Methods: Twenty patients with normal pulmonary functions and 20 patients with decreased respiratory function were involved in the study. Endotracheal aspiration samples and plasma samples were obtained just after the entubation, at the end of the cardiopulmonary bypass and at the postoperative sixth hour. The respiratory functional status, bronchial NO release and vascular NO release were evaluated.
Results: The NO levels in plasma and bronchial samples, and respiratory capacity were gradually decreased; and respiratory index values significantly deteriorated in both groups.
Conclusion: These findings show that patients with chronic obstructive lung disease undergoing cardiopulmonary bypass have similar lung damage with patients who have normal respiratory capacity.
This may result in an adverse clinical outcome especially in the patients with limited respiratory capacity.
Nitric oxide (NO) plays a significant role in both the normal and pathologic physiology of lung. In the lung, NO is an important regulator of intercellular interaction, affecting airway and microvascular reactivity and permeability. Pulmonary vascular endothelial cells synthesize NO after certain stimuli, such as shear stress and the receptor binding of specific vasodilators, which finally activate endothelial NOS (eNOS). Endogenously produced endothelium-derived NO is an important mediator of normal pulmonary physiological functions. Any aberrations in basal NO production may be implicated in the pathophysiology of postoperative pulmonary dysfunction.[4,5]
The overall underlying mechanisms of this process have not been entirely elucidated yet.[4] There is a dilemma in the postoperative physiopathology of pulmonary NO release. Decreases in NO activity have been demonstrated after CPB in some studies. While some other several reports highlight increased activity of NO.
This study was designed in the aim to evaluate the correlation of alterations in bronchial and vascular endothelial NO release with pulmonary functions in patients with normal and decreased pulmonary capacity, undergoing coronary artery bypass graft (CABG) operation with CPB.
The patients were grouped into two. Group 1 included the patients with normal pulmonary functions preoperatively. Group 2 included the patients with decreased respiratory capacity (2003 GOLD -Global Initiative for Chronic Obstructive Lung Disease- Classification Stage 2; FEV1/FEVC <%70, %50 <FEV1 <%80, symptomatic or asymptomatic patients) preoperatively.[6]
The study was approved by the local ethics committee of our institution and informed consent was obtained from all patients.
Routine CABG protocol of our cardiovascular surgery clinic was applied to all patients.
Anesthesia was induced with 20 mcg/kg fentanyl cytrate, 0.12 mg/kg pancuronium, 2 mg/kg propofol IV. After tracheal intubation, mechanical ventilation was instituted with 1.0 FiO2, 6-8 ml/kg tidal volume, and 10-12 min respiratory rates. Anesthesia was maintained with 10 mcg/kg/hour of fentanyl, 1 mg/kg/hour propofol as infusion. 2 mg of pancuronium were given every 45 minutes through the operation.
After preparation of left internal mammary artery flap and greater saphenous vein grafts, 400 IU/kg heparin was administered before the institution of CPB. Activated clotting time was managed to be over 400 seconds during cardiopulmonary bypass. At the end of the CPB the heparin effect was reversed with protamine sulphate at 1:1 ratio.
Aortic and two-stage venous cannulae were used to institute the CPB using a roller pump, membrane oxygenation and identical priming solution. The content of prime solution was 1000 ml Ringer’s lactate, 150 cc mannitol, 60 cc bicarbonate and 1 mg/kg heparin. Systemic blood flow was maintained at 2.2-2.4 L/m2, mean arterial blood pressure at 60-70 mmHg during CPB. Systemic hypothermia (28 ºC) and hemodilution were applied.
For myocardial protection, antegrade +4 ºC cold blood cardioplegia (1000 cc blood, 70 ml citrate, 750 mg magnesium sulphate, 3 mEq potassium/100 cc blood, 10 mEq Na-bicarbonate) was given 10 ml/kg at the beginning of the arrest and then repeated every 20 minutes. Topical cooling was maintained with cold saline solution.
