Combined use of cerebral spinal fluid drainage and naloxone reduces the risk of paraplegia in thoracoabdominal aneurysm repair

The risk of ischemic spinal cord injury in patients undergoing graft replacement for thoracoabdominal aortic aneurysms

PURPOSE

We developed a monitoring system to detect spinal cord ischemia during aortic cross-clamping (AXC). This system was used to prospectively determine in which patients ischemia occurs, in which patients reimplantation of intercostal arteries is unnecessary or mandatory, and when reperfusion of intercostal arteries (ICAs) is urgent.

METHODS

Two hundred sixty patients underwent thoracoabdominal aortic aneurysm (TAA) repair with simple AXC. In 167 patients, two electrocatheters were placed before the onset of anaesthesia at level L1/L2 (stimulation) and level T5/T6 (recording) within the epidural space. During surgery, spinal cord function was monitored by recording spinal somatosensory evoked potentials (sSSEP). According to the extent of aortic replacement, most patients were expected to have a high risk of paraplegia.

RESULTS

In group A (59 patients), sSSEP remained normal throughout surgery, and in 54 of these patients ICAs were not reattached outside the proximal aortic anastomosis. In the other five patients ICAs were reimplanted separately because of possible anatomic relation to spinal cord blood supply. No patient in group A had postoperative neurologic deficit. In group B (54 patients) sSSEP remained normal until 15 minutes after AXC but were impaired thereafter. Nineteen patients had early reimplantation of ICAs. Of the 19, three had paraparesis and two had paraplegia. Neurologic deficit developed in the patients without early reimplantation of ICAs. In four patients separate reimplantation of ICAs was performed late in the procedure because of incomplete sSSEP recovery. Subsequently, the sSSEP returned to normal and only one of the four patients had mild paraparesis. The total rate of neurologic deficits in this group was 13% (paraplegia, 3.5%; paraparesis, 9.5%). All 54 patients in group C showed rapid loss of sSSEP within 15 minutes of AXC. In 28 patients ICAs were reimplanted only within the proximal anastomosis. Twenty-one of these patients showed prompt signal recovery after blood-flow release into the reimplanted ICAs, and none had neurologic deficit. Seven patients had no or very late and incomplete sSSEP recovery. Of the seven, three had paraplegia and four had paraparesis. In 26 patients ICAs were reimplanted separately to the proximal anastomosis. This was done early during the procedure in 17 patients, of whom 13 had full recovery of sSSEP and normal neurologic status. Four patients had incomplete or no recurrence of sSSEP, followed by paraplegia in one and paraparesis in three. In nine patients ICAs were reimplanted after the aortic replacement had been completed because of sSSEP recovery was not satisfactory. In all patients in this subgroup sSSEP returned to normal. Six patients had a normal neurologic status and three had mild paraparesis. The total neurologic complication rate in group C was 26% (paraplegia, 7.5%; paraparesis, 18.5%).

CONCLUSION

The risk of ischemic spinal cord injury during replacement for TAA can be assessed continuously by monitoring the sSSEP directly from the spinal cord. Patients without sSSEP changes during aortic reconstruction do not require ICA reattachment and will not have neurologic deficit. Patients who lose sSSEP after AXC are at risk for paraplegia. Patients with impairment or loss of sSSEP >15 minutes after AXC have some collateral vessels, and must have ICAs reimplanted only if sSSEP do not return within normal recovery time after blood-flow release into the proximal anastomosis. Loss of sSSEP within 15 minutes of AXC shows poor collateralization and mandates early restoration of spinal cord blood supply. If the surgeon can achieve the return of sSSEP to normal by subsequent separate reimplantation of ICAS, paraplegia will not occur and paraparesis will be rare and mild. Spinal cord monitoring is a valuable guide to detect whether the spinal cord is at risk and to take measures against par

Cerebrospinal fluid drainage and distal aortic perfusion: reducing neurologic complications in repair of thoracoabdominal aortic aneurysm types I and II

PURPOSE

This study was conducted to evaluate the role of cerebrospinal fluid (CSF) drainage and distal aortic perfusion (DAP) in the prevention of postoperative neurologic complications for high-risk patients who had undergone type I and type II thoracoabdominal aortic aneurysm (TAAA) repair.

METHODS

CSF drainage and DAP were used as an adjunct in the treatment of 94 patients with TAAA (31 type I, 63 type II) between September 1992 and December 1994; 67 were men and 27 were women. The median age was 64 years (range, 28 to 88 years). Aortic dissection occurred in 35 of 94 patients (37%). Thirty-six of 94 patients (38%) had previously undergone proximal aortic surgery. All patients underwent intraoperative DAP and perioperative CSF drainage. Median aortic cross-clamp time was 67 minutes (range, 20 to 131 minutes).

