First-in-Human Segmental Esophageal Reconstruction Using a Bioengineered Mesenchymal Stromal Cell-Seeded Implant.

INTRODUCTION: Resection and reconstruction of the esophagus remains fraught with morbidity and mortality. Recently, data from a porcine reconstruction model revealed that segmental esophageal reconstruction using an autologous mesenchymal stromal cell-seeded polyurethane graft (Cellspan esophageal implant [CEI]) can facilitate esophageal regrowth and regeneration. To this end, a patient requiring a full circumferential esophageal segmental reconstruction after a complex multiorgan tumor resection was approved for an investigational treatment under the Food and Drug Administration Expanded Access Use (Investigational New Drug 17402). METHODS: Autologous adipose-derived mesenchymal stromal cells (Ad-MSCs) were isolated from the Emergency Investigational New Drug patient approximately 4 weeks before surgery from an adipose tissue biopsy specimen. The Ad-MSCs were grown and expanded under current Good Manufacturing Practice manufacturing conditions. The cells were then seeded onto a polyurethane fiber mesh scaffold (Cellspan scaffold) and cultured in a custom bioreactor to manufacture the final CEI graft. The cell-seeded scaffold was then shipped to the surgical site for surgical implantation. After removal of a tumor mass and a full circumferential 4 cm segment of the esophagus that was invaded by the tumor, the CEI was implanted by suturing the tubular CEI graft to both ends of the remaining native esophagus using end-to-end anastomosis. RESULTS: In this case report, we found that a clinical-grade, tissue-engineered esophageal graft can be used for segmental esophageal reconstruction in a human patient. This report reveals that the graft supports regeneration of the esophageal conduit. Histologic analysis of the tissue postmortem, 7.5 months after the implantation procedure, revealed complete luminal epithelialization and partial esophageal tissue regeneration. CONCLUSIONS: Autologous Ad-MSC seeded onto a tubular CEI tissue-engineered graft stimulates tissue regeneration following implantation after a full circumferential esophageal resection.

First lung and kidney multi-organ transplant following COVID-19 Infection.

As the world responds to the global crisis of the COVID-19 pandemic an increasing number of patients are experiencing increased morbidity as a result of multi-organ involvement. Of these, a small proportion will progress to end-stage lung disease, become dialysis dependent, or both. Herein, we describe the first reported case of a successful combined lung and kidney transplantation in a patient with COVID-19. Lung transplantation, isolated or combined with other organs, is feasible and should be considered for select patients impacted by this deadly disease.

A multilayer scaffold design with spatial arrangement of cells to modulate esophageal tissue growth.

Esophageal diseases may require resectioning of the damaged portion. The current standard of care requires the replacement of the esophagus with the stomach or the intestine. Such procedures have high rates of mortality and morbidity; therefore, the use of alternative conduits is needed. A tissue engineering approach that allows for the regeneration of esophageal tissues would have significant clinical application. A cell-seeded synthetic scaffold could replace the resected part of the esophagus and elicit tissue regrowth. In order to ideally recreate a functioning esophagus, its two crucial tissue layers should be induced: an epithelium on the luminal surface and a muscle layer on the exterior surface. To create a bioengineered esophagus with both tissue layers, a multilayer (ML) tubular scaffold design was considered. Luminal and exterior layers were electrospun with broad pore size to promote penetration and proliferation of mesenchymal stem cells on the lumen and smooth muscle cells on the external. These two layers would be separated by a thin layer with substantially narrower pore size intended to act as a barrier for the two cell types. This ML scaffold design was achieved via electrospinning by tuning the solution and the process parameters. Analysis of the scaffold demonstrated that this tuning enabled the production of three integrated layers with distinguishable microstructures and good mechanical integrity. In vitro validation was conducted on the separated unilayer components of the ML scaffold. The resultant proof-of-concept ML scaffold design could possibly support the spatial arrangement of cells needed to promote esophageal tissue regeneration. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 107B: 324-331, 2019.

Production and transplantation of bioengineered lung into a large-animal model.

