Using two nomogram percentiles and post void residual in the analysis of a large male uroflowmetry database

Sutton A1, Hashim H2, Gammie A3

Research Type

Clinical

Abstract Category

Urodynamics

Abstract 202
Voiding Dysfunction
Scientific Podium Short Oral Session 25
Thursday 28th September 2023
17:42 - 17:50
Theatre 102
Male Bladder Outlet Obstruction Urodynamics Techniques Retrospective Study
1. North Bristol NHS Trust, 2. North Bristol NHS Trust, Bristol Urological Institute, 3. Bristol Urological Institute
Presenter
Links

Abstract

Hypothesis / aims of study
Aim 1: Investigate the distribution of patients on the Liverpool nomogram when considering their post void residual in uroflowmetry studies.

Aim 2: Investigate the classification, correlation and agreement for patient percentiles between the Liverpool and Siroky nomograms.
Study design, materials and methods
This study uses a large department database of male uroflowmetry patients who had their investigations between 1988 and 2021. The unfiltered data comprises 29,076 patient data entries, with up to three uroflowmetry tests per patient. These tests were conducted in a urology outpatient setting, on men who were referred for lower urinary tract symptoms, including both storage and voiding complaints. Patients who opted out of their data being used for research were excluded from the database. 

In the uroflowmetry clinic it is routine to perform between one and three flow tests per patient, and a post void residual scan after each void. Uroflowmetry uses a natural method of filling- men are advised to arrive with a comfortably full bladder to perform the first flow, and asked to continue drinking water for a second or third flow. If their first or second void felt representative of their usual void, the test can conclude without a third flow. The data points of interest (Qmax, voided volume and post void residual- PVR) were entered manually by staff at the time of the clinic. 

As this data was collected over a 33-year period, equipment was changed. The flowmeters used during this data collection were Dantec, Mediwatch and MMS. 

Data screening was conducted to remove any typographical errors. Patients with duplicate data entries were deleted. Patients with more than one appointment remain in the database. Each patient data point has up to 3 sets of uroflowmetry data. 
Only one set of uroflowmetry data was used per patient. This was decided based on the largest voided volume <601ml out of the maximum 3 flows. The corresponding Qmax and PVR are also selected. 

At this point, we removed any patient who fell outside the ranges: Qmax <71ml/s, voided volume <601ml, as these are the largest criteria which can be plotted on the Liverpool nomogram. 

In calculating the relevant parameters, we noted that Siroky uses total volume (voided volume and PVR volume) but Liverpool uses voided volume only.

For each patient the Liverpool percentile, and the Siroky percentile were calculated using the Excel formulae below, which are derived from references (1) and (3).

Liverpool patient percentile= NORM.DIST(SQRT(Qmax), (2.37+0.18*SQRT(Voided volume)-0.014*Age), 0.727, 1)

The Siroky percentile is calculated using: 
Siroky mean= 7.327+0.113*vol-0.000224*vol2+2.6*POWER(10,-7)*vol3-1.62*POWER(10,-10)*vol4

Siroky mean-1SD= 6.071+0.0863*vol-0.000192*vol2+2.58*POWER(10,-7)*vol3-1.699*POWER(10,-10)*vol4

The standard deviation for Siroky is the difference in the two above equations. The percentiles were then calculated using the Excel NORM.DIST function. 

For aim 1, patients were grouped into increments of 100ml post void residual (PVR) and plotted on the Liverpool nomogram for visual representation. This allowed visual comparison of post void residual groups, and preliminary observations as to whether the spread of percentiles on the nomogram was changed for each group.

For aim 2 first a binary agreement was investigated. If a patient had a percentile <25% on the Liverpool or <-2SD on the Siroky nomograms, they would receive a “1” in the corresponding nomogram column. If a patient had a percentile >25% on the Liverpool or >-2SD on the Siroky nomograms, they would receive a “0” in the corresponding nomogram column. 

