A Prospective Randomized Controlled Trial on the Use of Cerebral Oximetry in Adult Chinese Patients Undergoing Liver Transplantation
Paraules clau
Resum
Descripció
Liver Transplant Liver transplantation (LT) is a life-saving procedure for patients with end-stage liver disease. Despite continuous advancement in technology, it remains a high-risk operation. The building-up of an oxygen debt during LT can lead to an increased risk of poor postoperative outcomes (1, 2). Furthermore, patients with acute liver failure or end-stage liver disease are prone to hepatic encephalopathy, which can lead to disturbance of auto-regulation in the brain, which may eventually cause cerebral hypoxia and ischaemia. Irresversible metabolic disturbances can impair cerebral auto-regulation, causing poor neurological outcomes after LT (3). The prevalence of encephalopathy, delirium and stroke in transplant recipients is 12-40% (3). Hypotheses for these conditions include prolonged stay in the intensive care unit (ICU) (so-called "ICU psychosis"), the use of Tacrolimus (4), rapid correction of hyponatraemia (5) and impaired cerebral auto-regulation (3), but no definite conclusion can be made most of the time. Among these hypotheses, impairment of cerebral auto-regulation has never been documented in large clinical trials for Chinese patients in LT.
Cerebral oximetry (Near infra-red spectroscopy, NIRS) There is no "gold standard" for measuring cerebral auto-regulation. Monitoring of the brain oxygenation, such as direct tissue O2 tension and jugular bulb O2 saturation, has been used as a surrogate of auto-regulation but it is invasive. Transcranial laser Doppler (TCD) of the middle cerebral artery has been validated in healthy volunteers as well as real patients as a good measurement of cerebral blood flow (6, 7). Similarly, near-infrared spectroscopy (NIRS), a non-invasive and continuous method, can also monitor the regional cerebral oxygenation (rScO2) and is increasingly used in cardiac surgery. A previous report has validated the use of NIRS when compared to TCD, as the latter requires a trained technician to monitor and supervise. NIRS provides a timely, real-time, inexpensive, easily measurable alternative to TCD, and thus should have a great potential for clinical usage in LT. Similar to other non-invasive oximetry (e.g. pulse oximetry), measurement can be done through adhesive tapes over bilateral forehead and connected to the machine (INVOS™ 5100C Cerebral/Somatic Oximeter by Covidien). This system is the ONLY cerebral/somatic oximetry system with FDA cleared improved outcome claims (8). Plachky et al. showed that 50% of patients demonstrated a decline in cerebral oxygen saturation when clamping of the vessles during LT and it had positive correlation with the postoperative cerebral disrubances (9). Nonetheless, the clinical application for patients undergoing LT is scarce and its application is novel. The use of this technology may potenitally be limited by the presence of high levels of bilirubin acting as a chromophore interferring with its data acquistion. However, in a pilot study of 9 patients who underwent LT investigators using this technology were able to demonstrate that 3 out of 9 patients had either transient or persistent impaired auto regulation throughout the operation. This in turn was associated with higher Model of End-Stage Disease Score (MELD) >15 (p=0.015), more postoperative seizures and stroke (P<0.0001) (3). A recent systematic review (10) of 901 Caucasians from 24 publications showing a decrease in NIRS (>15% relative to baseline) could have impaired postoperative cognitive function (28 versus 26; MMSE) and reduced LOS (14 versus 23 days) in open surgery. In the field of LT, impaired cerebral autoregulation (25%), cerebral deoxygenation in the anhepatic phase (36%) and cerebral hyperoxygenation with reperfusion of the grafted liver (14%) were identified by NIRS and could lead to adverse neurological outcome such as seizures, transient hemiparesis and stroke. Nonetheless, no large prospective randomized trial and no Chinese cohort were included.
References
1. Shoemaker WC, Appel PL, Kram HB. Role of oxygen debt in the development of organ failure sepsis, and death in high-risk surgical patients. Chest. 1992;102(1):208-15.