Distal anastomoses were performed during the crossclamp period. Proximal anastomoses were performed with partial occluding clamp on beating heart. All the left anterior descending arteries received pediculated left internal mammary artery grafts. The other vessels received greater saphenous vein grafts.
Postoperatively, pharmacological support was instituted according to hemodynamic requirements.
Evaluation of the respiratory capacity and function. The patient’s respiratory functional tests for the measurement of the respiratory capacity were performed the day before the operation and at the postoperative seventh day. FEVC, FEV1, FEV1/FVC were measured. The respiratory index (RI= AaDO2/PaO2), which is used as one of the main determinants of the oxygen transport through the arterioalveolar membrane, was calculated by arterial blood gas assay pre-CPB, post-CPB and at the postoperative sixth hour to define post-bypass lung damage. This factor reflects the arterioalveolar oxygen gradient and its level increases due to any impairment of oxygenation through this membrane. The parameters of this calculation are obtained from arterial blood gas analysis.
RI= AaDO2/PaO2
AaDO2= PAO2-PaO2
PAO2= PIO2-PACO2 x [(FIO2+(1-FIO2/R)]
PIO2= (760-PH2O) x FIO2
RI: Respiratory index; AaDO2: Arterioalveolar oxygen gradient; PaO2: Arteriolar oxygen pressure; PAO2: Alveolar oxygen pressure; PIO2: Inspiration oxygen pressure; PACO2: Alveolar carbondioxide pressure; FIO2: Inspiratory fraction of oxygen; PH2O: Water pressure.
Sample collection. Blood serum, arterial gas and mixed venous samples were taken preoperatively and repeated for follow up parameters in the postoperative period at admission to intensive care unit (ICU) and at the sixth postoperative hour. Systemic blood samples (10 cc) for serum NO detection were taken with the start of cardiopulmonary bypass, after the CPB, and at postoperative sixth hour in the ICU.
Maintaining endotracheal aspiration (ETA) samples. 5 cc of ETA was taken from the endotracheal tube, in order to detect NO levels. First samples are taken after anesthesia induction; second samples are taken at the end of CPB and the third ones at the postoperative sixth hour.
NO determination. All samples were concentrated by centrisart-1 tubes (cut-off 10.000, Sartorius, Goettingen- Germany) and storaged at –20º C. Before concentration by centrisart-1, all aspiration samples were dissolved in 0.1% DDT (dithiothreitol). After incubation at 37 ºC, they were mixed with PBS (pH 7.2). We used in our investigation Nitric Oxide Colorimetric Assay (Roche Molecular Biochemical’s, Mannheim-Germany) to determine the NO levels in serum and bronchial aspiration samples. In biological fluids NO is very rapidly deactivated by oxidation to nitrite and nitrate by physically dissolved oxygen and water. In NO colorimetric assay, NO levels are determined photometrically via its oxidation products nitrite and nitrate. In biological fluids, NO is measured via nitrite. In our test procedures, nitrate present in sample, is reduced to nitrite by reduced NADPH in presence of the enzyme nitrate reductase. Nitrite levels can be measured as diazo dye in the visible range at 550 nm.[7]
Statistical analysis. All the results are given as mean±standard deviation from the mean and percentages. Study groups were compared by using either student t-test or non-parametric Mann Whitney-U when the data did not follow Gaussian distribution. In comparison of categorical data chi square and Fisher exact tests were used when they were appropriate. A repeated measure ANOVA was used to assess changes in respiratory index, serum nitric oxide levels and endobronchial nitric oxide levels during preoperative and postoperative period. A p<0.05 was considered significant. SPSS for windows statistical software program was used in all statistical comparisons.
Table 1: Demographic variables
Table 2: Perioperative data of the patients
Table 3: FEV1/ FVC measurements
The NO levels were decreased gradually and significantly
in serum and ETA samples in both groups. The
change in the serum and the bronchial NO levels were
correlated (Table 3) (Fig. 1, 2).
