V07_No_4.pdf


Urological Oncology

243Urology Journal   Vol 7   No 4   Autumn 2010

Radical Prostatectomy Practice in England
Vishwanath S Hanchanale, John E McCabe, Pradip Javlé

Purpose: As there is paucity of data on radical prostatectomy (RP) as a 
primary treatment for patients with localized prostate cancer, we analyzed 
the trends in the RP practice in England.
Materials and Methods: This study was carried out on 14 300 patients who 
underwent RP for carcinoma of the prostate. Database was prepared from 
hospital episode statistics of the Department of Health in England. National 
trends in RP practice were summarized as well as volume outcome analysis.
Results: Annual number of RPs exponentially increased from 972 (1998 to 
1999) to 3092 (2004 to 2005). Laparoscopic RPs increased from 2 to 257 over 
the study period. Median waiting duration increased by more than 10 days 
(13 days). Significant decrease in median length of hospital stay from 8 (range, 
7 to 10) days to 6 (range, 5 to 8) days was observed (P < .001). More than 

correlation was found between the hospital volume (Odds Ratio: 0.40) and 

0.32) and shorter in-hospital stay in comparison to low volume surgeons and 
hospitals.
Conclusion: There is an exponential increase in the number of RPs with 
an increasing trend towards laparoscopic RP in England. This study showed 
a significant inverse correlation between provider volume (hospital and 
surgeon) and outcome (in-hospital mortality and hospital stay) for RP in 
England; thus, supporting the recommendations for centralization of care for 
complex radical procedures, including RP.

Urol J. 2010;7: -8.
www.uj.unrc.ir

Keywords: prostatic neoplasms, 
prostatectomy, laparoscopy, 
treatment outcome, England 

Department of Urology, Leighton 

Corresponding Author:

MS, MRCS
Department of Urology, Leighton 

United Kingdom

E-mail: vishwanath.hanchanale@gmail.com

Received October 2009
Accepted March 2010

INTRODUCTION
Prostate cancer is the most 
frequently diagnosed cancer in 
men in England.(1) With increasing 
patients’ awareness and widespread 
prostate-specific antigen testing, 
more than 650 000 men worldwide 
and approximately 26 000 men 
in England are diagnosed with 
prostate cancer every year. Each 
year, an estimated 221 000 deaths 
worldwide occur from the prostate 
cancer, with over 8000 of such 
deaths being recorded annually 
within the United Kingdom.(2)

Radical prostatectomy (RP) is 
widely used as a primary treatment 
in patients with localized prostate 
cancer.(3) Due to improvements 
in anesthesia, peri-operative care, 
and surgical technique, RP is now 
associated with lower morbidity 
than early years.(4) With wide 
array of new treatment options 
for the prostate cancer, RP can 
only remain a preferred treatment 
modality if it is associated with 
low morbidity, mortality, and 
short hospital stay. As there is 
paucity of data on RP trends in 



Radical Prostatectomy Practice—Hanchanale et al

244 Urology Journal   Vol 7   No 4   Autumn 2010

England, we addressed the temporal changes in 
the RP practice in England over 7 years. This 
study describes the changing trends in patients’ 
demographics, surgical activity, and outcomes 
(mortality rate and length of hospital stay) for 
RP.

MATERIALS AND METHODS
A total of 14 300 patients who underwent RP 
for carcinoma of the prostate by 592 surgeons 
at 191 hospitals between April 1998 and April 
2005 were included in this study. Database was 
prepared from Hospital Episode Statistics (HES) 
of Department of Health in England. 

National administrative databases have been used 
increasingly in the USA (Medicare) and Europe 
(Dutch National Medical Register) to investigate 
the quality of surgical care.(5,6) Hospital Episode 
Statistics is the national database of all the patients 
admitted to National Health Service (NHS) 
hospitals in England. It has evolved over the years 
following its establishment in 1989 and is the data 
source for a wide range of healthcare analysis 
for the NHS, government, and many other 
organizations and individuals.(7) Hospital Episode 
Statistics also forms an important tool for medical 
research, assessment of performance, and policy 
development.(8-12)

Diagnostic coding is recorded based on the 
International Classification of Diseases, 10th
revision (ICD-10) criteria and procedure coding is 
recorded according to the Office of Population, 
Census and Surveys – Classification of Surgical 
Operations and Procedures, 4th revision (OPCS4) 
criteria.(13,14)

At the outset, database was filtered for malignant 
neoplasm of the prostate by ICD-10 code C61-X 
in seven diagnostic fields and then OPCS4 codes, 
indicating total excision of the prostate along with 
the capsule (M61-1), retropubic prostatectomy 
(M61-2), perineal prostatectomy (M61-4), RP 
other specified (M61-8), and RP unspecified 
(M61-9) in four operative fields. Furthermore, 
laparoscopic procedures were identified by 
procedure codes Y50X and Y71X in four 
operative fields.

Patients’ outcomes were analyzed in various age 

groups. The major outcome variables of this 
study were mortality rate and length of hospital 
stay. Patients’ characteristics and national trends 
for RP over the 7-year study period were also 
assessed.

