Reoperation for Freestyle stentless aortic valves.

Ten patients who initially underwent Freestyle stentless aortic valve implantation required reoperation. The goal of this study was to describe the reoperative techniques used and to review the outcomes of reoperation in patients with Freestyle stentless aortic valves. From September 1992 to April 2001, at the University of Michigan, a total of 552 Freestyle stentless aortic valves were implanted, and in 10 (1.8%) of these patients (7 men, 3 women) a reoperation was required. The mean age at the time of the initial implantation was 53.5 +/- 14.1 years. Implantation techniques included both modified inclusion root (7) and inclusion root (3). Reasons for reoperation included endocarditis (7), aortic aneurysm (1), valve dehiscence (1), and subvalvular outflow tract obstruction (1). Eight patients underwent homograft reimplantations and in 2 Freestyle reimplantations. In all cases, the previous aortotomy was re-entered, the pseudoendothelial layer over the distal suture line of the noncoronary sinus was incised and continued into the other 2 sinuses. Utilizing a ganglion knife, the Freestyle valve was freed from the native aortic tissue to the proximal suture line. The Dacron sewing ring was then separated using sharp dissection and the lower suture line excised. No calcification was noted in any case. The mean time interval between the first and second operative procedure was 13.4 +/- 21.5 months. There were no operative deaths and only one late death. Mean long-term follow-up was 43 +/- 29 months. Reoperation on a Freestyle stentless aortic valve, when necessary, can be accomplished without increased operative risk and with excellent survival.

Mediators of ischemia-reperfusion injury of rat lung.

In rats, we characterized the mediators of lung reperfusion injury after ischemia. Animals underwent left lung ischemia. After 90 minutes of ischemia, reperfusion for up to 4 hours was evaluated. Lung injury, as determined by vascular leakage of serum albumin, increased in ischemic-reperfused animals when compared with time-matched sham controls. Injury was biphasic, peaking at 30 minutes and 4 hours of reperfusion. The late but not the early phase of reperfusion injury is known to be neutrophil dependent. Bronchoalveolar lavage of ischemic-reperfused lungs at 30 minutes and 4 hours of reperfusion demonstrated increased presence of serum albumin, indicative of damage to the normal vascular/airway barrier. Lung mRNA for rat monocyte chemoattractant protein-1 and tumor necrosis factor-alpha peaked very early (between 0.5 and 1.0 hour) during the reperfusion process. Development of injury was associated with a decline in serum complement activity and progressive intrapulmonary sequestration of neutrophils. Administration of superoxide dismutase before reperfusion resulted in reduction of injury at 30 minutes of reperfusion. Complement depletion decreased injury at both 30 minutes and 4 hours of reperfusion. Requirements for tumor necrosis factor-alpha, interferon-gamma, and monocyte chemoattractant protein-1 for early injury were shown whereas only tumor necrosis factor-alpha was involved at 4 hours. We propose that acute (30-minute) lung injury is determined in large part by products of activated lung macrophages whereas the delayed (4-hour) injury is mediated by products of activated and recruited neutrophils.

Regulatory effects of interleukin-10 on lung ischemia-reperfusion injury.

OBJECTIVE: Interleukin-10, a cytokine with antiinflammatory activities, was studied to determine its effects on development of early lung reperfusion injury. METHODS: Adult male rats underwent 90 minutes of left lung ischemia followed by 4 hours of reperfusion. Time-matched sham-operated control rats underwent hilar dissection but not lung ischemia. Lung injury was measured by vascular permeability to bovine serum albumin tagged with iodine 125. To evaluate the effect of exogenous interleukin-10, additional animals received interleukin-10 intravenously before ischemia. To assess the role of endogenous interleukin-10, animals received rabbit antimouse interleukin-10 immunoglobin G (or preimmune rabbit immunoglobin G) before ischemia. RESULTS: Compared with sham control rats, ischemia-reperfusion control rats demonstrated significantly more lung injury. Animals receiving interleukin-10 had significantly less lung injury than did ischemia-reperfusion control rats. Animals receiving antiinterleukin-10 had significantly more lung injury than did animals receiving preimmune immunoglobin G. Alveolar macrophages from animals after 90 minutes of lung ischemia produced more tumor necrosis factor-alpha in culture than did unstimulated macrophages; this production was reduced significantly by the addition of interleukin-10 to the culture medium. CONCLUSION: Endogenous interleukin-10 has a protective effect against early lung reperfusion injury, and interleukin-10 administration can reduce lung reperfusion injury, perhaps in part through its ability to reduce production by alveolar macrophages of tumor necrosis factor-alpha, a known proinflammatory cytokine.

Disparate effects of nitric oxide on lung ischemia-reperfusion injury.

BACKGROUND: Inhaled nitric oxide (.NO) has been found to be a potent pulmonary vasodilator. We assessed whether .NO, through this function or others, could alleviate lung reperfusion injury. METHODS: Rats underwent thoracotomy, with clamps used to create left lung ischemia. After 90 minutes of ischemia, clamps were released, permitting reperfusion for either 30 minutes or 4 hours. Additional animals received inhaled .NO via the ventilator to determine its effects on reperfusion injury. RESULTS: Lung injury, measured by increased vascular permeability using iodine-125-labeled bovine serum albumin leakage, was significantly increased in ischemic-reperfused animals compared with time-matched shams not undergoing ischemia. Inhaled .NO delivered at the start of reperfusion worsened injury at 30 minutes but was protective at 4 hours. The increased injury could be avoided either by delaying .NO for 10 minutes or by treating the animals with superoxide dismutase before reperfusion. .NO reversed postischemic pulmonary hypoperfusion at 4 hours, as measured by labeled microspheres. Lung neutrophil content was significantly reduced at 4 hours in .NO-treated animals. CONCLUSIONS: .NO is toxic early in reperfusion, due to its interaction with superoxide, but is protective at 4 hours of reperfusion, due to reversal of postischemic lung hypoperfusion and reduction of lung neutrophil sequestration.

Pattern of injury and the role of neutrophils in reperfusion injury of rat lung.

Using a rat lung model, we sought to characterize the time course for ischemia-reperfusion injury and the role of neutrophils in the development of injury. Adult male Long-Evans rats underwent left thoracotomy with dissection and clamping of the left pulmonary artery, bronchus, and vein for 90 min, resulting in complete left lung ischemia. The lungs were then ventilated and reperfused for up to 4 hr. Time-matched sham animals underwent the identical thoracotomy and hilar dissection, but the lungs were not rendered ischemic. Using vascular permeability of 125I-labeled bovine serum albumin as a measure of reperfusion injury, a bimodal pattern of injury was observed. Compared to sham controls, animals undergoing ischemia-reperfusion demonstrated a significant early phase of lung injury at 30 min of reperfusion (P < 0.0001), followed by partial recovery. A second peak of lung injury was noted after 4 hr of reperfusion (P < 0.001). Myeloperoxidase activity in reperfused lung tissue, a measure of neutrophil sequestration, increased during the reperfusion time course. To determine the role of neutrophils in the development of lung reperfusion injury, additional animals undergoing the identical ischemia-reperfusion protocol received either rabbit anti-rat neutrophil serum or preimmune serum the day prior to operation. Profound neutropenia (< 75/mm3 blood) was confirmed by differential leukocyte counts. Neutropenia had no protective effect against microvascular permeability at 30 min of reperfusion, but there was a significant reduction in lung injury at 4 hr (P < 0.005). We conclude that, during lung ischemia-reperfusion, there is a bimodal pattern of injury, consisting of both neutrophil-independent and neutrophil-mediated events.