V08_No_3_Final_Last.pdf


Endourology and Stone Disease

191Urology Journal    Vol 8    No 3    Summer 2011

Prone Position in Percutaneous Nephrolithotomy 
and Postoperative Visual Loss
Mahvash Agah,1 Mahshid Ghasemi,2 Fatemeh Roodneshin,3 Badiozaman Radpay,3 
Siamak Moradian4 

Purpose: To study the simultaneous effects of prone position and anesthesia 
on intraocular pressure (IOP) and the time impact on post anesthesia visual 
loss development in percutaneous nephrolithotomy (PCNL). 
Materials and Methods: Twenty patients who were candidates for PCNL 
were recruited in this study. Intraocular pressure was measured in five 
occasions:

1. Base line; 2. Ten minutes after anesthesia (Supine-I); 3. Ten minutes 
after position change to prone (Prone-I); 4. At the end of the operation 
(Prone-II); and 5. Ten minutes after position change to supine  
(Supine-II).

The data were analyzed by SPSS software using repeated measures ANOVA 
and paired t test. 
Results: The participants consisted of 17 (85%) men and 3 (15%) women, 
with the mean age of 44 years. The duration of the prone position was 
79.75 ± 22.73 minutes. Intraocular pressure changed significantly in five 
positions (P = .000). It was lower in supine-I than baseline, higher in prone-I 
than base line and supine-I, lower in supine-II than prone-II, and highest in 
prone-II (P = .000). There was a linear relationship between IOP and prone 
position duration (r = 0.67; P = .001).
Conclusion: Intraocular pressure dropped significantly after anesthesia and 
increased in prone position. There was a linear relationship between IOP 
rise and the prone position duration, doubled within two hours. Therefore, 
in PCNL carried out in prone position, it is recommended to observe safety 
measures and necessary precautions for IOP rise and possible post anesthesia 
visual loss, particularly in glaucoma. 

Urol J. 2011;8:191-6. 
www.uj.unrc.ir

Keywords: intraocular pressure, 
percutaneous nephrolithotomy, 

prone position, vision acuity 

1Anesthesiology Research Center, 
Shahid Labbafinejad Medical 

Center, Shahid Beheshti University 
of Medical Sciences,Tehran, Iran

2Taleghani Medical Center, Shahid 
Beheshti University of Medical 

Sciences, Tehran, Iran
3Urology and Nephrology Research 

Center, Shahid Labbafinejad 
Medical Center, Shahid Beheshti 

University of Medical Sciences, 
Tehran, Iran

4Shahid Labbafinejad Medical 
Center, Shahid Beheshti University 

of Medical Sciences, Tehran, Iran

Corresponding Author:
Fatemeh Roodneshin, MD

Urology and Nephrology Research 
Center, Shahid Labbafinejad 

Medical Center, Shahid Beheshti 
University of Medical Sciences, 

Tehran, Iran
Tel/Fax: +98 21 2254 9029

E-mail: Dr_roodneshin_f2007@yahoo.com

Received December 2010
Accepted March 2011

INTRODUCTION
Of peri-operative complications, 
post anesthesia visual loss (PVL) 
is one of the most important ones 
reported in numerous articles. (1-6) 
Post anesthesia visual loss is an 
unfortunate, horrifying, and rare 
complication that is among the 
legal complaints.(7) It has been 
mostly reported in spinal surgeries 
and the prone position.(3)

Several factors, including 
hypotension, anemia, and the 
pressure on the eyes may lead to 
PVL.(2) However, some researchers 
have suggested that hemorrhage, 
changes in blood pressure, 
hematocrit level alterations, and 
the volume of fluid replacement 
during the operation might 
not be contributory factors in 
development of PVL.(7) Reduction 



Prone Position and Visual Loss—Agah et al

192 Urology Journal    Vol 8    No 3    Summer 2011

in eye’s perfusion, the volume of blood loss, and 
the replacement fluids have been mentioned as the 
most common factors that lead to PVL.