Each hospital and surgeon has a unique 
identification code in the HES database. Using 
these codes, we analyzed the volume outcome 
relationship for hospital and surgeon volume in 
England. Annual hospital and surgeon volume 
thresholds were determined by dividing the 
patients into two equal-sized groups of high and 
low volume, based on the median volume (50th
percentile), ie, 26 and 16 for hospital and surgical 
caseload, respectively.

Statistical Analysis
Statistical analysis was performed using SPSS 
(Statistical Package for the Social Science, version 
13.0, SPSS Inc, Chicago, Illinois, USA) and 
NCSS-Pass (Number Cruncher Statistical System 
and Power Analysis and Sample Size (Kaysville, 
Utah, USA, 2004) softwares. One way ANOVA, 
Chi-square, and Kruskal-Wallis tests were used 
for univariate analysis if appropriate. Multiple 
logistic regressions were used to get the risk-
adjusted multivariate analysis for both in-hospital 
mortality and length of hospital stay. Age, waiting 
time, admission method (emergency or elective), 
annual surgeon volume, and annual hospital 
volume were the independent variables used 
for the risk adjustment. All P values were two-
sided and P values less than .05 were considered 
statistically significant. Independent variables 
with P values less than .1 in the univariate analysis 
were included in the multivariate analysis. The 
multivariate models were tested for goodness of 
fit using the Hosmer-Lemeshow test.

RESULTS
The mean age (± SD) of the patients was 62.7 
(± 6.1) years. A total of 33 in-hospital deaths 
were reported, giving an overall mortality rate 
of 0.23%. The median waiting duration (date 
of decision to operate to date of admission for 
operation) and median length of hospital stay 
for patients having RP were 39 days and 7 days, 
respectively.



Radical Prostatectomy Practice—Hanchanale et al

245Urology Journal   Vol 7   No 4   Autumn 2010

National Trends
The number of RPs has increased from 972 to 
3092 over the study period. Proportionately, 
laparoscopic RP has increased from 2 (1998) to 
257 (2004) (Figure 1). Patients’ characteristics 
over the study period are described in Table 1.
The mean age of the patients has decreased 
significantly over the same period (P = .001). 
There was an increase of 13 days in the median 
waiting duration (P < .001). In-hospital mortality 
rate was very low with significant reduction over 
the study period (P = .029). Median length of 
hospital stay has decreased from 8 days to 6 days.

The number of hospitals performing RP has been 
nearly constant over the study period and in 
contrast, number of surgeons performing RP has 
increased from 194 to 234 (Figure 2). The median 
hospital volume has increased by 2.6 times 
(P < .001) (Figure 3) and similarly median 

surgeon volume has increased significantly from 8 
to 20 (P < .001) over the 7 years (Figure 4).

Patients’ age had a significant impact on clinical 
outcomes and waiting time (Table 2).  Median 

Variable
Year

Test (P)
1998 1999 2000 2001 2002 2003 2004

Mean Age ( ± SD), 
years

63.3 (6.4) 62.8 (6.0) 62.7 (6.1) 62.7 (5.9) 62.4 (6.1) 62.5 (6.0) 62.6 (5.9) ANOVA ( .001)

Median (IQR) Waiting
time, days

32
(19 to 50)

34
(21 to 50)

39
(21 to 57)

38
(22 to 57)

40
(25 to 59)

40
(25 to 61)

45
(27 to 69)

Kruskal Wallis = 
242.911, 6df (< .001)

In-hospital mortality,
n (%)

6 (0.62) 2 (0.16) 8 (0.50) 4 (0.19) 4 (0.16) 3 (0.11) 6 (0.10)
( .029)

Median (IQR) Length of 
Stay, days

8
(7 to 10)

8
(6 to 9)

7
(6 to 9)

7
(6 to 9)

7
(5 to 8)

6
(5 to 8)

6
(5 to 8)

Kruskal Wallis= 764.885, 
6df (< .001)

Number of Hospitals, n 120 126 122 122 122 119 122 –
Number of Surgeons, n 194 204 212 226 234 242 234 –

*IQR indicates interquartile range.

Table 1. Patients’ characteristics for radical prostatectomy over 7-year study period

Figure 1. National trends of radical prostatectomy (RP and LRP)
in England.

Figure 2. Trends for total number of surgeons and hospitals 
performing radical prostatectomy in England.

Figure 3. Error bar representing the annual hospital volume over 
the study period.



Radical Prostatectomy Practice—Hanchanale et al

246 Urology Journal   Vol 7   No 4   Autumn 2010

waiting time (interquartile range) in patients 

17 to 53 days) and 41 days (range, 24 to 65 days), 
respectively. Ninety-five percentage of mortality 

younger (< 50 years) patients. Elderly patients 

to younger ones (< 50 years).