The inability to produce perfusable microvasculature networks capable of supporting tissue survival and of withstanding physiological pressures without leakage is a fundamental problem facing the field of tissue engineering. Microvasculature is critically important for production of bioengineered lung (BEL), which requires systemic circulation to support tissue survival and coordination of circulatory and respiratory systems to ensure proper gas exchange. To advance our understanding of vascularization after bioengineered organ transplantation, we produced and transplanted BEL without creation of a pulmonary artery anastomosis in a porcine model. A single pneumonectomy, performed 1 month before BEL implantation, provided the source of autologous cells used to bioengineer the organ on an acellular lung scaffold. During 30 days of bioreactor culture, we facilitated systemic vessel development using growth factor-loaded microparticles. We evaluated recipient survival, autograft (BEL) vascular and parenchymal tissue development, graft rejection, and microbiome reestablishment in autografted animals 10 hours, 2 weeks, 1 month, and 2 months after transplant. BEL became well vascularized as early as 2 weeks after transplant, and formation of alveolar tissue was observed in all animals (n = 4). There was no indication of transplant rejection. BEL continued to develop after transplant and did not require addition of exogenous growth factors to drive cell proliferation or lung and vascular tissue development. The sterile BEL was seeded and colonized by the bacterial community of the native lung.

Long-term regeneration and remodeling of the pig esophagus after circumferential resection using a retrievable synthetic scaffold carrying autologous cells.

Treatment of esophageal disease can necessitate resection and reconstruction of the esophagus. Current reconstruction approaches are limited to utilization of an autologous conduit such as stomach, small bowel, or colon. A tissue engineered construct providing an alternative for esophageal replacement in circumferential, full thickness resection would have significant clinical applications. In the current study, we demonstrate that regeneration of esophageal tissue is feasible and reproducible in a large animal model using synthetic polyurethane electro-spun grafts seeded with autologous adipose-derived mesenchymal stem cells (aMSCs) and a disposable bioreactor. The scaffolds were not incorporated into the regrown esophageal tissue and were retrieved endoscopically. Animals underwent adipose tissue biopsy to harvest and expand autologous aMSCs for seeding on electro-spun polyurethane conduits in a bioreactor. Anesthetized pigs underwent full thickness circumferential resection of the mid-lower thoracic esophagus followed by implantation of the cell seeded scaffold. Results from these animals showed gradual structural regrowth of endogenous esophageal tissue, including squamous esophageal mucosa, submucosa, and smooth muscle layers with blood vessel formation. Scaffolds carrying autologous adipose-derived mesenchymal stem cells may provide an alternative to the use of a gastro-intestinal conduit for some patients following resection of the esophagus.

Giving new life to old lungs: methods to produce and assess whole human paediatric bioengineered lungs.

We report, for the first time, the development of an organ culture system and protocols to support recellularization of whole acellular (AC) human paediatric lung scaffolds. The protocol for paediatric lung recellularization was developed using human transformed or immortalized cell lines and single human AC lung scaffolds. Using these surrogate cell populations, we identified cell number requirements, cell type and order of cell installations, flow rates and bioreactor management methods necessary for bioengineering whole lungs. Following the development of appropriate cell installation protocols, paediatric AC scaffolds were recellularized using primary lung alveolar epithelial cells (AECs), vascular cells and tracheal/bronchial cells isolated from discarded human adult lungs. Bioengineered paediatric lungs were shown to contain well-developed vascular, respiratory epithelial and lung tissue, with evidence of alveolar-capillary junction formation. Types I and II AECs were found thoughout the paediatric lungs. Furthermore, surfactant protein-C and -D and collagen I were produced in the bioengineered lungs, which resulted in normal lung compliance measurements. Although this is a first step in the process of developing tissues for transplantation, this study demonstrates the feasibility of producing bioengineered lungs for clinical use. Copyright © 2016 John Wiley & Sons, Ltd.

Silencing of Tumor Necrosis Factor Receptor-1 in Human Lung Microvascular Endothelial Cells Using Particle Platforms for siRNA Delivery.