Ischemic optic neuropathy (ION), in which 
either the anterior (AION) or the posterior 
(PION) section of the nerve is involved, is the 
most common cause of PVL.(6) Ho and colleagues 
studied the ION after the spinal cord surgeries 
in prone position and reported that mostly 
the external part of the nerve was affected by 
ischemia and was frequently bilateral (40% for 
AION and 47% for PION).(8) 

Unfortunately, nowadays, the routine check of 
the optic nerve blood flow is not carried out.(7) 
The anterior and posterior sections of the nerve 
are supplied separately by the posterior branches 
of the ciliary artery and perforating arteries, 
respectively. Over 20% of normal populations 
have abnormal autoregulation that is undetectable 
clinically.(9) Blood vessels are compressible easily 
at the posterior section of the optic nerve and 
with the alteration in the eye perfusion pressure, 
some patients become susceptible to ION,(10,11) 
and atherosclerosis worsens the situation.(11) In 
normal patients, reduction in the eye perfusion in 
the range of autoregulation is tolerable, but in the 
existence of atherosclerosis, there is a possibility of 
blood flow reduction in the nerve,(12) and patients 
with vascular impairment are at higher risk of 
developing ION.(10,11) Optic nerve is sensitive to 
acute bleeding; nonetheless, acute hemodilution 
is not precarious and therefore there is no need to 
extra blood.(6,7) Hemodilution and hypotension are 
routine in open heart surgery, but PVL is rare.(7)

Generally, PVL is not caused by direct pressure 
on the eye globe, but the main factor is the effect 
of hemodynamic alterations on ocular perfusion 
pressure (OPP) that is the result of subtracting 
the intraocular pressure (IOP) from mean arterial 
pressure (MAP); OPP = MAP – IOP.(13) Yet in 
ocular perfusion, the attention has been focused 
more on holding MAP normal or high, and IOP 
has been left relatively unnoticed, since even if 
MAP is steady, a high IOP prevents a proper 
OPP. Hypotension also decreases IOP, which in 
turn reduces OPP.(14)

In a study on the effect of position on IOP in 

awake patients, the pressure raised from 13.5 
mmHg in supine position to 20 mmHg in the 
prone position.(15) Prone position causes an 
increase in the peritoneal pressure with subsequent 
increase in IOP, peak inspiratory pressure (PIP), 
and central vein pressure. In the patients not 
suffering from glaucoma, the peritoneal pressure 
during the laparoscopic surgery did not yield 
increased IOP in the lithotomy position,(16) 
but IOP increased in glaucomatous rabbits.(17) 
Intraocular pressure showed an increase in the 
anesthetized patients and the awake volunteers 
in the supine position with low head placement 
(Trendelenburg). The mechanism is the rise in the 
episcleral venous pressure.(9) Furthermore, general 
anesthesia reduces IOP.(18) The rise in PaCO2 
could increase IOP during the general anesthesia 
in the supine position,(19) but PaCO2 does not 
change substantially during general anesthesia.(20) 
In a study, the rises of PaCO2 and end-tidal carbon 
dioxide concentration (ETCO2) in the prone 
position were reported.(21) The balance between 
the prone position and general anesthesia plays an 
important role in OPP.

Percutaneous nephrolithotomy (PCNL) is 
relatively a new technique and the treatment 
of choice for removing stones in the kidney, 
proximal ureter, inferior pole of the kidney, or 
infundibulopelvic and the stones accompanied by 
the evidence of obstruction. This operation usually 
results in low blood loss and the overall need for 
blood transfusion is less than 10%.(22) To carry out 
this operation, there is mostly a need to general 
anesthesia. Although PCNL is usually completed 
in prone position, performing it in the supine and 
flank positions is still under debate.(23-26)

The aim of this study was to investigate the 
simultaneous effects of anesthesia and prone 
position on IOP during PCNL and the risk of 
developing PVL.