2. Shoemaker WC, Appel PL, Kram HB. Hemodynamic and oxygen transport responses in survivors and nonsurvivors of high-risk surgery. Critical care medicine. 1993;21(7):977-90.
3. Lescot T, Karvellas CJ, Chaudhury P, Tchervenkov J, Paraskevas S, Barkun J, et al. Postoperative delirium in the intensive care unit predicts worse outcomes in liver transplant recipients. Can J Gastroenterol. 2013;27(4):207-12.
4. DiMartini AF, Trzepacz PT, Pajer KA, Faett D, Fung J. Neuropsychiatric side effects of FK506 vs. cyclosporine A. First-week postoperative findings. Psychosomatics. 1997;38(6):565-9.
5. Lee J, Kim DK, Lee JW, Oh KH, Oh YK, Na KY, et al. Rapid Correction Rate of Hyponatremia as an Independent Risk Factor for Neurological Complication Following Liver Transplantation. Tohoku J Exp Med. 2013;229(2):97-105.
6. Lang EW, Mehdorn HM, Dorsch NW, Czosnyka M. Continuous monitoring of cerebrovascular autoregulation: a validation study. Journal of neurology, neurosurgery, and psychiatry. 2002;72(5):583-6.
7. Ono M, Zheng Y, Joshi B, Sigl JC, Hogue CW. Validation of a stand-alone near-infrared spectroscopy system for monitoring cerebral autoregulation during cardiac surgery. Anesthesia and analgesia. 2013;116(1):198-204.
8. 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. Anesthesia and analgesia. 2007;104(1):51-8.
9. Plachky J, Hofer S, Volkmann M, Martin E, Bardenheuer HJ, Weigand MA. Regional cerebral oxygen saturation is a sensitive marker of cerebral hypoperfusion during orthotopic liver transplantation. Anesth Analg. 2004;99(2):344-9.
10. Sorensen H, Grocott HP, Secher NH. Near infrared spectroscopy for frontal lobe oxygenation during non-vascular abdominal surgery. Clin Physiol Funct Imaging. 2016;36(6):427-35.
Dates
Darrera verificació: | 09/30/2019 |
Primer enviat: | 10/08/2019 |
Inscripció estimada enviada: | 10/08/2019 |
Publicat per primera vegada: | 10/09/2019 |
Última actualització enviada: | 10/08/2019 |
Publicació de l'última actualització: | 10/09/2019 |
Data d'inici de l'estudi real: | 07/29/2018 |
Data estimada de finalització primària: | 05/30/2020 |
Data estimada de finalització de l’estudi: | 05/30/2020 |
Condició o malaltia
Intervenció / tractament
Other: Cerebral oximeter
Fase
Grups de braços
Braç | Intervenció / tractament |
---|---|
Active Comparator: Control Patients undergoing liver transplantation without regional cerebral oxygenation monitoring using a cerebral oximeter. | |
Active Comparator: Intervention Patients undergoing liver transplantation with regional cerebral oxygenation monitoring using a cerebral oximeter. |
Criteris d'elegibilitat
Edats elegibles per estudiar | 18 Years Per a 18 Years |
Sexes elegibles per estudiar | All |
Accepta voluntaris saludables | Sí |
Criteris | Inclusion Criteria: - Able to get informed consent by patient - Patients undergo DDLT or LDLT at Department of Surgery, Liver Transplant Centre, The University of Hong Kong, Queen Mary Hospital - Ethnicity is Chinese Exclusion Criteria: - Refusal of consent by patient - Pre-existing neurological damage, history of seizures and on antidepressants - Skin conditions over forehead that precludes the application of sensors of equipment - Ethnicity is not Chinese |
Resultat
Mesures de resultats primaris
1. Duration of confusion as assessed by the Confusion Assessment method [48 hours after liver transplant]
Mesures de resultats secundaris
1. The time taken for MOCA to return to baseline [10 days after liver transplant]
2. Other complications unrelated to neurological deficit according to Clavien-Dino Classification. [2 years]