Cerebral Oximetry as a Guide Monitor in Extreme Trendelenburg P
Position and Elevated Intrathoracic Pressure for Prolonged Robotic
Assisted Radical Prostatectomy Cerebral Oximetry as a Guide Monitor
in Extreme Trendelenburg P Position and Elevated Intrathoracic
Pressure for Prolonged Robotic Assisted Radical Prostatectomy R. F.
Ghaly MD, S. Saatee, MD, N. N. Knezevic, MD, PhD, A. Khorasani, MD,
K. D. Candido, MD Department of Anesthesiology, Advocate Illinois
Masonic Medical Center, Chicago, IL USA Abstract Case Description
Introduction Discussion 1. Edmonds HL Jr, et al. Semin Cardiothorac
Vasc Anesth 2004;8: Kalmar AF, et al. Br J Anaesth. 2010;104 : Park
EY, et al. Acta Anaesthesiol Scand. 2009;53: A 69-year-old man
presented for a robotic radical prostatectomy. This procedure which
requires prolonged extreme Trendelenburg position can compromise
venous return and promote brain swelling. We used brain oxygenation
monitor to record regional oxygen saturation (rSO 2 ) in both
hemispheres under scalp probe. Intrathoracic pressure rose from 22
cmH 2 O in a supine to 45 cmH 2 O in Trendelenburg position. rSO 2
was decreased only 4% on average during 5-hour surgery (average of
64% on the right and 74% on the left). The use of guided therapy
fluid restriction, vasopressors and intravenous anesthetics
(remifentanyl 0.5 mcg/kg/min and propofol 50 mcg/kg/min) can
prevent brain swelling during extreme Trendelenburg position and
elevated intrathoracic pressure. The use of Robotic Assisted
Radical Prostatectomy (RARP) improves the outcomes and reduces the
complications compared with open radical prostatectomy. Extreme
Trendelenberg (40) position for several hours which facilitates
this surgery plus CO 2 pneumoperitoneum potentially can cause
significant cardiovascular and neurophysiologic changes including
intracranial hypertension and reduction of cerebral tissue oxygen
saturation (SctO 2 ). Noninvasive cerebral oximtery is a technique
utilizing Near-Infrared Spectroscopy (NIRS) light ( nm) and can be
used to assess the continuous and non invasive monitoring of the
regional cerebral tissue oxygen saturation. Desaturation of more
than 10 scale below baseline or an absolute value of less than 50
are associated with decreased SSEP amplitude and is the threshold
for intervention. 1 A 69-year-old man, ASA class III with the past
medical history of poorly controlled hypertension treated by
Ramipril 10 mg/daily and Prostate CA (Gleason Score 7) presented
for RARP. The patient was premedicated with Midazolam 3 mg IV. Upon
arrival in the OR, standard monitoring was applied. Bilateral
frontal lobe brain O 2 saturation sensors were placed and the rSO 2
values recorded, continuously. Anesthesia was induced using
propofol 2mg/kg, fentanyl 3mcg/kg, succinylcholine 1mg/kg and the
trachea intubated. Arterial line was placed for beat to beat
monitoring of BP and the transducer was zeroed at external acoustic
meatus as a reflection of the base of the brain pressure.
Anesthesia was maintained with sevoflurane 0.5 MAC and propofol,
remifentanyl infusion (50 mcg/kg/min and 0.5 mcg/kg/min
respectively). The patient was slowly placed in steep Trendelenburg
position and the intraperitoneal pressure was adjusted as needed by
the surgeon. He was awakened in the operating room, transferred to
the PACU without any neurologic impairment and discharged after 3
days with a satisfactory condition. Previous reports indicated that
intracranial pressure and extracranial vascular pressure increases
during acute head down tilt and may cause cerebral edema. 1 Kalmar
demonstrated that in the first 5 min after Trendelenburg
positioning, CPP increases by 11 mmHg and then decreases modestly.
After resuming to supine position, CPP decreases by 12 mmHg that
recovered to its baseline within 3 minutes. 2 Park showed that in a
population of 32 patients going for daVinci RARP, rSO 2 increased
slightly, which suggests that the procedure did not induce cerebral
ischemia and was well tolerated by the majority of the patients. 3
Using TIVA technique, fluid restriction and vasopressors when
needed, will help to restore the rSO 2 as an indirect measure of
cerebral edema and ICP toward their baseline. Steep Trendelenburg
positioning during RARP have a potential to disrupt the normal,
tightly controlled balance between brain oxygen supply and demand.
Such disruption if not prevented and managed can result in brain
ischemia, presented from transient subtle cognitive decline to more
serious permanent functional impairments. Cerebral oximtery
provides noninvasive means of continually monitoring brain oxygen
imbalance and guiding interventions aimed at its correction
especially in patient that are at increased risk for position
related decline in rSO 2 such as patients with carotid stenosis,
previous TIA or stroke. Conclusions References