Acute lung injury (ALI) and its most severe manifestation, acute respiratory distress syndrome (ARDS), is a clinical syndrome defined by acute hypoxemic respiratory failure and bilateral pulmonary infiltrates consistent with edema. In-hospital mortality is 38.5% for AL, and 41.1% for ARDS. Activation of alveolar macrophages in the donor lung causes the release of pro-inflammatory chemokines and cytokines, such as TNF-α. To determine the relevance of TNF-α in disrupting bronchial endothelial cell function, we stimulated human THP-1 macrophages with lipopolysaccharide (LPS) and used the resulting cytokine-supplemented media to disrupt normal endothelial cell functions. Endothelial tube formation was disrupted in the presence of LPS-activated THP- 1 conditioned media, with reversal of the effect occurring in the presence of 0.1µg/ml Enbrel, indicating that TNF-α was the major serum component inhibiting endothelial tube formation. To facilitate lung conditioning, we tested liposomal and porous silicon (pSi) delivery systems for their ability to selectively silence TNFR1 using siRNA technology. Of the three types of liposomes tested, only cationic liposomes had substantial endothelial uptake, with human cells taking up 10-fold more liposomes than their pig counterparts; however, non-specific cellular activation prohibited their use as immunosuppressive agents. On the other hand, pSi microparticles enabled the accumulation of large amounts of siRNA in endothelial cells compared to standard transfection with Lipofectamine(®) LTX, in the absence of non-specific activation of endothelia. Silencing of TNFR1 decreased TNF-α mediated inhibition of endothelial tube formation, as well as TNF-α-induced upregulation of ICAM-1, VCAM, and E-selection in human lung microvascular endothelial cells.

Enhanced gene delivery in porcine vasculature tissue following incorporation of adeno-associated virus nanoparticles into porous silicon microparticles.

There is an unmet clinical need to increase lung transplant successes, patient satisfaction and to improve mortality rates. We offer the development of a nanovector-based solution that will reduce the incidence of lung ischemic reperfusion injury (IRI) leading to graft organ failure through the successful ex vivo treatment of the lung prior to transplantation. The innovation is in the integrated application of our novel porous silicon (pSi) microparticles carrying adeno-associated virus (AAV) nanoparticles, and the use of our ex vivo lung perfusion/ventilation system for the modulation of pro-inflammatory cytokines initiated by ischemic pulmonary conditions prior to organ transplant that often lead to complications. Gene delivery of anti-inflammatory agents to combat the inflammatory cascade may be a promising approach to prevent IRI following lung transplantation. The rationale for the device is that the microparticle will deliver a large payload of virus to cells and serve to protect the AAV from immune recognition. The microparticle-nanoparticle hybrid device was tested both in vitro on cell monolayers and ex vivo using either porcine venous tissue or a pig lung transplantation model, which recapitulates pulmonary IRI that occurs clinically post-transplantation. Remarkably, loading AAV vectors into pSi microparticles increases gene delivery to otherwise non-permissive endothelial cells.

Multipotent adult progenitor cells decrease cold ischemic injury in ex vivo perfused human lungs: an initial pilot and feasibility study.

BACKGROUND: Primary graft dysfunction (PGD) is a significant cause of early morbidity and mortality following lung transplantation. Improved organ preservation techniques will decrease ischemia-reperfusion injury (IRI) contributing to PGD. Adult bone marrow-derived adherent stem cells, including mesenchymal stromal (stem) cells (MSCs) and multipotent adult progenitor cells (MAPCs), have potent anti-inflammatory actions, and we thus postulated that intratracheal MAPC administration during donor lung processing would decrease IRI. The goal of the study was therefore to determine if intratracheal MAPC instillation would decrease lung injury and inflammation in an ex vivo human lung explant model of prolonged cold storage and subsequent reperfusion. METHODS: Four donor lungs not utilized for transplant underwent 8 h of cold storage (4°C). Following rewarming for approximately 30 min, non-HLA-matched allogeneic MAPCs (1 × 10(7) MAPCs/lung) were bronchoscopically instilled into the left lower lobe (LLL) and vehicle comparably instilled into the right lower lobe (RLL). The lungs were then perfused and mechanically ventilated for 4 h and subsequently assessed for histologic injury and for inflammatory markers in bronchoalveolar lavage fluid (BALF) and lung tissue. RESULTS: All LLLs consistently demonstrated a significant decrease in histologic and BALF inflammation compared to vehicle-treated RLLs. CONCLUSIONS: These initial pilot studies suggest that use of non-HLA-matched allogeneic MAPCs during donor lung processing can decrease markers of cold ischemia-induced lung injury.

Production and assessment of decellularized pig and human lung scaffolds.

