Sebastian Stefaniak

Predictive factors of late venous aortocoronary graft failure: ultrastructural studies.

Background Venous aortocoronary graft arterialization may precede a preterm occlusion in some coronary artery bypass grafting (CABG) patients. The aim of the present study was to identify ultrastructural variations in the saphenous vein wall that may have an impact on the development of venous graft disease in CABG patients. Methods The study involved 365 consecutive patients with a mean age of 62.9±9.4 years who underwent isolated CABG. The thickness and area of the whole venous wall, the tunica intima, the tunica media and the adventitia and the number and shape (length, thickness and length/thickness ratio) of the nuclei in the medial smooth muscle cells nuclei in the distal saphenous vein segments were evaluated by ultrastructural studies. Patients were followed up for 41 to 50 months (mean 45.1±5.1). Saphenous vein graft patency was assessed by follow-up coronary angiography. Logistic regression models were used to identify independent risk factors for late graft failure. Results In 71 patients significant lesions in the saphenous vein grafts were observed. The whole venous wall thickness (437.5 µm vs. 405.5 µm), tunica media thickness (257.2 µm vs. 211.5 µm), whole venous wall area (2.23 mm2 vs. 2.02 mm2) and tunica media area (1.09 mm2 vs. 0.93 mm2) were significantly larger for this group of patients than for those without graft disease. In the latter group more elongated smooth muscle cell nuclei (higher length/thickness ratio) were found in the tunica media of the saphenous vein segments. Thickening of the saphenous vein tunica media and chunky smooth muscle cell nuclei were identified as independent risk factors for graft disease development. Conclusions Saphenous vein tunica media hypertrophy (resulting in wall thickening) and chunky smooth muscle cell nuclei might predict the development of venous graft disease.

The role of simulation to support donation after circulatory death with extracorporeal membrane oxygenation (DCD-ECMO)

Maintaining the viability of organs from donors after circulatory death (DCD) for transplantation is a complicated procedure, from a time perspective in the absence of appropriate organizational capabilities, that makes such transplantation cases difficult and not yet widespread in Poland. We present the procedural preparation for Poland’s first case of organ (kidney) transplantation from a DCD donor in which perfusion was supported by extracorporeal membrane oxygenation (ECMO). Because this organizational model is complex and expensive, we used advanced high-fidelity medical simulation to prepare for the real-life implementation. The real time scenario included all crucial steps: prehospital identification, cardiopulmonary resuscitation (CPR), advanced life support (ALS); perfusion therapy (CPR-ECMO or DCD-ECMO); inclusion and exclusion criteria matching, suitability for automated chest compression; DCD confirmation and donor authorization, ECMO organs recovery; kidney harvesting. The success of our first simulated DCD-ECMO procedure in Poland is reassuring. Soon after this simulation, Maastricht category II DCD procedures were performed, involving real patients and resulting in two successful double kidney transplantations. During debriefing, it was found that the previous simulation-based training provided the experience to build a successful procedural chain, to eliminate errors at the stage of identification, notification, transportation, donor qualifications and ECMO organ perfusion to create DCD-ECMO algorithm architecture.

