Endocarditis in Bovine Vein Grafts in the Pulmonary Position Placed Surgically & Percutaneously.

Background: Infective endocarditis (IE) is one of the major complications following pulmonary valve replacement (PVR). This analysis hopes to evaluate the incidence, outcomes and possible risk factors of IE associated with trans-catheter and surgical placement of a bovine jugular vein (BJV) graft in the pulmonary position. Methods: In this single-center retrospective study, all records of trans-catheter and surgical PVR from 3/2010 to 12/2019 were reviewed. IE was defined as positive blood cultures, with vegetations seen on echocardiography or sudden increase in peak gradient across the valve or vegetations confirmed at time of valve replacement. Poor dental hygiene:1.dental procedures without S.B.E prophylaxis AND/OR 2.one or more dental cavities, caries, dental abscess. Results: 165 patients had PVR with BJV:107 trans-catheter and 63 surgical. 7%(12/170) of PVRs developed IE(catheter:n = 10, surgery:n = 2) at a median time from valve placement of 38 months. The incidence of IE in the catheter group:3-per-100patient-years and in surgical group:1-per-100patient-years. Multivariate cox regression showed that poor dental hygiene was significantly associated with IE [HR(95% CI):16.9(4.35-66.2)](p value <.001). Kaplan-Meier curves showed a significant difference in freedom from IE between patients with poor and appropriate dental hygiene (p value<.001). Conclusions: There is a 7% incidence of IE with the use of BJV grafts in the pulmonary position at mid-term follow-up. Though the rate in catheter placed BJV seems 3x higher than surgically placed ones, their cohorts are quite different making this comparison flawed. Poor dental hygiene is a strong predictor for post-operative IE and offers a significant opportunity for lowering the rate of infective endocarditis.

Children who stroke on VAD support: When is it safe to transplant and what are their outcomes?

OBJECTIVE: Ventricular assist devices (VADs) increase waitlist survival, yet the risk of stroke remains notable. The purpose of this study was to analyze how strokes on VAD support impact post-transplant (post-Tx) outcomes in children. METHODS: About 520 pediatric (<18 years) heart transplant candidates listed from January 2011 to April 2018 with a VAD implant date were matched between the United Network of Organ Sharing and Pediatric Health Information System databases. Patients were divided into pre-Tx Stroke and No Stroke cohorts. RESULTS: About 81% of the 520 patients were transplanted; 28% (n = 146) had a pre-Tx Stroke; and 59% (n = 89) of the Stroke patients were transplanted at a median of 57 (IQR 17-102) days from stroke. Significantly more No Stroke cohort (90%) were transplanted (p < 0.001). There was no difference in post-Tx survival between the Stroke and No Stroke cohorts (p = 0.440). Time between stroke and transplant for patients who died within 1 year of transplant was 32.0 days (median) compared to 60.5 days for those alive >1 year (p = 0.18). Regarding patients in whom time from stroke to transplant was more than 60 days, one-year survival of Stroke vs. No Stroke patients was 96% vs. 95% (p = 0.811), respectively. CONCLUSION: Patients with stroke during VAD support, once transplanted, enjoy similar survival compared to No Stroke patients. We hypothesize that allowing Stroke patients more time to recover could improve post-Tx outcomes. Unfortunately, the ideal duration of time between stroke and safe transplantation could not be determined and will require more detailed and larger studies in the future.

More Than 400 Uses of an Intestinal Submucosal Extracellular Matrix Patch in a Congenital Heart Program.

BACKGROUND: Repair of complex congenital heart disease frequently requires use of a patch as an anatomic substitute. The study's aim is to evaluate the use, effectiveness, and safety of using small intestine submucosal extracellular matrix (SIS-ECM) patches in a congenital cardiac surgery program. METHODS: This is a single-center, retrospective, cohort study of surgeries using SIS-ECM between 2012 and 2019. The SIS-ECM data were categorized by use and type (four-ply and two-ply). All reinterventions and complications were reviewed by an independent surgeon, a practicing congenital heart surgeon, and a pediatric cardiologist. RESULTS: In all, 408 SIS-ECM patches were used in 309 patients (188 male, 121 female; median age 8.5 months). Use of the patches consisted of 314 arterioplasties (77%), 22 venoplasties (5.4%), 63 intracardiac repairs (15.4%), and 9 valve repairs (2.2%). The most common use was for pulmonary artery repair (n = 181; 44.4%). Median follow-up time was 3.9 years (range, 3 days to 7.4 years). Ten patches (2.5%) required surgical reintervention (2 in the first 30 days and 5 in the first year) and 27 (6.6%) required percutaneous reinterventions (2 in the first 30 days and 22 in the first year). Between four-ply (n = 376) and two-ply (n = 32) SIS-ECM, the rate of surgical (2.1% [n = 8] vs 6.3% [n = 2], P = .18) or percutaneous reinterventions (6.4% [n = 24] vs 9.4% [n = 3], P = .46) was not different. There were no deaths related to the SIS-ECM patch or reports of calcification. CONCLUSIONS: The SIS-ECM is a viable patch option that can be used in various cardiac and vascular reconstructive surgeries with low risk of failure and calcification. Long-term, positive outcomes may be maximized by using consistent techniques and understanding the appropriate applications of the patch.

Modelling Human Physiology on-Chip: Historical Perspectives and Future Directions.

For centuries, animal experiments have contributed much to our understanding of mechanisms of human disease, but their value in predicting the effectiveness of drug treatments in the clinic has remained controversial. Animal models, including genetically modified ones and experimentally induced pathologies, often do not accurately reflect disease in humans, and therefore do not predict with sufficient certainty what will happen in humans. Organ-on-chip (OOC) technology and bioengineered tissues have emerged as promising alternatives to traditional animal testing for a wide range of applications in biological defence, drug discovery and development, and precision medicine, offering a potential alternative. Recent technological breakthroughs in stem cell and organoid biology, OOC technology, and 3D bioprinting have all contributed to a tremendous progress in our ability to design, assemble and manufacture living organ biomimetic systems that more accurately reflect the structural and functional characteristics of human tissue in vitro, and enable improved predictions of human responses to drugs and environmental stimuli. Here, we provide a historical perspective on the evolution of the field of bioengineering, focusing on the most salient milestones that enabled control of internal and external cell microenvironment. We introduce the concepts of OOCs and Microphysiological systems (MPSs), review various chip designs and microfabrication methods used to construct OOCs, focusing on blood-brain barrier as an example, and discuss existing challenges and limitations. Finally, we provide an overview on emerging strategies for 3D bioprinting of MPSs and comment on the potential role of these devices in precision medicine.