Journal of Minimal Access Surgery Medknow Publications ISSN: 0972-9941 EISSN: 1998-3921 Vol. 4, Num. 4, 2008, pp. 104-107

Journal of Minimal Access Surgery, Vol. 4, No. 4, October-December, 2008, pp. 104-107

Original Article

Cerebral oxygenation monitoring using near infrared spectroscopy during one-lung ventilation in adults

Tobias JosephD, Johnson GarryA, Rehman Saif, Fisher Robert, Caron Norman

Department of Anaesthesiology and Paediatrics, University of Missouri, Columbia, Missouri
Correspondence Address:Department of Anaesthesiology, 3W-27G HSC, One Hospital Drive, Columbia, Missouri 652 12 tobiasj@health.missouri.edu

Date of Submission: 22-Jul-2008
Date of Acceptance: 19-Aug-2008

Code Number: ma08024

Abstract

Keywords: Cerebral oxygenation, near infrared spectroscopy, one-lung ventilation, thoracic surgery, thoracoscopy

Introduction

One-lung ventilation (OLV) is frequently used during open and endoscopic thoracic procedures to eliminate lung movement and improve surgical visualisation. With newer thoracoscopic procedures, effective OLV has become mandatory to facilitate completion of the procedure and avoid the need for open thoracotomy. During OLV, even in the presence of effective hypoxic pulmonary vasoconstriction, intrapulmonary shunting still occurs, resulting in alterations in systemic oxygenation. These modest decreases in systemic oxygenation are accepted with the assumption that tissue oxygenation remains adequate. However, there are limited data examining the end-organ effects of the alterations in respiratory and cardiovascular function which may occur during OLV.

Near infrared spectroscopy (NIRS), otherwise known as cerebral oximetry, is a non-invasive device that uses infrared light to estimate brain tissue oxygenation (rSO ₂ ). ^[1] The potential use of NIRS as a means of monitoring cerebral oxygenation was first suggested by Jobsis in 1977. ^[2] In a technique similar to pulse oximetry, NIRS uses infrared light to penetrate living tissue and estimate brain tissue oxygenation by measuring the absorption of infrared light by tissue chromophores such as haemoglobin. After the infrared light penetrates living tissue, the relative absorption of the different wavelengths is dependent on the concentration of the various hemoglobin species (unoxygenated vs oxygenated). Based on the relative absorption of the infrared light at various wavelengths, the specific concentration of the haemoglobin species can be determined using a modification of the Beer-Lambert law. ^[1],[2],[3] Previous studies have suggested that decreases in cerebral oxygenation as measured by NIRS may occur even without changes in routine intraoperative monitoring techniques including heart rate (HR), blood pressure (BP), and oxygen saturation measured by pulse oximetry (SaO ₂ ). ^{[4],[5],[6],[7]} Additionally, it has been demonstrated that these episodes of cerebral oxygen desaturation may correlate with postoperative neurocognitive dysfunction and that monitoring and treating these episodes may decrease the incidence of postoperative neurocognitive dysfunction. ^[6],[7] To date, there are no studies evaluating changes in rSO ₂ which may occur during OLV. The current study prospectively monitored cerebral oxygenation using NIRS during OLV in adults.

Materials and Methods

The study was approved by the University′s Institutional Review Board and informed consent was obtained from the patients. Patients 18 years of age and greater scheduled for thoracic surgery requiring OLV were considered eligible for inclusion. Patients with a pre-existing oxygen requirement or those requiring preoperative mechanical ventilation were not considered eligible. The choice of anaesthetic agents was not standardised and was at the discretion of the anaesthesia team. Cerebral oxygenation (rSO ₂ ) was continuously monitored using near infrared spectroscopy (INVOS 3100A, Somanetics Corporation, Troy, MI) with a single sensor placed on the right side of the patient′s forehead with its caudad border approximately 1 cm above the patient′s eyebrow and the medial edge at the midline according to the manufacturer′s guidelines. The rSO ₂ value was recorded every 10 sec during the procedure. The anaesthesia team was not allowed to view the rSO ₂ value during the procedure. Oxygen saturation measured by pulse oximetry (SaO ₂ ), end-tidal carbon dioxide (ETCO ₂ ), BP, and HR were continuously monitored and the values recorded every 5 min. OLV was provided using either a double lumen endotracheal tube or a bronchial blocker. The surgical procedures were performed in either the right or left lateral decubitus position. During the procedure, the BP was maintained within 20% of baseline by the administration of fluids or the direct acting α-adrenergic agonist, phenylephrine, for a low BP and by increasing the concentration of the inhalational anaesthetic agent or the administration of additional opioid (fentanyl) for a high BP. The inspired oxygen concentration (F _i O ₂ ) was adjusted as needed with a goal of maintaining the oxygen saturation at ≥ 95%. During OLV, the tidal volume was decreased to 6-8 mL/kg and the ventilation rate adjusted as needed to maintain the PaCO ₂ at 35-40 mmHg.