Customization of a patient simulator for ECMO training

Background: Poland is setting up its first regional ECMO program and relies heavily on the use of simulation in testing processes and training clinicians.1 As ECMO is a complex and expensive procedure, we developed an advanced ECMO simulator for high-fidelity medical simulation training.2–6 It can be used to modify any type of full-body patient simulator and allows for the creation of an unlimited number of scenarios. Methods: The system is equipped with an electronic core control unit (CCU) (Figure 1), a set of synthetic valves, pressure sensors, and hydraulic pumps. The major functions of the CCU are to stabilize the hydraulic system (flow of simulated blood, differential pressures in the arterial and venous lines), providing instant information about the system to the user via a display. Electric valves and sensors provide ‘on-the-fly’ information to the CCU about the actual systems status and it can be made to respond to specific instructions imitating the physiological circulatory system and simulating several scenarios (i.e. bleeding, low pressure, occlusion, reaction to proper and incorrect pharmacological treatment). It can be connected to an ECMO machine to act like the human body during ECMO run. Silicone tubes (modified polyethylene) that can be realistically cannulated using ultrasound imaging represent the artificial vessels. The CCU is made of electronic components that can be integrated to customize any mannequin as shown in Figure 1. The hardware includes both digital and analogue components that are controlled by a software run on a computer connected to the CCU via a serial port (RS232) (Figure 2). The software allows for the visualization of measurements obtained from the sensors and the control of the pumps and valves via electronic controllers. The controllers affect the ECMO circuit simulated blood flow, and hence the readings from the ECMO machine sensors, to recreate various clinical scenarios.Figure 1. The modified patient simulator with circulatory loop prepared for VA ECMO cannulation and CCU (core control unit) for high-fidelity simulations. Figure 2. The ECMO simulator architecture. Results: Every component used can be easily replaced. The total cost of the simulator modification, excluding the cost of the computer or future mobile device, is approximately 200 USD, and the consumable parts cost about 20 USD. It has been used to help simulate successfully a range of scenarios.1 Although the system is currently tethered, the next prototype will include a wireless controller so that the system can be controlled from a mobile application. Conclusions: This advanced simulator allows for unlimited possibilities with regard to creating clinical scenarios. Our ambition is to become a reference ECMO training center in Poland so that our high-fidelity ECMO simulator can be used to its full potential and for the benefit of more clinicians and their patients around Poland.

Using simulation to create a unique regional ECMO program for the Greater Poland region

Background: “ECMO for Greater Poland” is a program being developed to serve the 3.5 million inhabitants of the Greater Poland region (Wielkopolska) based on an approach already implemented in the USA1 or Qatar.2,3Method: The program is complex and takes full advantage of the ECMO perfusion therapy opportunities to save the life of patients in the Greater Poland region. The main implementation areas are: – treatment of patients with hypothermia;4 – treatment of reversible severe respiratory failure;5 – treatment of acute intoxication resulting in cardiorespiratory failure6 or other critical conditions resulting in heart failure; – in the absence of response to treatment and eventual death, and with donor authorization, there is possible organ transplantation from a non-heart beating donor (NHBD) to another patient.7 This led to the development of a program for donation after circulatory death (DCD). Study: The program will help to put in place a Medical Rescue System including ECMO (Figure 1). It requires training in specialized resuscitation, perfusion, and transplantation teams in the implementation of this “ECMO rescue chain”. The main strength of the program is the widespread use of extracorporeal perfusion. All program arms in the use of ECMO should be implemented in parallel to maximize its positive impact.Figure 1. Organizational model of “ECMO for Greater Poland” – “ECMO rescue chain” scheme divided into three stages: prehospital, hospital/perfusion, and transplantation. As this organizational model is complex and expensive, we used high-fidelity medical simulation to prepare for the real-life implementation of our ECMO program. During 4 months, we performed scenarios including: – “ECMO for DCD” which includes: prehospital identification, CPR ALS (cardiopulmonary resuscitation advanced life support), perfusion therapy (CPR-ECMO or DCD-ECMO), inclusion and exclusion criteria matching, mechanical chest compression, transport, DCD confirmation, and donor authorization, the veno-arterial (VA) cannulation of a mannequins artificial vessels, and starting on-scene organ perfusion.7 – “ECMO for INTOXICATION” which includes: hospital identification (Department of Toxicology), poisoning treatment, CPR ALS, mechanical chest compression, VA cannulation, for the implementation of ECMO therapy and transport to another hospital (Department of Cardiac Surgery).6 – “ECMO for RRF” (reversible respiratory failure) which includes: hospital identification (Regional Department of Intensive Care) – inclusion and exclusion criteria matching, ECMO team transport (80 km), therapy confirmation, veno-venous cannulation for the implementation of perfusion therapy, and return transport (80 km) with ECMO to another hospital in a provincial city (Clinical Department of Intensive Care), where the veno-venous (VV) ECMO therapy was continued for the next 48 hours.5 The training programs, in a short time, resulted in a team being appropriately trained to successfully undertake the complex procedures. Soon after these simulations, Maastricht category II DCD procedures were performed involving real patients and resulting in two double successful kidney transplantations, for the first time in Poland. One month later, we treated two hypothermia patients and, for the first time in the region, also treated on ECMO an adult patient with reversible respiratory failure. Conclusions: The “ECMO for Greater Poland” program will allow the use of perfusion therapy for the inhabitants of Wielkopolska in a comprehensive manner, covering all critical disease states, by what appears to be a unique regional program in Poland. The full-scale, high-fidelity simulation enabled standardized training and testing of new, commonly, and rarely used procedures, and facilitated clinicians’ skills development.

