BACKGROUND Persistent left superior vena cava(PLSVC),a relatively rare thoracic vascular malformation,can inconvenience perfusionists and operators when encountered during deep hypothermic circulatory arrest(DHCA).CAS...BACKGROUND Persistent left superior vena cava(PLSVC),a relatively rare thoracic vascular malformation,can inconvenience perfusionists and operators when encountered during deep hypothermic circulatory arrest(DHCA).CASE SUMMARY Herein,we describe the case of a patient with concurrent giant aortic arch aneurysm,aortic stenosis,and PLSVC.To treat these conditions,we performed right hemiarch and aortic valve replacements under DHCA.Notably,we applied“bilateral superior vena cava retrograde cerebral perfusion(RCP)”for cerebral protection,which significantly optimized the surgical procedure and reduced the risk of postoperative complications.The patient was discharged 14 d after surgery with no complications.CONCLUSION Surgical intervention for PLSVC under DHCA can be performed using the bilateral superior vena cava RCP approach.展开更多
Background Large animal cardiopulmonary bypass (CPB) models are expensive,and prevent assessment of neurocognitive function,and difficulties with long-term recovery.The purpose of this study was to establish a novel...Background Large animal cardiopulmonary bypass (CPB) models are expensive,and prevent assessment of neurocognitive function,and difficulties with long-term recovery.The purpose of this study was to establish a novel rat model of cardiopulmonary bypass for deep hypothermic circulatory arrest without blood priming.Methods Twenty adult male Sprague-Dawley rats weighing 450-560 g were randomized to CPB with deep hypothermic circulatory arrest (DHCA) and control groups,with 10 rats each.The experimental protocols,including blood and crystalloid fluid administration,anesthesia,orotracheal intubation,ventilation,cannulation,and heparinization were identical in both groups.After inducing cardiac arrest,the circuit was turned off and rats were left in a DHCA state for 15 minutes.Rats were rewarmed to 34℃ to 35℃ over a period of 36 to 42 minutes using CPB-assisted rewarming,a heating blanket,and a heating lamp along with administration of 0.1 mEq of sodium bicarbonate and 0.14 mEq of calcium chloride.The remaining priming volume was reinfused and animals were weaned from CPB.Results All CPB with DHCA processes were successfully achieved.Blood gas analysis and hemodynamic parameters were in the normal range.The vital signs of all rats were stable.Conclusions Our CPB circuit has several novel features,including a small priming volume,active cooling/rewarming processes,vacuum-assisted venous drainage,peripheral cannulation without thoracotomy or stemotomy,and an accurate means of monitoring peripheral tissue oxygenation.展开更多
Background: In clinical and basic science medicine, we often isolate ourselves in silos, unaware of developments in other related disciplines. Our team has had substantial experience, both in the operating room and in...Background: In clinical and basic science medicine, we often isolate ourselves in silos, unaware of developments in other related disciplines. Our team has had substantial experience, both in the operating room and in the laboratory, with protecting the brain and the spinal cord via hypothermia. Herein, we briefly share this experience with our colleagues in Neurology, eager for comments and advice from the neurologic perspective. Methods: 1) Clinical brain protection via deep hypothermic circulatory arrest (DHCA) for surgery of the aortic arch. For aortic arch replacement (performed for aortic arch aneurysm or aortic dissection), the aortic arch must be opened and native perfusion stopped. We have decades of experience in many hundreds of patients with this technique. This experience is reviewed. 2) Experimental protection of the spinal cord via cooling. We review our laboratory experience with a novel, recirculating cooling catheter for the vulnerable spinal cord. 3) Experimental protection of the brain via an intraventricular cooling catheter. We review our laboratory experience cooling the brain with a balloon-tipped catheter residing the lateral ventricles. Results: 1) Deep hypothermic circulatory arrest for aortic arch surgery provides superb brain protection for periods up to 45 minutes or longer. Clinical neurologic function, and quantitative neurologic tests, show excellent brain preservation. 2) The novel spinal cooling catheter provides excellent cooling of the spinal cord in a large animal model, without apparent injury of any type. 3) The intraventricular brain cooling catheter provides excellent cooling of the brain, documented by both direct temperature probe and high-tech brain imaging. Conclusions: We wish herein (in this article) to share this experience across our disciplines (Cardiac Surgery and Neurology). We welcome advice from the Neurology community on these surgically-directed methods for cooling and protection of neurological tissue in both the brain and the spinal cord.展开更多
基金Technology Innovation and Application Development Project of Chongqing,No.2021yc-cxfz30016.
