Continuous Intraocular Pressure Patterns in Spine Surgery
NCT ID: NCT03299400
Last Updated: 2020-05-06
Study Results
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Basic Information
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COMPLETED
NA
10 participants
INTERVENTIONAL
2016-05-09
2017-05-09
Brief Summary
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IOP is known to increase in the prone position thus putting susceptible patients at risk for inadequate ocular nerve perfusion. Most of the evidence comes from animal and healthy volunteer studies and cannot give an accurate insight into the subtle changes of intra-operative IOP. All the published studies employed the use of a tonometer, which may have rooms for measurement errors due to inadvertent pressure on the globe while retracting the eyelids, particularly when there is significant periorbital/conjunctival swelling in the prone position. The majority of the studies recruited healthy volunteers in a simulated surgical setting so other fluctuating parameters, which can affect intraoperative IOP, cannot be measured. In the few reports where patients undergoing surgery in the prone position were studies, IOP measurements were taken at non-continuous monitoring at time intervals, thus the effects of changes in blood volume, MAP, central venous pressure (CVP) and PaCO 2 could not be studied. Lastly, all the literature consists of case series only with no control group so the effect of position cannot be evaluated independently of the other factors.
The investigators therefore propose to conduct a prospective study with continuous intraoperative IOP monitoring to give us further insight into the physiological changes of IOP in patients undergoing spine surgery, and identify the risk factors related to fluctuations of IOP during prone spinal surgery.
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Detailed Description
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One of the known associations is prone spinal surgery with a prolonged duration.
The cause is not completely understood, but some of the risk factors for developing POVL include anaemia, hypotension, the duration of surgery and patient factors such as age, hypertension and atherosclerosis. There are also some unidentifiablerisk factors that may predispose young healthy patients to POVL. Once the patient develops POVL, it is usually irreversible, and the patient is left with a permanent disability.
The majority of POVL cases that occur with prone spinal surgery are due to posterior ischaemic optic neuropathy (PION). PION is directly related to the ocular perfusion pressure (OPP), which is estimated as the difference between mean arterial blood pressure (MAP) and intraocular pressure (IOP). Autoregulation is believed to maintain a constant perfusion to the optic nerve despite fluctuations in the perfusion pressure.
However, there is a knowledge gap in the physiological changes of IOP during prone surgery. IOP is a highly dynamic parameter, and the most widely used method to measure it is using a handheld tonometer. The main limitation of this technique is the isolated nature of its measurements, as it can only be taken at regular intervals, and may not reflect the full range of IOP changes. Studies on IOP during prone position in the current literature have all used this technique. 1-5 Hence subtle changes of IOP can be undetected, as interval measurements cannot reflect short-term variations that occur within seconds or minutes. Furthermore, most of the studies are performed on animals or healthy volunteers 5,6 , which further limit the interpretation of their results. For the few studies performed on anaesthetised patients undergoing spinal surgeries, the duration of surgery is short or mixed, so the critical time point may not have been studied. The American Society of Anesthesiologists Postoperative Visual Loss Registry suggests that an anaesthetic duration of greater than 6 hours is more correlated with POVL.
Using state of the art technology Over the past five years, advances in technology have led to the development of devices that allow 24 hour continuous IOP monitoring. The new system makes use of microelectromechanical systems, nanotechnology, and telemetry to allow continuous monitoring. A disposable contact lens sensor, first proposed by Leonardi et al. 8 , is now commercially available (SENSIMED Triggerfish; Sensimed AG, Lausanne, Switzerland). This technology can acquire data points over a 24 hour period corresponding to 30 seconds of continuous measurements. It measures changes in the ocular dimensions at the corneoscleral junction, which corresponds to changes to IOP and volume. The microprocessor within the lens transmits data to an external antenna, and the profiles can be stored in a portable recorder. 9 Although this sensor does not measure IOP directly, it gives measurements with a composite of IOP and volume changes, and it is most valuable in documenting relative changes of IOP-related events and their timing. It is also well tolerated in real life patients, and have been used to document IOP changes in patients with glaucoma and thyroid eye disease. 9-11 This is the only non-invasive temporary continuous monitoring in the system that can be used in human beings. This new technology is therefore ideal in detecting subtle changes in IOP pattern in prone spinal surgery. It will provide a continuous monitoring which can be correlated with the patient's level of anaesthesia, arterial pressure fluctuations and volume status, and can contribute to improved understanding of IOP changes during prone spinal surgery, which may in turn bridge the knowledge gap of the causes of POVL.
Conditions
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Study Design
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NA
SINGLE_GROUP
Patient will undergo general anaesthesia for prone spinal surgery. The degree of inclination was set prior to the start of the case and independently confirmed using a goniometer. Patients will be placed in the prone position on a Jackson Spine table.
Once positioned, the head is carefully placed on the GentleTouch prone positioning pillow of the appropriate size.
Patient will continue to wear the contact lens postoperatively for a total of 24 hours or until the patient cannot tolerate the contact lens. After removal of the contact lens sensor, the recorded profiles will be collected and visualized graphically on a computer interface. The output of the sensor expressed in voltage, and can be analysed in real time points corresponding to the intraoperative events.