MATERIALS AND METHODS
This study was a non-controlled, non-
randomized, and non-blinded (pre post quasi-
experimental design) clinical trial that was 
carried out on 20 patients candidate for PCNL. 
All of them were in American Society of 
Anesthesiologists (ASA) class I to III. The written 



Prone Position and Visual Loss—Agah et al

193Urology Journal    Vol 8    No 3    Summer 2011

informed consents were obtained from each 
participant.

Patients with a history of either eye disease or 
eye surgery were excluded from the study. The 
demographic and clinical data were collected 
using a questionnaire.

All the patients had hematocrits above 30% and 
the duration of patients’ fasting was 8 hours. 
First, electrocariography monitors, non-invasive 
sphygmomanometer, pulse oximetry, and nerve 
stimulator were connected to the patient. Both 
eyes were anesthetized by 0.5% tetracaine. Before 
prescription of any premedication, the pressures 
of both eyes were measured in supine position by 
Tono-Pen XL hand-held applanation tonometer 
(Baseline). The mean of 4 measurements with 
the right standard deviation of less than 5% was 
acceptable that otherwise the measurement was 
repeated. 

Anesthesia protocol was the same for all the 
patients and achieved as follows: Premedication 
with xylocaine 1.5 mg/kg and fentanyl 1 to 2 μg/
kg. Induction with nesdonal 3 to 5 mg/kg and 
atracurium 0.5 mg/kg and the continuation of the 
anesthesia by fentanyl 1 to 2 μg/kg/h infusion, 
halothane 0.5% to 0.6%, and N2O 50%.

Mean arterial pressure was regulated at the range 
of 20% of wakefulness and ventilation on the 
basis of ETCO2 30 to 35 mmHg. In order to 
maintain the intravascular volume during the 
operation, in addition to the precise compensation 
of the hemorrhage, 5 mL/kg normal saline was 
prescribed for each patient. Any subject with the 
hemorrhage of greater than 1000 cc was excluded 
from the study. By controlling train of four, the 
timing for intubation and the re-prescription of the 
muscle relaxants were determined that in the case 
of the existence of more than one twitch, muscle 
relaxant (0.1 mg/kg) was repeated. Particularly, 
at the time of the position change, patient was 
sustained flaccid and in deep anesthesia.

The IOP was measured in the following stages:

1. Awakeness and in supine position (Baseline)

2. Ten minutes after induction and in supine 
position (Supine-I)

3. Ten minutes into acquiring prone position 
(Prone-I)

4. At the end of the operation in prone position 
(Prone-II)

5. Ten minutes into acquiring supine position 
(Supine-II) before the reverse injection and the 
change in depth of anesthesia

Simultaneously, in the above-mentioned stages, 
PIP, end-tidal halothane (ET Hal), ETCO2, pulse 
rate, saturation of peripheral oxygen (SPO2), and 
MAP were measured as well.

The XL hand-held tonometer was calibrated after 
each use. The change of position was carried 
out by the same team, considering all necessary 
precautions gently for all the patients. Applying 
pressure on the eyes was avoided during the prone 
position and a gelatinous head ring was placed 
under the patient’s head without any contact 
with the eyes. The method of operation was 
unchanged. The surgeon, surgical equipment, the 
evaluators, and persons who collected the data 
were the same for all the patients.

The patients were questioned concerning the 
visual acuity or any other visual disturbances 
in both eyes in the recovery room. Pre and 
postoperative hematocrit level as well as urine 
output and blood loss were measured. 

The data were analyzed by SPSS software (the 
Statistical Package for the Social Sciences, version 
11.0, SPSS Inc., Chicago, Illinois, USA) using 
repeated measures ANOVA and paired t test. 
P values less than .05 were considered significant.

RESULTS
The participants consisted of 17 (85%) men and 3 
(15%) women, with the mean age of 44 years. The 
duration of the prone position was 79.75 ± 22.73 
minutes. No significant differences were observed 
regarding PIP, ETCO2, MAP, SPO2, and ET Hal 
in the five stages.

