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Ann Thorac Surg 2000;69:750-754
© 2000 The Society of Thoracic Surgeons

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Original Articles

Neuron-specific enolase increases in plasma during and immediately after extracorporeal circulation

^a Department of Cardiothoracic Surgery, University Hospital, Lund, Sweden
^b Department of Anesthesiology, University Hospital, Lund, Sweden
^c Department of Medical Chemistry, University Hospital, Lund, Sweden

Address reprint requests to Dr Blomquist, Department of Anesthesiology and Intensive Care, University Hospital, S-22185 Lund, Sweden

	Abstract

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Background. Minor cerebral complications are common after cardiac surgery. Several biochemical markers for brain injury are under research; one of these is neuron-specific enolase (NSE). The purpose of this study was to investigate the release of this enzyme into the blood during and immediately after extracorporeal circulation and to evaluate the effect of hemolysis on this release.

Methods. Sixteen patients scheduled for elective heart surgery were included in the study. Blood samples for analysis of NSE and free hemoglobin in plasma were drawn before, during, and up to 48 hours after the end of extracorporeal circulation. The release of NSE from erythrocytes and its correlation to the release of free hemoglobin was studied by serial dilution and hemolysis in vitro.

Results. The peri- and postoperative course was uneventful in all patients. Extracorporeal circulation initiated a release of NSE that reached a maximum 6 hours after the end of perfusion. Thereafter, the levels declined with an estimated t_1/2 of 30 hours. The concentration of free hemoglobin increased during the perfusion, with maximum levels at the end of perfusion, after which they fell rapidly to normal values. The in vitro study showed a strong linearity between the release of NSE and free hemoglobin after induced hemolysis.

Conclusions. The increased levels of enolase at the end of cardiopulmonary bypass can, to a major part, be explained by the release from hemolysed erythrocytes. The value of NSE as a marker for brain injury in these situations is therefore doubtful.

	Introduction

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Cerebral injury continues to be a major source of complication after extracorporeal circulation. The incidence of stroke after cardiac surgery is 1% to 5%, however, the incidence of minor cerebral complications have been reported to be 60% to 70% [1–4]. Patients with such complications show subtle dysfunction concerning memory, concentration ability, as well as disturbance in personality. These cognitive dysfunctions can only be detected by prospective neuropsychological testing, which is both cumbersome to the patients and expensive. Methods to identify these patients at an early stage are lacking, thus justifying the search for specific biochemical markers for brain injury.

Enolase is a cytoplasmatic glycolytic enzyme that converts 2-phosphoglycerate to phosphoenolpyruvate. The enzyme exists as a dimer and has three immunologically distinct subunits, , ß, and . Five isoenzymes can be found: , ßß, , ß, and . The brain contains both and subunits but not ß. The dimeric form is specific for glial cells, whereas the -enolase has been shown to be located in neurons and neuroectodermal tissue. The term "neuron-specific enolase" (NSE) refers to both the and forms. The molecular weight for the dimeric form of the enzyme is 77 kDa [5–7].

In vitro studies have shown that NSE is released from cultured neurons when exposed to cytotoxic agents and that the levels of NSE can serve to quantify the amount of neuronal cell death [8]. In animals, increased levels of NSE in cerebrospinal fluid (CSF) have been reported in models of traumatic and ischemic brain damage [9, 10]. Studies in humans have shown increased levels of NSE in CSF to be associated with a variety of central nervous injuries and diseases, eg, stroke, traumatic head injury, multiple sclerosis, Alzheimer’s disease, and epileptic seizures [11–17]. We have previously reported results that show an association between neurological outcome after open heart surgery and serum levels of NSE assessed on the second postoperative day [18]. However, NSE can also be found in platelets and erythrocytes [6, 7], both of which are significantly affected by extracorporeal circulation (ECC) and cardiac surgery. In this study, we report the appearance and elimination of NSE from serum during and after ECC. To evaluate the effect of hemolysis on the release of NSE, we also studied the appearance of free hemoglobin (fHb) during and after ECC, as well as the effect of hemolysis on the release of NSE in vitro.

	Material and methods

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Sixteen consecutive patients scheduled for elective open heart surgery were studied. Patients with a history of cerebral disease were excluded from the study. Informed consent was obtained and the study protocol was approved by the Ethics committee of the University. Indications for surgery were coronary disease in 14 patients and valvular disease in 2 patients. The male/female ratio was 12:4, and the median age was 63 years (range 30 to 78 years). The anesthetic procedure was similar in all patients, and consisted of 5 to 15 µg/kg of fentanyl (Leptanal; Janssen Pharmaceutica, Beerse, Belgium) in combination with midazolam (Dormicum; Roche, Basel, Switzerland), 3 to 5 mg at induction. Intubation was performed during succinylcholine relaxation and anesthesia was maintained by additional doses of midazolam and fentanyl. No volatile anesthetic was given before ECC; however, during and after bypass inhalation of isoflurane (Forene; Abbot, Chicago, IL) 0.7% to 1.0% was administered.

Surgery was performed in moderate hypothermia (30°C to 32°C) using a COBE compact membrane lung (CML) membrane oxygenator and a roller pump generating a nonpulsatile flow. An arterial filter was included in the circuit. Mean arterial pressure was maintained above 50 mm Hg during bypass; if necessary, intermittent doses of norepinephrine were administered. Distal anastomosis was performed with the aorta cross-clamped, while the ensuing proximal anastomosis was performed on a beating heart with a side-biting clamp on the aorta. Cold anterograde St. Thomas’ cardioplegic solution and topical ice slush were used for myocardial protection.