The rSO ₂ values obtained prior to the start of OLV were averaged for each patient and then used as the patient′s baseline for subsequent analysis. The values obtained during OLV were then compared to the baseline values and categorised as an increased in rSO ₂ from baseline or as an absolute decrease from baseline of 0-9, 10-19, 20-29 or ≥ 30. The number of values representing an rSO ₂ decrease to less than 75% and 80% of the baseline was also determined. The demographics (age, weight, gender, ASA designation), hemodynamic values (HR, BP) and SaO ₂ values of patients with an rSO ₂ value less than 75% of baseline were compared to those of patients without cerebral desaturation using a non-paired t-test and Fisher′s exact test with a contingency [Table - 1]. The data are presented as the mean ± SD.

Results

The study cohort included 40 adults ranging in age from 38 to 78 years of age and in weight from 59 to 122 kg . Eight were ASA II and 32 were ASA III. Open thoracotomy was performed in 28 and thoracoscopy in 12. The baseline rSO ₂ varied from 51 to 78 (65 ± 11). The duration of OLV varied from 45 to 98 min (78.8 ± 20.6 minutes). A total of 18,562 rSO ₂ values were collected during OLV. The rSO ₂ was ≥ baseline at 3,593 of the 18,562 data points (19%). For the remaining 14,969 data points, the rSO ₂ value was ≤ baseline [Table - 1]. The rSO ₂ was 0-9 ≤ baseline in 7,053 (38%) of the readings, 10-19 ≤ baseline in 4,084 (22%) of the readings, and 20-29 ≤ baseline in 3,898 (21%) of the readings. No rSO ₂ values was 30 ≤ the average baseline values. A total of 4,459 of the rSO ₂ values (24%) were less than 80% of the baseline value and 2599 (14%) were less than 75% of the baseline value. Twenty-one patients (52.5%) had at least one rSO ₂ value that was less than 80% of the baseline and 13 patients (32.5%) had at least one rSO ₂ value that was less than 75% of the baseline. Eight patients (20%) had rSO ₂ values less than 75% of baseline for more than 25% of the duration of OLV.

Patients with prolonged decreases in rSO ₂ to less than 75% of the baseline value for 25% or more of the duration of OLV (n=8) were older (63.7 ± 10.2 vs 54.6 ± 9.8 years, p< 0.025), weighed more (95.8 ± 17.4 versus 82.6 ± 14.6 kg, p=0.038), and were more likely to be ASA III vs II (7 of 8 vs 25 of 32, relative risk 1.75) than the remainder of the cohort (n=32). There was no difference between the two groups in regards to gender, duration of OLV, and the intraoperative SaO ₂ , HR, BP, or ETCO ₂ values.

Discussion

The potential for postoperative neurocognitive dysfunction and its impact on the postoperative course has gained recent attention over the past few years. ^[8] Although likely multi-factorial, recent data suggest that changes in cerebral oxygenation as assessed by NIRS may be a risk factor. ^[6],[7] In a prospective trial, 122 elderly patients undergoing major abdominal surgery under general anaesthesia were randomly assigned to a treatment group in which the rSO ₂ value was monitored and maintained at ≥ 75% of the preinduction values or a monitor only group in which cerebral oximetry was monitored, but not visible to the anaesthesiologist. ^[6] Cerebral oxygen desaturation (≤ 75% of baseline) was observed in 11 patients of the treatment group (20%) and 15 patients in the control group (23%). The treatment protocol to treat cerebral oxygen desaturation included ensuring adequate ventilation, checking head position, increasing the F _i O ₂ , increasing the PaCO ₂ , and increasing the blood pressure with fluids or vasoconstricting medications. Control patients with cerebral oxygen desaturation had lower mini-mental status examination (MMSE) scores on postoperative day #7, longer PACU stays (median: 47 minutes vs 25 min, P =0.01) and longer hospital stays (median: 24 days vs 10 days, P =0.007) when compared with the treatment patients. More recently, Murkin et al. randomized 200 adults undergoing coronary artery bypass grafting to either a treatment group where the rSO ₂ was monitored and treated or a monitor only group. ^[7] There was an increased incidence of prolonged cerebral desaturation in the monitor only group (6 vs 0, P =0.014) as well as a longer stay in the Intensive Care Unit ( P =0.029). Additionally, there was an increased incidence of major end-organ morbidity and mortality defined as death, the need for mechanical ventilation for > 48h, stroke, myocardial infarction, or need for re-exploration ( P =0.048).