Since the statistical differences were unavailable 
between the right-eye and the left-eye IOPs, we 
considered the left-eye IOP in our calculations. 
The measured IOP ranged between 12 and 40 
mmHg and it was observed that IOP changed 



Prone Position and Visual Loss—Agah et al

194 Urology Journal    Vol 8    No 3    Summer 2011

significantly in the five positions (P = .000). 
The IOP in supine I (12.5 ± 0.5 mmHg) was 
lower than the baseline (15.42 ± 0.9 mmHg) 
(P = .000). The intraocular pressure in prone 
I (25.5 ± 1.5 mmHg) was higher than supine I 
and the baseline (P = .000). The IOP in prone II 
(38.9 ± 0.9 mmHg) was higher than all previous 
measurements (P = .000). The IOP in supine 
II (13.7 ± 0.4 mmHg) was lower than prone II 
(P = 0.000) (Table and Figure). There was a linear 
relationship between the IOP and duration of the 
prone position (r = 0.67; P = 0.001) that the IOP 
rose as the time elapsed. 

DISCUSSION
To the best of our knowledge, this study is the 
first one on the IOP in PCNL and the effect of the 
duration of the prone position on the anesthetized 
patients. In this study, anesthesia reduced the 
IOP, which is in line with other studies showing 
that administration of anesthetic drugs, such as 
nesdonal and atracurium, resulted in reduction of 

the IOP.(27) The other finding is that the position 
change to prone leads to alteration of the IOP in 
a way that not only it compensates the reducing 
effects of the anesthetic drugs in 10 minutes, but 
also exceeds the baseline. The effects of the prone 
position have also been demonstrated in a study 
by Lam and Douthwaite, in which the IOP raised 
within 8 minutes after the change of position to 
prone.(15) They carried out the trial on awake 
volunteers. Our study showed that the increasing 
effect of the prone position on IOP is stronger than 
the reducing effects of general anesthesia on IOP. 

The most accurate method of measuring IOP 
over the time is its continuous and invasive 
measurement. This type of recording IOP has been 
reported in two groups of patients by implanting 
a probe into the anterior chamber of the eye for 
96 hours.(28) However, we utilized Tono-Pen XL 
similar to the study by Lam and Douthwaite.(15) 
The accuracy of this device in comparison with the 
invasive method of probe implantation has been 
demonstrated by Setogawa and Kawai.(29) Rises in 
PaCO2 and EtCO2 have been reported in the prone 
position.(21) Since the rise of the PaCO2 could 
increase the IOP,(21) we kept PaCO2 unchanged 
from the beginning to the end of the anesthesia in 
order to abolish its interfering effects.

A number of researchers induced a rise in the IOP 
by increasing the acute fluid administration. (25) 
In our study, we compensated not only the 
fluid loss, but also the patients received 5cc/
kg/h of fluid. The point that the intravascular 
volume change is capable of changing the IOP 
requires prospective studies.(27) Nonetheless, we 
maintained the fluid balance and the intravascular 
volume in a steady state in order to prevent the 
possible effects of the intravascular volume.

Unlike the study by Pillunat and colleagues, 

95% Confidence  
Interval for MeanStd. ErrorStd. DeviationMean (Range), mm/HgN

15.01 to 15.83.1963.877715.42 (14.00 to 17.00)20Base line
12.31 to 12.78.1141.510412.55 (12.00 to 13.00)20Supine I
24.83 to 26.26.34391.538125.55 (20.00 to 28.00)20Prone I
38.50 to 39.39.2112.944538.95 (37.00 to 40.00)20Prone II
13.54 to 13.959.934E-02.444313.75 (13.00 to 14.00)20Supine II
19.20 to 23.201.007010.069621.24 (12.00 to 40.00)100Total

Patients’ mean intraocular pressures in five occasions 

50

40

30

20

10

95
%

 C
on

fid
en

ce
 In

te
rv

al
 o

f I
nt

ra
oc

ul
ar

 P
re

ss
ur

e

GROUPS

N - 20 20 20 20 20
Base Line Supine I Prone I Prone II Supine II

Patients’ mean intraocular pressures in five positions in 
percutaneous nephrolithotomy