This was followed by a Cohen’s Kappa agreement statistical test. This investigates the agreement of criteria (Liverpool <25%, Siroky <-2SD) for each patient, as to whether both agree, both disagree, or they disagree. 

These two calculations allowed simple investigation in the agreement of patients being classified as Liverpool <25% and Siroky <-2SD. This was conducted on patients within the parameters of both nomograms. 

A correlation study was then performed between the Liverpool percentiles and the Siroky percentiles. 

Finally, level of agreement was investigated between Liverpool percentiles and the Siroky percentiles using a paired sample t-test.
Results
Table 1 is the final data set summary of 26,536 patients, grouped by age rounded to the nearest decade when considering the above specified criteria. 

Table 2 is the final data set grouped into PVR brackets.

The patients who fit the Siroky criteria comprise of less patients, due to the smaller range of graph. The ranges of the Siroky graph are: Qmax <31ml/s and total volume <501ml. 
This gave us a total of 18,856 patients who have a percentile on both nomograms.

Aim 1: As PVR changes, so does the distribution of patients on the Liverpool nomogram. As PVR increases, there are less patients above the Liverpool nomogram 25th percentile.  

Aim 2: 
Binary agreement: Across patients who can be plotted on both nomograms, there is a 79% agreement for patients being classed as <25% on the Liverpool nomogram, and <-2SD on the Siroky nomogram. 

Cohen’s Kappa agreement: 0.57 (moderate agreement).

Linear correlation of patient percentile in each of the nomograms was 0.69 (moderately high correlation).

Paired samples t-test with the following values: 
	Sample mean of differences (X): 19(%)
	Sample standard deviation of the differences (S): 18(%)
	Sample size (N): 18856
This yielded a T-test value of 144.95 (P-value <0.00001).
Interpretation of results
The results from aim 1 suggests the change in the spread of data on the Liverpool nomogram between different groups of PVR shows that there is scope for considering nomogram percentile and PVR as separate variables in patient assessment. A graph of patient percentile versus PVR may be more predictive of particular clinical diagnoses than the current nomograms alone. 

The results from aim 2 show that when percentile increases in one nomogram, it will increase in the other, giving the nomograms a moderately high correlation.

However this holds little importance, because as the paired sample T-test value is statistically significant with a p value of <0.00001, we can reject the null hypothesis of ‘the mean of patient percentile on the Liverpool nomogram equals the mean of patient percentile on the Siroky nomogram’. 
We have sufficient evidence to say that the mean patient percentiles are statistically significantly different between the Liverpool and Siroky nomogram calculations.
Concluding message
The significant difference in the mean patient percentiles between the Liverpool and Siroky nomograms demonstrates that the nomograms cannot be used interchangeably. 

Following this study, we plan to continue investigating the power of percentiles and PVR in predicting urodynamic study outcome in the same patient cohort. By investigating this we hope this research can contribute to designing a nomogram with the added PVR dimension which is helpful for counselling patients suspected of male bladder outlet obstruction.
Figure 1 Table 1 and 2 summarizing the data sets
Figure 2 Patients with PVR plotted on the Liverpool nomogram
References
  1. Haylen, B.T., Ashby, D., Sutherst, J.R., Frazer, M.I. and West, C.R. (1989), Maximum and Average Urine Flow Rates in Normal Male and Female Populations—the Liverpool Nomograms. British Journal of Urology, 64: 30-38.
  2. Siroky, M.B., Olsson, C.A., Krane, R.J. The flow rate nomogram: I. Development. J Urol. 1979 Nov;122(5):665-8.
  3. Hosmane, B., Maurath, M., McConnell, M. (1993). Construction of the flow rate nomogram using polynomial regression. Computer Methods and Programs in Biomedicine, 39:258-288
Disclosures
Funding No disclosures Clinical Trial No Subjects Human Ethics Committee East of Scotland Research Ethics Service Helsinki Yes Informed Consent Yes
Citation

Continence 7S1 (2023) 100920
DOI: 10.1016/j.cont.2023.100920

22/11/2024 11:28:33