RESULTS

The 30-day survival rate was 90% (85 of 94 patients). Early neurologic complications occurred in 5 of 94 patients (5%), and late neurologic complications occurred in 3 of 94 patients (3%). We compared the neurologic complications of our current group of 94 patients with the data from 42 patients (control group) who also underwent repair of TAAA type I and type II with only simple cross-clamp and without CSF drainage or DAP. Both groups were treated by the senior author (HJS) at the same institution. Total neurologic complications for the current group occurred in 8 of 94 patients (9%) versus 8 of 42 patients (19%) for the control group (p=0.090). Neurologic complications for patients with type II TAAA occurred in 8 of 63 patients (13%) versus 17 of 42 patients (41%) (p=0.014). For all patients with aortic clamp times >or=45 minutes, neurologic complications occurred in 7 of 55 (13%) versus 7 of 18 (39%) (p=0.033).

CONCLUSION

The period of risk during aortic cross-clamp time is reduced with the adjuncts of CSF drainage and DAP, which significantly lower the incidence of neurologic complications after repair of TAAA types I and II.

Alterations in intracranial volume following cross-clamping of the descending thoracic aorta in pigs--an experimental study using MRI

OBJECTIVES

To determine whether alterations in intracranial volume occurred following cross-clamping of the descending thoracic aorta in pigs.

DESIGN AND SETTING

Laboratory animal study.

MATERIALS

Eight pigs undergoing cross-clamping of the descending thoracic aorta for 30 min.

CHIEF OUTCOME MEASURES

A Philips Gyroscan T5-II Release 3 (0.5 T) was used to obtain intracranial images before cross-clamping, during cross-clamping and after declamping. The ventricular volume was measured on Spin Echo T1-weighted images. The signal intensity of the cerebral tissue was measured on Spin Echo T2-weighted images. Increased signal intensity of the cerebral tissue relative to an external reference was used as an indicator of cerebral oedema.

MAIN RESULTS

The ventricular volume decreased to 89% (p < 0.01) of the baseline value after 5 min of cross-clamping. At 5 min after declamping the ventricular volume decreased further to 71% (p < 0.01). At 25 min after declamping the ventricular volume had returned to the baseline value. The signal intensity of the cerebral tissue did not differ from baseline values following aortic cross-clamping.

CONCLUSIONS

In this study, ventricular volume decreased following cross-clamping of the descending thoracic aorta. Since no cerebral oedema was observed, the decrease of ventricular volume was most likely due to increased intracranial blood volume.

Prevention of spinal cord injury after repair of the thoracic or thoracoabdominal aorta

Spinal cord injury occurring as the result of surgical repair of thoracic and thoracoabdominal aortic disease remains a devastating complication. The incidence of postoperative neurologic deficits varies from 4% to 38%. Factors associated with a greater risk for injury include the presence of dissection or extensive thoracoabdominal disease, and a prolonged cross-clamp time. Spinal cord ischemia initiates a deleterious cascade of biochemical events that ultimately result in an increased intracellular calcium concentration. Calcium-activated proteases, lipases, and nucleases mediate the processes that cause cell injury. The accumulation of oxygen-derived free radicals and the occurrence of hyperemia during reperfusion are also contributing causes of spinal cord injury. Increasing the spinal cord blood flow with shunts, oxygenated bypass circuits, cerebrospinal fluid drainage, the intrathecal administration of vasodilators, and the reattachment of intercostal arteries has been tried in an effort to increase spinal cord perfusion. Pharmacologically based measures to prevent spinal cord injury have been pursued, and these have consisted of hypothermia, anesthetic agents, calcium channel blockers, free radical scavengers, and immune system modulation. However, no single technique has proved to be consistently effective in preventing ischemia-induced spinal cord injury.

Endogenous opiates: 1994

This article is the 17th installment of our annual review of research concerning the opiate system. It includes papers published during 1994 involving the behavioral, nonanalgesic, effects of the endogenous opiate peptides. The specific topics covered this year include stress; tolerance and dependence; eating; drinking; gastrointestinal, renal, and hepatic function; mental illness and mood; learning, memory, and reward; cardiovascular responses; respiration and thermoregulation; seizures and other neurological disorders; electrical-related activity; general activity and locomotion; sex, pregnancy, and development; immunological responses; and other behaviors.