Prone Position and Visual Loss—Agah et al

195Urology Journal    Vol 8    No 3    Summer 2011

our patients were in a position completely in 
parallel to the horizontal surface, and therefore, 
the effects of increase or decrease in episcleral 
intravenous pressure due to the Trendelenburg 
position could not be measured in our study.(9)

Fortunately, we did not observe any visual loss 
after anesthesia, but the first reported case of PVL 
after PCNL in the Labbafinejad Medical Center 
was a 75-year-old man with the history of diabetes 
mellitus, hyperlipidemia, and mild anemia. The 
patient had painless PVL in both eyes limited to 
light perception immediately after the operation. 
In ophthalmologic examination, the optic disc 
was pink without swelling and visual fields were 
severely affected; however, neuroimaging was 
normal. The visual fields and acuity improved 
dramatically in a matter of three months, but 
optic disc turned slightly pale and this was the 
first report of PION after PCNL.(30)

According to the report by Roth and Barach, 
there is a possibility of PVL in the prone position, 
with hypotension, anemia, and direct pressure 
to the eyeball as risk factors.(7) In our study, we 
have avoided all the three mentioned factors and 
the fact that whether or not it is the reason for no 
visual loss after anesthesia is not assessable with this 
number of patients and it requires further studies.

On the other hand, it does not seem that acute 
hemodilution is precarious. Since hemodilution 
occurs frequently in open heart surgery, but 
visual loss usually occurs after the spinal surgeries 
in prone position.(22) In a study on 20 anesthetized 
patients in spinal surgery in prone position, 
Hunt and coworkers reported the rise in the 
IOP. Nevertheless, the duration of the operation, 
age, and body mass index have been mentioned 
as non-contributory factors.(31) According to 
the report of Ho and colleagues in assessing the 
reasons for ION duration, the prone position has 
been lengthy in all the subjects with the average 
of 450 minutes, which points to the time factor 
in the development of ION in prone position. (8) 
Also the reduction of OPP, intra-operative 
bleeding, anemia or hemodilution, and the 
infusion of large amounts of intravascular fluids 
are among the aggravating factors in ION.(8)

In healthy volunteers, IOP increases with the 

acute rise in the fluid load,(25) and dehydration due 
to physical exercise reduces IOP.(32) The reduction 
in osmolarity during dialysis also increases 
IOP. (33) Prospective studies are required in order 
to demonstrate the relationship between the fluid 
balance and IOP in prone position.(27)

In a comprehensive literature review on visual 
loss after non-ocular surgeries, it has been 
reported that risk of decrease in visual acuity and 
visual ability rises in case of preexisting diseases, 
such as hypertension, diabetes mellitus, sickle 
cell anemia, renal failure, gastrointestinal ulcer, 
narrow-angle glaucoma, vascular occlusive disease, 
cardiac disease, arteriosclerosis, polycythemia 
vera, and collagen vascular disorders. 
Furthermore, the precipitating factors for ION 
include prolonged hypotension, anemia, surgery, 
trauma, gastrointestinal bleeding, hemorrhage, 
shock, prone position, direct pressure on the 
globe, and long operation time.(34)

In our study, the effect of the duration of the prone 
position on the rise of IOP was significant and 
other factors were ruled out. All the patients had 
the blood pressures of above 120 mmHg during 
the operation. By maintaining other conditions 
unchanged, it was tried to study the effect of the 
duration of the prone position on IOP in PCNL. 
After doubling the IOP from the normal level,(35) 
the risk of damage to the optic nerve starts, and 
according to our study the IOP was doubled and 
reached up to 40 mmHg after two hours.

CONCLUSION
Since in PCNL the rise of IOP in the prone 
position has a linear relationship with time and 
doubles within two hours, it is recommended that 
in the prone position surgeries, special attention 
has to be focused on the IOP. Prospective larger 
studies on the IOP with different setting are 
needed to confirm our results.

CONFLICT OF INTEREST
None declared.

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