Volume Outcome Relationship
In univariate analysis, mortality rate was 

year) hospitals compared to low volume 
(< 26 RP/year) hospitals (0.10% versus 0.30%, 
P < .05). In the risk adjusted multivariate 
analysis, mortality rate was significantly lower 
when comparing high volume to low volume 
hospitals (Odds Ratio: 0.40, 95% Confidence 
Interval: 0.17 to 0.90, P = .028). Similarly, 
high volume surgeons had significantly lower 
mortality in comparison to low volume surgeons 
(0.10% versus 0.40%, P < .01). In the risk 
adjusted multivariate analysis, mortality rate was 
significantly lower when comparing high volume 
to low volume surgeons (Odds Ratio: 95% 
Confidence Interval: 0.13 to 0.75, P = .009). The 

median length of hospital stay was lower for high 
volume hospitals in comparison to low volume 
hospitals. Likewise, high volume surgeons had 
shorter in-patient stay than low volume surgeons.

DISCUSSION
In proportion to the increase in number of 
newly diagnosed prostate cancer cases,(1) the 
annual number of RPs has increased by more 
than threefold over 7 years. An increasing trend 
towards laparoscopic RP over the study period 
was noted. In-hospital mortality and length of 
hospital stay was lower in younger patients and 
later years of study. Furthermore, mortality rate 
and length of in-patient stay was lower in patients 
treated by high volume surgeons and at high 
volume hospitals.

Our patients’ demographics are similar to 
previous population-based studies from the 
USA. (15,16) Mortality rate from RP has been 
very low for many years, with majority of 
academic centers reporting 0% to 0.42%.(17-19)
Overall mortality rate of 0.23% (present study) 
is comparable to the studies from the USA 
(0.25%). (16) Further reductions in the mortality 
rate (0.62% to 0.10%) over the study period could 
be attributed to the increase in surgical caseload 
and improvements in peri-operative care. Length 
of stay is higher than medicare population-based 
studies from the USA by one day.(16) Hu and 
colleagues suggested that surgeon volume is 
inversely related to in-hospital complications and 
length of stay in men undergoing RP.(20) Litwin 
and associates reported that length of stay can 
be further decreased by 28% with clinical care 
pathway design.(21) Present study has shown a 
significant difference in the mortality rate and 
length of hospital stay between the high and low 
volume groups in England. This analysis supports 

Variable
Age range

Test (P)
<50 50 to 59 60 to 69

Total, n 283 3930 8572 1515 –
Median (IQR) waiting time, days 34 (17 to 53) 38 (23 to 57) 40 (24 to 60) 41 (24 to 65) Kruskal Wallis = 36.223, 

3df (< .001)
In-hospital mortality, n (%) 0 2 (0.05) 17 (0.19) 14 (0.92)
Median (IQR) length of stay, days 6 (5 to 8) 7 (5 to 8) 7 (5 to 9) 7 (6 to 9) Kruskal Wallis= 136.935, 

3df (< .001)

*IQR indicates interquartile range.

Table 2. Clinical outcomes of radical prostatectomy in various age groups

Figure 4. Error bar representing the annual surgeon volume 
over the study period.

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Radical Prostatectomy Practice—Hanchanale et al

247Urology Journal   Vol 7   No 4   Autumn 2010

the volume outcome relationship studies from 
Northern America for RP.(3,16)

There was a significant increase in the number of 
surgeons with almost no change in the number 
of hospitals performing RP over the study 
period. The drift towards centralization has been 
supported by the significant increase in the annual 
hospital and surgeon volume.

Administrative databases are important resources 
for health services research. However, because 
the data were collected for reasons other than 
answering specific research questions, the 
conclusions must be balanced with caveats. 
In-hospital mortality rate obtained from HES 
database, in contrast to 30 or 60-day mortality 
rate, could be deceptive; as hospitals with early 
discharge policy have higher re-admission rate and 
higher 30-day mortality rate.(22-24)

Concerns have been raised with coding accuracy 
of HES database. Various studies have confirmed 
the coding accuracy in the United Kingdom 
to be on average 92%, especially for procedure 
coding. (25) Furthermore, the major outcome 
variables (in-hospital mortality and length of 
hospital stay) can be extracted accurately through 
HES database. The audit verifying the excess 
deaths in Bristol pediatric cardiac surgery unit 
attests the accuracy of HES coding.(26)

One of the major strengths of this study lies in its 
population-based nature, which makes the results 
more easily generalizable and applicable to the 
majority of patients treated in various clinical 
settings. New British Association of Urological 
Surgeons database of complex operations might 
resolve the few obstacles of Hospital Episodes 
Statistics and aid in future studies.

CONCLUSION
In conclusion, there is an exponential increase 
in the number of RPs with an increasing trend 
towards laparoscopic RP in England. This 
study showed a significant inverse correlation 
between provider volume (hospital and 
surgeon) and outcome (mortality and length 
of hospital stay) for radical prostatectomy in 
England; thus, supporting the recommendations 
for centralization of major complex radical 

procedures, including radical prostatectomy.

ACKNOWLEDGEMENTS
The authors are thankful to the Department of 
Health in England for providing the Hospital 
Episode Statistics data.

CONFLICT OF INTEREST
None declared.

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