The authors have previously shown that acellular (AC) trachea-lung scaffolds can (1) be produced from natural rat lungs, (2) retain critical components of the extracellular matrix (ECM) such as collagen-1 and elastin, and (3) be used to produce lung tissue after recellularization with murine embryonic stem cells. The aim of this study was to produce large (porcine or human) AC lung scaffolds to determine the feasibility of producing scaffolds with potential clinical applicability. We report here the first attempt to produce AC pig or human trachea-lung scaffold. Using a combination of freezing and sodium dodecyl sulfate washes, pig trachea-lungs and human trachea-lungs were decellularized. Once decellularization was complete we evaluated the structural integrity of the AC lung scaffolds using bronchoscopy, multiphoton microscopy (MPM), assessment of the ECM utilizing immunocytochemistry and evaluation of mechanics through the use of pulmonary function tests (PFTs). Immunocytochemistry indicated that there was loss of collagen type IV and laminin in the AC lung scaffold, but retention of collagen-1, elastin, and fibronectin in some regions. MPM scoring was also used to examine the AC lung scaffold ECM structure and to evaluate the amount of collagen I in normal and AC lung. MPM was used to examine the physical arrangement of collagen-1 and elastin in the pleura, distal lung, lung borders, and trachea or bronchi. MPM and bronchoscopy of trachea and lung tissues showed that no cells or cell debris remained in the AC scaffolds. PFT measurements of the trachea-lungs showed no relevant differences in peak pressure, dynamic or static compliance, and a nonrestricted flow pattern in AC compared to normal lungs. Although there were changes in content of collagen I and elastin this did not affect the mechanics of lung function as evidenced by normal PFT values. When repopulated with a variety of stem or adult cells including human adult primary alveolar epithelial type II cells both pig and human AC scaffolds supported cell attachment and cell viability. Examination of scaffolds produced using a variety of detergents indicated that detergent choice influenced human immune response in terms of T cell activation and chemokine production.

Nanotechnology and stem cell therapy for cardiovascular diseases: potential applications.

The use of stem cell therapy for the treatment of cardiovascular diseases has generated significant interest in recent years. Limitations to the clinical application of this therapy center on issues of stem cell delivery, engraftment, and fate. Nanotechnology-based cell labeling and imaging techniques facilitate stem cell tracking and engraftment studies. Nanotechnology also brings exciting new opportunities to translational stem cell research as it enables the controlled engineering of nanoparticles and nanomaterials that can properly relate to the physical scale of cell-cell and cell-niche interactions. This review summarizes the most relevant potential applications of nanoscale technologies to the field of stem cell therapy for the treatment of cardiovascular diseases.

Experience of sternal secondary closure by means of a titanium fixation system after transverse thoracosternotomy.

Sternal dehiscence is a common complication after transverse thoracosternotomy in patients undergoing bilateral sequential lung transplantation (BSLT). These patients can be treated with conservative therapy, but severe dehiscence requires surgical reapproximation and secondary closure of the sternum. Seventy-one cases of patients who underwent BSLT between January 2007 and May 2009 were reviewed retrospectively. Out of 71 patients, the sternum was intact in two cases due to the use of bilateral anterolateral thoracotomy, and a clamshell incision had been utilized in 69 patients. Four patients (6.8%) presented with persistent chest pain with severe sternal dehiscence diagnosed by chest X-ray and/or chest computed tomography, and underwent sternal reapproximation using the Synthes Titanium Sternal Fixation System for longitudinal sternal plating. All four patients had successful sternal realignment and resolution of their preoperative clinical symptoms. No perioperative or postoperative complications were observed. The Synthes Titanium Sternal Fixation System is an appropriate and effective method for internal fixation of the sternum when used for symptomatic severe sternal dehiscence after sequential BSLT via transverse thoracosternotomy.

Selective and self-guided micro-ablation of tissue with plasmonic nanobubbles.

BACKGROUND: The accuracy, selectivity, and safety of surgical and laser methods for tissue elimination are often limited at microscale. MATERIALS AND METHODS: We developed a novel agent, the plasmonic nanobubble (PNB), for optically guided selective elimination of the target tissue with micrometer precision. PNBs were tested in vitro in the two different models of superficial tumors and vascular plaques. RESULTS: PNBs were selectively generated around gold nanoparticles (delivered to the target tissues) with short laser pulses. Monolayers of cancerous cells and atherosclerotic plaque tissue were eliminated with PNBs with micrometer accuracy and without thermal and mechanical damage to collateral normal tissues. The effect of the PNB was dynamically controlled through the fluence of laser pulses (532 nm, duration 0.5 and 10 ns) and was guided through the optical scattering by PNB. CONCLUSIONS: Plasmonic nanobubbles were shown to provide precise, tunable, selective, and guided ablation of tissue at a microscopic level and could be employed as a new generation of surgical tools.