High-fidelity simulation — the first DCD-ECMO procedure in Poland

Mateusz Puslecki, Marcin Ligowski, Marek Dabrowski, Maciej Sip, Sebastian Stefaniak, Tomasz Klosiewicz, Lukasz Gasiorowski, Marek Karczewski, Tomasz Malkiewicz, Malgorzata Ladzinska, Marcin Zielinski, Aleksander Pawlak, Agata Dabrowska, Piotr Ziemak, Bartlomiej Perek, Marcin Misterski, Slawomir Katarzynski, Piotr Buczkowski, Wojciech Telec, Ilona Kiel-Puslecka, Michal Kiel, Michael Czekajlo, Marek Jemielity Poznan University of Medical Sciences, Department of Cardiac Surgery and Transplantology, Clinical Hospital SKPP, Poznan, Poland Poznan University of Medical Sciences, Department of Rescue and Disaster Medicine, Poznan, Poland Polish Society of Medical Simulation, Poland Poznan University of Medical Sciences, Center for Medical Simulation, Poznan, Poland Poznan University of Medical Sciences, Department of Intensive Care and Pain Treatment, Poznan, Poland Poznan University of Medical Sciences, Department of Transplantology, General, Vascular and Plastic Surgery, Poznan, Poland Poznan University of Medical Sciences, Department of Anesthesiology and Intensive Care, Clinical Hospital H. Święcickiego, Poznan, Poland Voivodeship Emergency Medical Services, Poznan, Poland Poznan University of Medical Sciences, Department of Palliative Medicine, Poznan, Poland ZF RTW, Częstochowa, Poland Hunter Holmes McGuire VA Medical Center, Department of Surgery, Richmond, United States of America Lublin Medical University, Lublin, Poland

Routine transfusion of platelet concentrates effectively reduces reoperation rate for bleeding and pericardial effusion after elective operations for ascending aortic aneurysm

Abstract Patients with ascending aortic aneurysm undergoing complex surgical procedures are at increased risk of early postoperative excessive blood loss. The aim of this study was to analyze safety and efficacy of routine transfusions of platelet (PLT) concentrates in reduction of hemorrhagic postoperative complications. The study involved 396 consecutive patients (289 males and 107 females) with the mean age of 55.9 ± 13.6 years who underwent elective operations for aortic aneurysms. They were divided retrospectively into two groups, without (group A; n = 123) or with the routine use of PLTs (group B; n = 273). PLTs were transfused intraoperatively just after completion of cardiopulmonary bypass. Twelve patients in group A (9.8%) and 10 (3.7%) in group B required re-thoracotomy due to hemorrhage (p = 0.027). Routine transfusions of PLT concentrates reduced postoperative incidence of excessive pericardial effusion from 24.1% in group A to 2.1% in group B (p = 0.002). In a consequence, significantly less units (p < 0.0001) of red blood concentrates and fresh frozen plasma were transfused in group B than in group A. The rates of other adverse events in the early postoperative period did not differ between groups. Patients with pericardial effusion required 6.3 ± 2.7 additional days of hospitalization due to surgical re-intervention. Neither blood transfusion-related infections nor adverse reactions were noted. In conclusion, routine intraoperative transfusions of PLT concentrates in patients with ascending aortic aneurysms significantly reduced a need for re-intervention due to both early bleeding and late cardiac tamponade.