Epidural cooling for regional spinal cord hypothermia during thoracoabdominal aneurysm repair

PURPOSE

We investigated the feasibility of achieving regional hypothermia of the spinal cord with an infusion of iced (4 degrees C) saline solution administered into an epidural catheter while monitoring cerebral spinal fluid (CSF) temperature in eight patients undergoing thoracic or thoracoabdominal aneurysm resection.

METHODS

As part of the anesthetic management, an epidural catheter was placed at T11-12, and a subarachnoid thermistor catheter was placed at L3-4. Approximately 30 minutes before aortic cross-clamping, iced (4 degrees C) saline solution was infused into the epidural catheter until CSF temperature decreased to approximately 25 degrees C. The infusion was then adjusted to maintain this temperature until the aorta was unclamped. The subarachnoid catheter was also used to measure CSF pressure and provide for CSF drainage. Surgery was performed in all patients with a clamp-and-sew technique with selective intercostal vessel reattachment.

RESULTS

Infusion of a mean volume of 489 ml (range 80 to 1700 ml) of iced saline solution into the epidural space before aortic cross-clamping led to a decrease in mean CSF temperature to 26.9 degrees C (range 25 degrees to 28.8 degrees C) in 15 to 90 minutes. During cross-clamping and aortic replacement the mean CSF temperature was maintained between 25.2 degrees to 27.6 degrees C and, with discontinuation of the infusion, returned to within 1 degrees C of body core temperature by the end of the procedure. Body core temperature was not significantly affected by the epidural infusion. Mean CSF pressure increased during the epidural infusion but could be reduced by removing saline solution from the epidural space. No postoperative neurologic deficits were observed.

CONCLUSION

Epidural cooling appears to be a satisfactory method of achieving regional spinal cord hypothermia in patients requiring resection of thoracic or thoracoabdominal aortic aneurysms.

Influence of segmental arteries, extent, and atriofemoral bypass on postoperative paraplegia after thoracoabdominal aortic operations

PURPOSE

The purpose of this article was to study the influence of either reattachment or oversewing of patient segmental intercostal or lumbar arteries, extent of aneurysm, and atriofemoral bypass on the incidence of postoperative paraplegia/paraparesis in patients at high risk with type I or II thoracoabdominal aneurysms.

METHODS

Data were prospectively collected on 99 patients undergoing type I or II thoracoabdominal aneurysm repairs, including exact extent of repair and whether atriofemoral bypass ws used. Patency of intercostal arteries from T3 to T12 and lumbar arteries from L1 to L4 were checked by intraoperative inspection. If the arteries were patent, note was taken of whether they were reattached to the new aortic prosthesis. Postoperative neurologic motor function was graded daily for the first 5 days, and the worst score in the first 30 postoperative days (POD) was used for analysis.

RESULTS

Ninety-five of 99 (96%) patients were 30-day survivors. By POD 30, 31 of 98 (32%) patients had had a neurologic deficit. There was no difference in the incidence of deficits according to whether lumbar or intercostal arteries were reattached, ignoring the effect of patency of the arteries. Of greater importance, however, was whether patent segmental arteries were oversewn at specific levels. Thus, for patients who had one or more arteries at T11, T12, or L1 oversewn (often because they could not be reattached), a deficit developed in 11 of 23 (48%) patients versus 20 of 75 (27%) patients who did not have patent arteries or had all patient arteries reattached (p = 0.05, odds ratio = 2.5). More specifically, if all arteries at this level were oversewn, a neurologic deficit developed in 63% of patients versus 23% if all their arteries were reattached (p = 0.01). Reattachment of patent arteries at individual levels from T7 to L4 showed a trend toward a lower risk of deficits but did not reach statistical significance. On multivariate analysis, atriofemoral bypass was associated with a lower risk of paralysis (p = 0.068), and significantly so when controlled for age (p = 0.0329, odds ratio 0.287). Subgrouping of extent type I thoracoabdominal aneurysms resulted in an incidence of paralysis of 14% (3/22) for subgroup A and 23% (5 of 22) for subgroup B compared with 43% (23 of 55) for type II thoracoabdominal aneurysms (type I [8 of 44 18%], versus type II [p = 0.0097]).

CONCLUSION

Patients with no or few patent segmental arteries in the aortic segment being replaced have a lower risk of neurologic deficits, compared with those with patent arteries. Every effort should be made to reattach all arteries at T11, T12, and L1 and, when possible within the constraints of technical feasibility and time, also those from T7 to L4. Preoperative angiography or intraoperative hydrogen testing may better identify the arteries that need to be reattached. When feasible, atriofemoral bypass appears to be protective, particularly when sequential clamping and segmental repairs can be performed.