 deaths in the US out of a total of 2,813,503 registered deaths for the year 2017 (1). Cardiovascular disorders come at a very high cost, estimated to be $1.1 trillion by the year 2035, with direct medical cost estimated to reach $748.7 billion and indirect cost estimated to be $368 billion (1). Given the severity of cardiovascular disorders in the USA, there is an urgent need to develop novel and innovative therapies to help these patients. Cardiac tissue engineering is one such example, a field in which scientists and researchers are working rigorously to develop innovative technologies to help patients with cardiovascular disorders in need of these lifesaving therapies (2, 3).

Research in the field of tissue engineering is focused on fabricating tissue and organs that can be used for clinical transplantation. One of the first publications describing engineering of functional tissue was in 1988, when it was shown that primary hepatocytes isolated from rodent were cultured in three-dimensional matrices fabricated using three different polymers, polyglactin, polyorthoester, and polyanhydride (4). The primary hepatocytes were shown to maintain viability, function, and engraftment within the three-dimensional matrices. This work was seminal as it was the first time that primary cells were cultured within three-dimensional matrices to form functional tissue, the basis of tissue engineering as a scientific discipline.

The field of cardiac tissue engineering includes heart muscle tissue (2, 3), aortic valves (5), vascular grafts (6–8), vascular networks (9, 10) and Purkinje networks, left ventricles (11), and whole hearts (12) (Figure 1). While heart muscle tissue engineering is now an established field (3), the same is not true for ventricle bioengineering, a niche field and the focus on this review article.

There is a large body of literature describing methods to bioengineer cardiovascular tissue constructs (13–17), based on which a methodological process has now evolved (Figure 2). The first step in the process is cell sourcing, generating a large number of contractile cardiomyocytes (CMs). Neonatal ventricular rat myocytes (NVRMs) are used for initial proof-of-concept studies and model development and validation efforts, while induced pluripotentent stem cell (iPSC)-derived CMs are used for clinical studies. The second step involves biomaterial synthesis, which entails the development of novel biomaterials that can be used to simulate mammalian extracellular matrix (ECM). A large number of biomaterials have been used in the field, to include collagen type I, fibrin, gelatin, alginate, and chitosan, to name a few (18). The third step involves coupling contractile CMs with novel biomaterials to generate functional ventricles, in other words, develop novel fabrication methods to bioengineer functional ventricles. The fourth and final step is in vitro conditioning of bioengineered ventricles using bioreactors for coupled electromechanical stimulation.

The notion to bioengineer cardiac patches is easy to understand as the potential applications to repair infarcted myocardium tissue are now well-established (18, 19). Similarly, the utility of vascular grafts, aortic and mitral valves, and whole hearts for potential therapeutic purposes is evident and well-described (19). However, the rationale to bioengineer ventricles is not as straightforward as there is no obvious therapeutic target for bioengineered ventricles. However, irrespective of the lack of a clear therapeutic target, there are many reasons to bioengineer ventricles. First and foremost, the holy grail of tissue engineering is to bioengineer a complete bioartificial and the experience gained in ventricle bioengineering is critical to accomplishing this goal. Second, bioengineered ventricles provide valuable tools to study fluid dynamics in an isolated in vitro system and can also be used to understand the role of pressure and volume overload and other complex physiological phenomena, oftentimes difficult to study using existing models. Third, a complete left ventricle that contains a hollow chamber, contractile heart muscle, and mitral valves, including outflow and inflow tracts, can be used to investigate and understand the interrelationship between all these tissue components during heart function, something that would not be possible using any other in vitro or in vivo model systems. Fourth, bioengineered ventricles can be used to study cardiotoxicity effects of pharmacological agents, thereby reducing the animal cost.

Our approach to answering this question is to explore at different strategies for the key components of the ventricle fabrication process, namely, fabrication technology, biomaterial, cell source, bioreactors, and functional assessment; see Table 1. The goal is to critically evaluate the current state of the art and provide a directive moving forward.

While much progress has been made in the field of ventricle tissue engineering, a structured and methodological approach is needed moving forward. Here we provide guidance for the field of ventricle tissue engineering moving forward. Model development and optimization studies need to be conducted with NVRMs to achieve left ventricular pressures of 120 mm Hg coupled with parallel studies using iPSC-derived CMs for patient-specific disease models, for biomarker development and development of new investigational strategies. CMs derived from iPSCs are known to be immature, and the ability to develop maturation paradigms is critical for the field of ventricle tissue engineering and tissue engineering as a whole. Controlled electromechanical regimes coupled with chemical conditioning using growth factors and cytokines are required to achieve this. New biomaterial formulations continue to be developed and optimized, and existing tissue fabrication methods continue to be refined and adopted for ventricle bioengineering (34). A critical hurdle that needs to be overcome is the development of patent vasculature that can support the viability of contracting CMs. This is critical to supporting the metabolic activity of contracting cells, and in the absence of engineered vasculature, tissue-engineered constructs are limited in thickness.

Bioreactors need to be more consistent between labs to allow information exchange (35, 36), which in turn will accelerate development of ventricles for any given applications; sharing of software and code hardware components through open-source mechanisms will be required and will be a much-needed advancement in the field of ventricle tissue engineering.

Though challenges remain in the field, recent advances provide positive guidance and suggest that the ability to bridge the functional gap between bioengineered and human ventricles is achievable in the near future.

The author confirms being the sole contributor of this work and has approved it for publication.

RB is CSO of a Biotech Company that worked on bioprinting human hearts.