Closure of ruptured aneurysm of the sinus of Valsalva using a native aortic valve leaflet.

We present a case of the native valve used to complete closure of a ruptured aneurysm of the sinus of Valsalva. Aneurysm of the sinus of Valsalva is rare and a non-coronary artery is affected in only 20% of cases. To close the rupture, we decided to use a non-coronary leaflet in a young patient with moderate aortic stenosis and fibrosis of the leaflets. In our opinion, use of a native non-coronary valve leaflet should be considered when making intra-operative decisions for repair of non-coronary aneurysm of the sinus of Valsalva.

Reconstructive Surgery of the Aortic Valve

Abstract Several techniques of aortic valve repair have been described. These procedures are usually performed in young and middle-aged rather low-risk individuals with severe aortic insufficiency. Unfortunately, they accounted for a minority of patients with aortic valve disease treated in adult cardiac surgical departments. Reconstructive procedures, due to their complexity and unknown long-term results, are performed only in the selected centers and by the most experienced cardiac surgeons. Although the middle-term outcomes are promising in the experienced hands, there are doubts if they will be applied commonly in the future. An exception may be Ozakis procedure that can be carried out even in patients with severe aortic stenosis with extent calcifications and concomitant disorders. However, it will have to compete with minimally invasive interventions.

Venoarterial extracorporeal membrane oxygenation in massive pulmonary embolism

Address for correspondence: Sebastian Stefaniak, MD, PhD, Department of Cardiac Surgery and Transplantology, Poznan University of Medical Sciences, ul. Długa 1/ 2, 61–848 Poznań, Poland, e-mail: seb.kos@gmail.com Conflict of interest: none declared Acknowledgements: The authors wish to thank Professor Guillaume Alinier and Doctor Bartłomiej Perek for their assistance. Kardiologia Polska Copyright

Personal resources and satisfaction with life in Marfan syndrome patients with aortic pathology and in abdominal aortic aneurysm patients

Introduction Whether or not the source of aortic pathology is Marfan syndrome (MFS) or other processes leading to development of abdominal aorta aneurysms (AAA), the awareness of pathology may lead to an emotional upset and low assessment of satisfaction with life. Aim To assess, in regard to MFS patients with aortic pathology and to abdominal aortic aneurysm patients: 1) whether or not self-efficacy (SE) and health locus of control (HLoC) affect the patients’ satisfaction with life; 2) whether the two groups of patients differ in terms of mental dispositions. Material and methods The study population consisted of 16 MFS patients with aortic pathology and 16 AAA patients, 9 men and 7 women in each group. The mean age of the MFS patients was 28.5 ±8.214, and of the AAA patients 64.25 ±7.019. The following scales were applied: Generalized Self-Efficacy Scale, Satisfaction With Life Scale, Multidimensional Health Locus of Control Scale. Results Abdominal aorta aneurysms patients compared to MFS patients gave a higher rating for SE (MD = 33.94 and MD = 29.56), internal health locus of control (MD = 25.00 and MD = 21.13), external personal HLoC (MD = 24.50 and MD = 19.25), external impersonal HLoC (MD = 23.06 and MD = 18.25), and satisfaction with life (M = 22.06 and M = 20.13). Internal and external HLoC were significantly lower in MFS patients compared to AAA patients. Conclusions In patients with aortic diseases, special attention must be paid to the state of personal resources (PR). Interactions made by medical professionals should focus on enhancing PR supporting the patients’ self-knowledge on their SE. This will help to improve their satisfaction with life and form a positive attitude to the illness.