Respiratory index before CPB was similar between
the groups (group 2 vs 1: 0.41±0.01 vs 0.38±0.01),
and there were significant changes in the second and
the third measurements in RI value in both groups
(p<0:0001; ANOVA, treatment effect) (Fig. 3).
Duration of mechanical ventilation was significantly
longer in group 2 (Table 2).
Postoperative seventh day measurements of FEV1/
FVC were found to be decreased slightly (group 1 vs
group 2: 90.12±2.48 vs 63.23±4.71) and the values were
significantly lower in group 2.
Although the cellular and molecular events underlying the pathological response to heart surgery are not yet entirely clear, NO is known to be involved and could serve both to mediate and indicate lung injury in cardiac surgery with CPB.[11,12]
The NO production is regulated by endothelial-NOS (eNOS) and inducible NOS (iNOS) in the development of CPB-induced inflammatory response. The ETA specimens are compounds of endothelial secretions through the lung, the NO levels of these specimens may reflect the EC dysfunction. The NO levels in the ETA sample can be determined as a marker of bronchial endothelial function and can differ according to the degree of inflammatory process altering the endothelial function in response to inflammatory reaction of lung tissue.[7,13,14]
The basal serum and ETA levels of NO groups were not significantly different but post cardiopulmonary bypass levels showed significance. There was a correlation between vascular and bronchial release of NO levels. The NO levels in both patient groups decreased gradually.
The RI values were found to be increased threefold after cardiopulmonary bypass. The comparison of increase between two groups showed no significance. The RI values at postoperative sixth hour were also high but similar to post cardiopulmonary bypass levels.
The change of vascular and brochial NO levels and RI values may reflect the inflammatory effect of CPB on respiratory physiology. The insignificant values between groups are worth for discussion. Although the patients included in the study as group 2 had decreased respiratory capacity preoperatively, (2003 GOLDGlobal Initiative for Chronic Obstructive Lung Disease- Classification Stage 2), the CPB seems to have a similar effect on both groups. The CPB effect on respiratory functions may be diverse in patients with more severely decreased respiratory capacity.
However, previous studies of the changes in basal NO production induced by CPB, as determined on the basis of plasma levels of NO metabolites, have been inconsistent. Despite extensive research into both proinflammatory and anti-inflammatory actions of NO, the overall contribution of NO to inflammatory conditions of the lung is not easily predicted and seems to depend on many factors, such as the site, time and degree of NO production in relation to the local redox status, and the acute or chronic nature of the immune response.[15,16]
In the respiratory tract, NO is generated enzymatically by three distinct isoforms of NO synthase (NOS-1, NOS-2 and NOS-3) that are present to different extents in numerous cell types, including airway and alveolar epithelial cells, neuronal cells, macrophages, neutrophils, mast cells, and endothelial and smooth muscle cells. Inflammatory diseases of the respiratory tract, such as asthma, acute respiratory distress syndrome (ARDS) and bronchiectasis, are commonly characterized by an increased expression of NOS-2 within respiratory epithelial and inflammatory-immune cells, and a markedly elevated local production of NO, presumably as an additional host defense mechanism against bacterial or viral infections. Pro-inflammatory cytokines and endotoxin can induce the release of NO by EC and smooth muscle cells through the inducible form of the enzyme NOS (iNOS). Constitutive NO (cNO) is normally produced by EC from the amino acid L-arginine by means of calcium-dependent NOS. Nitric oxide modulates vasomotor tone in response to physiologic stimuli such as pulsatile flow and shear stress.[17-20]
In conclusion, we evaluated that, there is a bronchial and vascular NO release impairment after CPB, and this is correlated with the respiratory capacity. This may reflect the bronchial endothelial cell dysfunction after CPB. Nevertheless, RI values and NO release are similarly affected during CPB. The patients with COPD at stage 2 can be operated with COPD under similar risks in terms of decrease in respiratory capacity. Further studies may help the status for patients with more severe COPD.
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