文摘BACKGROUND Persistent left superior vena cava(PLSVC),a relatively rare thoracic vascular malformation,can inconvenience perfusionists and operators when encountered during deep hypothermic circulatory arrest(DHCA).CASE SUMMARY Herein,we describe the case of a patient with concurrent giant aortic arch aneurysm,aortic stenosis,and PLSVC.To treat these conditions,we performed right hemiarch and aortic valve replacements under DHCA.Notably,we applied“bilateral superior vena cava retrograde cerebral perfusion(RCP)”for cerebral protection,which significantly optimized the surgical procedure and reduced the risk of postoperative complications.The patient was discharged 14 d after surgery with no complications.CONCLUSION Surgical intervention for PLSVC under DHCA can be performed using the bilateral superior vena cava RCP approach.
基金This study was supported by grants from the National Natural Science Foundation of China (No.81371443),Beijing Natural Science Foundation (No.7142137,No.7122056 and No.7142049),Basic and Clinical Cooperation Project of Capital Medical University (No.13JL26).
文摘Background Large animal cardiopulmonary bypass (CPB) models are expensive,and prevent assessment of neurocognitive function,and difficulties with long-term recovery.The purpose of this study was to establish a novel rat model of cardiopulmonary bypass for deep hypothermic circulatory arrest without blood priming.Methods Twenty adult male Sprague-Dawley rats weighing 450-560 g were randomized to CPB with deep hypothermic circulatory arrest (DHCA) and control groups,with 10 rats each.The experimental protocols,including blood and crystalloid fluid administration,anesthesia,orotracheal intubation,ventilation,cannulation,and heparinization were identical in both groups.After inducing cardiac arrest,the circuit was turned off and rats were left in a DHCA state for 15 minutes.Rats were rewarmed to 34℃ to 35℃ over a period of 36 to 42 minutes using CPB-assisted rewarming,a heating blanket,and a heating lamp along with administration of 0.1 mEq of sodium bicarbonate and 0.14 mEq of calcium chloride.The remaining priming volume was reinfused and animals were weaned from CPB.Results All CPB with DHCA processes were successfully achieved.Blood gas analysis and hemodynamic parameters were in the normal range.The vital signs of all rats were stable.Conclusions Our CPB circuit has several novel features,including a small priming volume,active cooling/rewarming processes,vacuum-assisted venous drainage,peripheral cannulation without thoracotomy or stemotomy,and an accurate means of monitoring peripheral tissue oxygenation.
文摘Background: In clinical and basic science medicine, we often isolate ourselves in silos, unaware of developments in other related disciplines. Our team has had substantial experience, both in the operating room and in the laboratory, with protecting the brain and the spinal cord via hypothermia. Herein, we briefly share this experience with our colleagues in Neurology, eager for comments and advice from the neurologic perspective. Methods: 1) Clinical brain protection via deep hypothermic circulatory arrest (DHCA) for surgery of the aortic arch. For aortic arch replacement (performed for aortic arch aneurysm or aortic dissection), the aortic arch must be opened and native perfusion stopped. We have decades of experience in many hundreds of patients with this technique. This experience is reviewed. 2) Experimental protection of the spinal cord via cooling. We review our laboratory experience with a novel, recirculating cooling catheter for the vulnerable spinal cord. 3) Experimental protection of the brain via an intraventricular cooling catheter. We review our laboratory experience cooling the brain with a balloon-tipped catheter residing the lateral ventricles. Results: 1) Deep hypothermic circulatory arrest for aortic arch surgery provides superb brain protection for periods up to 45 minutes or longer. Clinical neurologic function, and quantitative neurologic tests, show excellent brain preservation. 2) The novel spinal cooling catheter provides excellent cooling of the spinal cord in a large animal model, without apparent injury of any type. 3) The intraventricular brain cooling catheter provides excellent cooling of the brain, documented by both direct temperature probe and high-tech brain imaging. Conclusions: We wish herein (in this article) to share this experience across our disciplines (Cardiac Surgery and Neurology). We welcome advice from the Neurology community on these surgically-directed methods for cooling and protection of neurological tissue in both the brain and the spinal cord.