In our prospective evaluation, we noted as with previous studies that changes in rSO ₂ frequently occurred without changes in haemodynamic or ventilatory parameters. Therefore, monitoring with standard ASA monitors fails to identify these periods of cerebral desaturation. Thirteen of the 40 patients (32.5%) had at least one rSO ₂ value that was less than 75% of the baseline, which using the criteria of Casati et al , may place these patients at higher risk for postoperative neurocognitive dysfunction. Additionally, eight patients or 20% of the current cohort had rSO ₂ values that were ≤ 75% of baseline for more than 25% of the duration of OLV or approximately 20 min. We noted no correlation of these changes with HR, BP, ETCO ₂ , or SaO ₂ values, findings similar to those reported by other investigators. The incidence of significant cerebral desaturation was higher in our current cohort of patients than demonstrated in previous studies as almost one-third of our cohort had at least one rSO ₂ value that was ≤ 75% of baseline compared to 20% in the study of Casati et al and 9% in our previous study in adults during laparoscopic procedures. ^[4],[6] One explanation for the increased incidence of cerebral desaturation in the current cohort may be that rSO ₂ values were recorded every 10 sec compared to other studies where values were recorded at intervals varying from 5 to 30 minutes. In the current cohort, each rSO ₂ value that was obtained during OLV (n=18,562) was compared to the baseline rather than averaging values over a period of time. Alternatively, the use OLV may place these patients at higher risk for cerebral desaturation due to the presence of intrapulmonary shunt and lower PaO ₂ values during the procedure. As with our previous study in adult laparoscopic surgery, ^[4] we did note that patients who experienced rSO ₂ values ≤ 75% of baseline were older, weighed more, and were more likely to be ASA category III.

There are specific limitations of the current study. We did not separate the patients into treatment and non-treatment groups to determine if treating the rSO ₂ decreases would alter postoperative outcome. Our intent was only to perform an observational study to determine if cerebral desaturation occurs during OLV as with other major surgical procedures. Additionally, we did not investigate the effect of intraoperative episodes of cerebral desaturation on postoperative outcome and since the anaesthetic technique was not strictly controlled, we can make no comment regarding the anaesthetic technique and its impact on cerebral desaturation. Based on the relatively high incidence of decreases in rSO ₂ during thoracic procedures using OLV, we would suggest that future studies are needed to address these issues.

References

1.	Tobias JD. Cerebral oxygenation monitoring: Near infrared spectroscopy. Exp Rev Med Devices 2006;3:235-43.  Back to cited text no. 1
2.	Jobsis FF. Noninvasive, infrared monitoring of cerebral and myocardial oxygen sufficiency and circulatory parameters. Science 1977;198:1264-7.  Back to cited text no. 2
3.	Yoshitani K, Kawaguchi M, Tatsumi K, Kitaguchi K, Furuya H. A comparison of the INVOS 4100 and the NIRO 300 near-infrared spectrophotometers. Anesth Analg 2002;94:586-90.  Back to cited text no. 3  [PUBMED]  [FULLTEXT]
4.	Gipson CL, Johnson GA, Fisher R, Stewart A, Giles G, Johnson JO, et al. Changes in cerebral oximetry during peritoneal insufflation for laparoscopic procedures. J Min Access Surg 2006;2:67-72.  Back to cited text no. 4
5.	Yao FS, Tseng CC, Ho CY, Levin SK, Illner P. Cerebral oxygen desaturation is associated with early postoperative neuropsychological dysfunction in patients undergoing cardiac surgery. J Cardiothorac Vasc Anesth 2004;18:552-8.  Back to cited text no. 5  [PUBMED]  [FULLTEXT]
6.	Casati A, Fanelli G, Pietropaoli P, Proietti R, Tufano R, Danelli G, et al. Continuous monitoring of cerebral oxygen saturation in elderly patients undergoing major abdominal surgery minimizes brain exposure to potential hypoxia. Anesth Analg 2005;101:740-7.  Back to cited text no. 6  [PUBMED]  [FULLTEXT]
7.	Murkin JM, Adams SJ, Novick RJ, Quantz M, Bainbridge D, Iglesias I, et al. Monitoring brain oxygen saturation during coronary bypass surgery: A randomized, prospective study. Anesth Analg 2007;104:51-8.  Back to cited text no. 7  [PUBMED]  [FULLTEXT]
8.	Newman MF, Kirchner JL, Phillips-Bute B, Gaver V, Grocott H, Jones RH, et al. Longitudinal assessment of neurocognitive function after coronary artery bypass surgery. N Engl J Med 2001;344:395-402.  Back to cited text no. 8  [PUBMED]  [FULLTEXT]

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