DIAGNOSTIC
NONE
Study Groups
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Contact lens sensor
Patient will continue to wear the contact lens postoperatively for a total of 24 hours or until the patient cannot tolerate the contact lens. After removal of the contact lens sensor, the recorded profiles will be collected and visualized graphically on a computer interface.
Contact lens sensor
Patient will continue to wear the contact lens postoperatively for a total of 24 hours or until the patient cannot tolerate the contact lens. After removal of the contact lens sensor, the recorded profiles will be collected and visualized graphically on a computer interface.
Interventions
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Contact lens sensor
Patient will continue to wear the contact lens postoperatively for a total of 24 hours or until the patient cannot tolerate the contact lens. After removal of the contact lens sensor, the recorded profiles will be collected and visualized graphically on a computer interface.
Eligibility Criteria
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Inclusion Criteria
* Age 18 to 80 years inclusive
* No pre-existing eye pathology (excluding refractive error), patients with glaucoma, history of eye injury or ophthalmic surgery
* No known allergy to contact lens material
* Patients undergoing anterior cervical spine surgery and prone spine surgery for duration of 3 hours or longer
Exclusion Criteria
* Cannot tolerate wearing contact lens
* Has active eye infection
18 Years
80 Years
ALL
No
Sponsors
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The University of Hong Kong
OTHER
Responsible Party
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Dr. Kenny Kwan
Clinical Assistant Professor
Principal Investigators
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Dr Kenny Kwan, BMBCh(Oxon)
Role: PRINCIPAL_INVESTIGATOR
The University of Hong Kong
Locations
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Duchess of Kent Children's Hospital
Hong Kong, , Hong Kong
Countries
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References
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Carey TW, Shaw KA, Weber ML, DeVine JG. Effect of the degree of reverse Trendelenburg position on intraocular pressure during prone spine surgery: a randomized controlled trial. Spine J. 2014 Sep 1;14(9):2118-26. doi: 10.1016/j.spinee.2013.12.025. Epub 2014 Jan 20.
Sugata A, Hayashi H, Kawaguchi M, Hasuwa K, Nomura Y, Furuya H. Changes in intraocular pressure during prone spine surgery under propofol and sevoflurane anesthesia. J Neurosurg Anesthesiol. 2012 Apr;24(2):152-6. doi: 10.1097/ANA.0b013e31823fe822.
Yoshimura K, Hayashi H, Tanaka Y, Nomura Y, Kawaguchi M. Evaluation of predictive factors associated with increased intraocular pressure during prone position spine surgery. J Anesth. 2015 Apr;29(2):170-4. doi: 10.1007/s00540-014-1921-8. Epub 2014 Sep 24.
Deniz MN, Erakgun A, Sertoz N, Yilmaz SG, Ates H, Erhan E. The effect of head rotation on intraocular pressure in prone position: a randomized trial. Braz J Anesthesiol. 2013 Mar-Apr;63(2):209-12. doi: 10.1016/j.bjane.2012.03.008. Epub 2013 Aug 13.
Walick KS, Kragh JE Jr, Ward JA, Crawford JJ. Changes in intraocular pressure due to surgical positioning: studying potential risk for postoperative vision loss. Spine (Phila Pa 1976). 2007 Nov 1;32(23):2591-5. doi: 10.1097/BRS.0b013e318158cc23.
Setogawa A, Kawai. Measurement of intraocular pressure by both invasive and noninvasive techniques in rabbits exposed to head-down tilt. Jpn J Physiol. 1998 Feb;48(1):25-31. doi: 10.2170/jjphysiol.48.25.
Postoperative Visual Loss Study Group. Risk factors associated with ischemic optic neuropathy after spinal fusion surgery. Anesthesiology. 2012 Jan;116(1):15-24. doi: 10.1097/ALN.0b013e31823d012a.
Leonardi M, Pitchon EM, Bertsch A, Renaud P, Mermoud A. Wireless contact lens sensor for intraocular pressure monitoring: assessment on enucleated pig eyes. Acta Ophthalmol. 2009 Jun;87(4):433-7. doi: 10.1111/j.1755-3768.2008.01404.x. Epub 2008 Nov 12.
Mansouri K, Weinreb R. Continuous 24-hour intraocular pressure monitoring for glaucoma--time for a paradigm change. Swiss Med Wkly. 2012 Mar 28;142:w13545. doi: 10.4414/smw.2012.13545. eCollection 2012.
Parekh AS, Mansouri K, Weinreb RN, Tafreshi A, Korn BS, Kikkawa DO. Twenty-four-hour intraocular pressure patterns in patients with thyroid eye disease. Clin Exp Ophthalmol. 2015 Mar;43(2):108-14. doi: 10.1111/ceo.12400. Epub 2014 Sep 29.
De Smedt S, Mermoud A, Schnyder C. 24-hour intraocular pressure fluctuation monitoring using an ocular telemetry Sensor: tolerability and functionality in healthy subjects. J Glaucoma. 2012 Oct-Nov;21(8):539-44. doi: 10.1097/IJG.0b013e31821dac43.
Other Identifiers
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UW 16-207
Identifier Type: -
Identifier Source: org_study_id
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