Techniques and complications of TandemHeart ventricular assist device insertion during cardiac procedures.

Patients with heart failure and profound cardiogenic shock, who are unresponsive to vasopressors and intra-aortic balloon pump insertion, have few options except for mechanical cardiac support with a ventricular assist device. The TandemHeart is a new assist device that may be percutaneously or surgically inserted. We review techniques for percutaneous and intraoperative placement of the TandemHeart, including detailed descriptions of its insertion. Additionally, we present the most common complications associated with the percutaneous or operative approaches and suggest ways to avoid these complications. Whether placed percutaneously or surgically, the TandemHeart can provide adequate hemodynamic support for heart failure patients. If the device is placed by surgeons in the operating room, there must be strict adherence to protocols and de-airing techniques. Complications may occur with either insertion technique, so knowledge of the most common types of complications and their prevention is necessary.

The TandemHeart as a bridge to a long-term axial-flow left ventricular assist device (bridge to bridge).

End-stage heart-failure patients in acute refractory cardiogenic shock with multi-organ dysfunction require aggressive medical therapy that includes inotropic support. Historically, the intra-aortic balloon pump was the last option for patients who were dying of acute cardiogenic shock. Short-term extracorporeal pulsatile or nonpulsatile cardiac assist devices or extracorporeal membrane oxygenation offered further treatment options; however, these therapies required invasive surgical procedures. Patients in this high-risk group had increased mortality rates from major procedures that required cardiopulmonary bypass. We used the TandemHeart, a percutaneously implanted device for short-term cardiac assistance, to lower the risk of death and improve hemodynamic performance and end-organ perfusion before implanting long-term assist devices in selected patients with signs of profound cardiogenic shock. Nine end-stage heart-failure patients (mean age, 37.7 yr) in acute refractory hemodynamic decompensation received a percutaneously implanted TandemHeart pump as a bridge to an implantable axial-flow pump. To determine the relative risk for these patients, prognostic scores were calculated before and after insertion of the TandemHeart. Percutaneous support times ranged from 1 to 22 days (mean, 5.9 d). The mean cardiac index before support, 1.02 L/(min.m2) (range, 0.0-1.8 L/[min.m2]) (0.0 L/[min.m2] implies active cardiopulmonary resuscitation), improved to 2.97 L/(min.m2) (range, 2.2-4.0 L/[min.m2]) during support. Three patients underwent successful cardiac transplantation; 5 are currently supported by axial-flow pumps; and 1 died of complications unrelated to the axial-flow pump, after 587 days. End-organ function and overall condition improved uniformly in our patients, thus decreasing the preoperative risk factors for implantation of the long-term device.

CentriMag left ventricular assist system: cannulation through a right minithoracotomy.

The CentriMag left ventricular assist system can be used for perioperative or postcardiotomy circulatory support of the failing heart. The device resides at the patient's bedside, and the cannulae are usually inserted through a midline sternotomy, with the inflow cannula in the left ventricle or right superior pulmonary vein and the outflow cannula in the aorta. In a patient whose chest has been closed and who has a delayed need for temporary mechanical support, a less invasive method of left ventricular assist device cannula insertion is preferred. In these cases, the CentriMag cannulae can be inserted through a right minithoracotomy with the inflow cannula in the right superior pulmonary vein and the outflow cannula in the aorta, with no heparinization. Herein, we describe this approach in a patient who experienced postcardiotomy cardiogenic shock after aortocoronary bypass surgery. This technique may facilitate ambulation and recovery in selected patients.

A less invasive approach to axial flow pump insertion.

BACKGROUND: Implantation of a HeartMate II or a Jarvik 2000 FlowMaker left ventricular assist system (LVAS) usually involves a mid-line sternotomy and the use of cardiopulmonary bypass (CPB). In patients with numerous co-morbid conditions, however, surgical trauma may be minimized by implanting the LVAS via a minimally invasive approach, preferably without CPB. METHODS: In 6 patients with end-stage heart failure and other serious co-morbidities, we implanted a HeartMate II (n = 3) or a Jarvik 2000 FlowMaker (n = 3) LVAS via a right mini-thoracotomy and a left sub-costal incision. Patients included 3 men and 3 women with a mean age of 41 years. In 3 cases, the LVAS was implanted without CPB. RESULTS: After a mean follow-up period of 6 months, 5 patients are alive and well and on the transplant waiting list. Seven months after LVAS implantation, the remaining patient developed a hemorrhagic stroke necessitating Jarvik 2000 replacement with a new pump of the same type. CONCLUSIONS: In this small series, the combined sub-costal and mini-thoracotomy incision proved safe and technically feasible. It may be useful for other LVAS candidates who have serious co-morbidities that preclude traditional implant operations.