Arterial blood samples for analysis of NSE and fHb were collected during anesthesia immediately after administration of heparin, 20 minutes after the start of ECC, immediately after the end of ECC (t = 0 in the figures), and then 3, 6, 12, 24, and 48 hours after the end of ECC.

In vitro study
Blood from 6 healthy donors was used. After centrifugation and separation, the erythrocytes were serially diluted and hemolysed by distilled water to obtain hemolysis of 0.2%, 0.5%, 1%, and 2.5%. The concentrations of free Hb and NSE were measured at each stage.

Biochemical assay
Hemoglobin in plasma was determined by measuring the absorption of plasma at 577 nm. The concentration of hemoglobin was then calculated after correction for nonspecific absorbance at 660 nm.

NSE in serum was analyzed using a monoclonal two-site single incubation immunoradiometric assay (Prolifigen NSE; Sangtec Medical, Bromma, Sweden). The assay uses monoclonal antibodies that bind to the -subunit of the enzyme. Both the - and - forms of the enzyme are thus detected. The sample is incubated with a plastic bead coated with the antibody to NSE labeled with ¹²⁵I. The antibodies bind to different epitopies of the NSE molecule, whereby the labeled antibody is indirectly bound to the bead. After washing unreacted radioactive antibody off the bead, the radioactivity bound to the bead was measured using a gamma counter. The amount of NSE in the samples was then calculated using standards with known concentrations of NSE. The upper limit of normal values with the method of analysis used in this study has been reported to be 9.2 µg/L.

Statistics
Linear and multiple regression tests were performed using the Sigma-Stat software (SPSS Inc, Chicago, IL). Mann-Whitney rank sum test was used for groupwise comparison in Table 1. A p level of less than 0.05 was considered significant.

	Results

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View larger version (14K): [in this window] [in a new window]   Fig 1. The concentrations in serum of NSE (µg/L) (filled circles, left y-axis) and fHb (g/L) (open circles, right y-axis) during and after ECC. End of ECC is at t = 0. (Data are mean ± SEM, n = 16).

View larger version (11K): [in this window] [in a new window]   Fig 2. The correlation between concentration of NSE (µg/L) at the end of ECC and perfusion time (min). (Linear regression, n = 16. r = 0.68, p < 0.01).

There was no correlation between the concentration of fHb at the end of the perfusion and the duration of perfusion. The concentration of NSE at the end of perfusion as a function of fHb at the same time is shown in Figure 3. A weak positive correlation was found, with r = 0.55 and p less than 0.05. A multiple linear regression test with the concentration of NSE at the end of perfusion as dependent variable and the concomitant concentration of fHb and perfusion time as independent variables resulted in a correlation coefficient of r = 0.806. Both variables contributed significantly to the model, with p less than 0.05 and less than 0.01, respectively.

View larger version (10K): [in this window] [in a new window]   Fig 3. The correlation between concentrations of NSE (µg/L) and fHb (g/L) at the end of ECC. (Linear regression, n = 16, r = 0.55, p < 0.05).

View larger version (13K): [in this window] [in a new window]   Fig 4. The correlation between concentrations of NSE (µg/L), fHb (g/L), and degree of hemolysis (%) in vitro. (r = 0.99, p < 0.0001).

	Comment

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As can be seen from Figure 1, the levels of NSE continue to rise after the end of ECC even though the levels of fHb started to decline at the same time. When considering the relationship between hemolysis and NSE in blood after ECC, differences in elimination need to be noted. The free hemoglobin produced by hemolysis is rapidly taken up by the reticuloendothelial system and transformed in the liver. When fHb reaches critical levels, hemoglobinuria appears, usually at 0.5% hemolysis. NSE is a fairly large protein and is probably metabolized in the liver, although the rate of elimination is unknown. The fact that fHb decreased rather instantly after the end of ECC in our study does not necessarily mean that hemolysis has ceased. Therefore, due to the differences in elimination rates, the sustained increase in NSE could in part be explained by the release caused by ongoing hemolysis. Our results raise the question as to whether NSE could be used as a marker for cerebral injury after cardiac surgery. The advantage of NSE as a marker for neuronal injury is the well-proven correlation between the release of NSE and neuronal death in in vitro studies mentioned before. Likewise, increased levels of NSE in CSF and blood after experimental brain injury in animals and cerebral injury, not associated with hemolysis, in humans suggest the usefulness of NSE in these respects. The main disadvantage would be the association between NSE and hemolysis, especially early in the course after ECC, coupled with the relatively slow elimination of NSE from the circulation. However, we believe that analysis of NSE can be used as a marker for cerebral injury after ECC provided that serial tests are analyzed and ample time is allowed between the tests in order to avoid possible contamination from hemolysis caused by ECC. In our study, all patients had an uneventful outcome with no clinical signs of cerebral injury. The clinical value of NSE as a marker for cerebral injury after ECC needs to be validated in patients with a known postoperative brain lesion, preferably where the location and volume of the lesion is known.

	Acknowledgments

 
This study was in part supported by grants from Sangtec AB, Bromma, Sweden.

	References

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