Clinical experience with sternotomy versus subcostal approach for exchange of the HeartMate XVE to the HeartMate II ventricular assist device.

BACKGROUND: Most patients undergoing destination therapy with a HeartMate XVE left ventricular assist device will eventually require pump exchange to continue long-term cardiac support. METHODS: To determine whether left ventricular assist device exchange can be accomplished with low morbidity and mortality, we retrospectively reviewed the records of 14 patients who experienced pump malfunction and subsequently required replacement of their HeartMate XVE left ventricular assist devices with HeartMate II axial-flow pumps. We collected data regarding duration of support and reasons for pump failure, perioperative characteristics, and operative approach. RESULTS: On average, patients were supported 473 +/- 233 days with HeartMate XVE pumps. Seven early patients required both subcostal and sternotomy incisions; 7 later patients had subcostal incisions only. Thirteen patients underwent successful exchange to the HeartMate II; 1 patient died in the operating room. Another patient died in the perioperative period (30-day mortality, 14% [2 of 14]). There were significant differences between the two groups. The patients who required only subcostal incisions had shorter operative times (187 versus 220 minutes; p = 0.04) and required fewer transfused blood products (packed red blood cells, 8.6 versus 28.7 units; p = 0.03; and fresh-frozen plasma, 12.4 versus 30.9 units; p = 0.04). Additionally, the patients with subcostal incisions had shorter postoperative intensive care unit stays (5.3 +/- 1.1 versus 8.4 +/- 3.1 days for redo sternotomy patients; p = 0.03). Of the survivors, average hospital stay was 22 +/- 14 days. Average long-term follow-up was 11.2 +/- 7.8 months; 71% (10 of 14) of patients are currently alive. CONCLUSIONS: Exchange of a HeartMate XVE to a HeartMate II can be accomplished with relatively low morbidity and mortality through a subcostal approach.

Clinical experience with the TandemHeart percutaneous ventricular assist device as a bridge to cardiac transplantation.

Cardiac support with a ventricular assist device is among the few treatments for heart-failure patients who have profound cardiogenic shock unresponsive to vasopressors and intra-aortic balloon pumps. The TandemHeart percutaneous ventricular assist device can provide temporary support until another device can be placed or a donor heart becomes available. We examined the TandemHeart's effect on cardiac index, central venous pressure, mixed venous oxygen saturation, creatinine, mean arterial pressure, urine output, and 30-day mortality rate in 5 heart-failure patients (2 with nonischemic and 3 with ischemic cardiomyopathy; mean preoperative left ventricular ejection fraction, 0.17 +/- 0.056). Two patients were undergoing cardiopulmonary resuscitation when the device was inserted. The average duration of TandemHeart support was 7.6 +/- 3.2 days; all patients were successfully bridged to transplantation. The TandemHeart improved the cardiac index (1.9 +/- 0.3 vs 3.5 +/- 0.8 L/[min.m2], P= 0.01), mean arterial pressure (69 +/- 12.5 vs 91 +/- 4.3 mmHg, P=0.009), mixed venous oxygen saturation (45.4 +/- 14.3 vs 71.4 +/- 7.5, P=0.009), and urine output (1,861 +/- 988 vs 4,314 +/- 1,346 mL/hr, P=0.01). The device decreased central venous pressure (21.2 +/- 7.4 vs 12.8 +/- 5.9 mmHg, P=0.02) and pressor requirements (2.4 +/- 1.1 vs 1.0 +/- 0.7 agents, P=0.02). Average long-term follow-up after heart transplantation was 8.4 +/- 9.9 months, with no deaths. We conclude that the TandemHeart can provide hemodynamic support for patients with profound, refractory cardiogenic shock. Furthermore, the device can bridge patients to cardiac transplantation and can be placed percutaneously, without invasive surgery.