Recent advances in proteomic profiling technologies, such as surface enhanced laser desorption ionization mass spectrometry, have allowed preliminary profiling and identification of tumor markers in biological fluids in several cancer types and establishment of clinically useful diagnostic computational models. There are currently no routinely used circulating tumor markers for renal cancer, which is often detected incidentally and is frequently advanced at the time of presentation with over half of patients having local or distant tumor spread. We have investigated the clinical utility of surface enhanced laser desorption ionization profiling of urine samples in conjunction with neural-network analysis to either detect renal cancer or to identify proteins of potential use as markers, using samples from a total of 218 individuals, and examined critical technical factors affecting the potential utility of this approach. Samples from patients before undergoing nephrectomy for clear cell renal cell carcinoma (RCC; n 48), normal volunteers (n 38), and outpatients attending with benign diseases of the urogenital tract (n 20) were used to successfully train neural-network models based on either presence/absence of peaks or peak intensity values, resulting in sensitivity and specificity values of 98.3–100%. Using an initial “blind” group of samples from 12 patients with RCC, 11 healthy controls, and 9 patients with benign diseases to test the models, sensitivities and specificities of 81.8–83.3% were achieved. The robustness of the approach was subsequently evaluated with a group of 80 samples analyzed “blind” 10 months later, (36 patients with RCC, 31 healthy volunteers, and 13 patients with benign urological conditions). However, sensitivities and specificities declined markedly, ranging from 41.0% to 76.6%. Possible contributing factors including sample stability, changing laser performance, and chip variability were examined, which may be important for the long-term robustness of such approaches, and this study highlights the need for rigorous evaluation of such factors in future studies

Banks, R. E.

Clarke, Paul

Munro, N. P.

Noble, Jason

Paul, A.

Rogers, M. A.

Selby, P. J.

English

Southampton (e-Prints Soton)

eosinophil-derived neurotoxin, antineoplastic urinary protein, an-giostatin, inhibin, and activin A. A tentative identification of thepresence of the peptide  defensin-1 in urine profiles in this study canbe made based on comparison with previous non-SELDI-based uri-nary studies. Produced by many epithelial cell types including partic-ularly the renal distal tubules and Loops of Henle in the kidney (40,41), the presence of  defensin-1 in urine has been described previ-ously (40, 42), with proforms and proteolytically processed formsincluding of 5068.1, 5068.7, 4749.2, and 4750.5 Da, very close to themasses of the peaks seen here at 5071.5 and 4753.3, and able to bindWCX2 chips (43). The reason for the decrease or relative absence inRCC urines may reflect increased proteolysis or alternatively de-creased production, because complete loss of defensin expression hasbeen shown in clear cell tumors (44).However, the most marked problem in the present study is the poorresults achieved with the subsequent larger blind set analyzed 10months later, particularly the marked decline in sensitivity. There areseveral possible explanations ranging from sample processing andstability through machine performance to problems with the neural-network model. The neural-network model was used in combinationwith an equally promising peak detection algorithm that enabled theexplicit identification of predictively relevant peaks, in contrast withthe “black box” approaches often used in machine learning. As istypical with neural-network analyses, various aspects of this designwere arrived at via a process of trial and error. Experimentation onfictional data sets was used to establish that the network couldsuccessfully classify cases given a few predictively relevant peaksagainst a background of noise, and experimentation within the trainingset determined the optimum number of inputs for each model typewith this number determining the sizes of models used to predict theblind test sets. Peaks were ranked by their associated 2 statisticswhen cross-tabulated with the incidence of cancer, and the number ofpeaks used as input ranged from the best 10 to the best 70. The exactnumber of inputs was chosen after testing to find the smallest subsetthat would result in the minimum classification error. The choice of 5hidden-layer neurons was somewhat arbitrary; the performance ofnetworks with 10 neurons in the hidden layer was also examined butproduced no improvement in predictive accuracy. More fundamen-tally, the use of a small hidden layer was intended as a defense againstthe dangers of over-fitting: with enough inputs and a large enoughhidden layer, a network could be trained to successfully classify anydata set. Given the modest sample size in comparison with the amountof data collected per subject, it seemed prudent to limit the space ofpossible models. Although a 5-hidden-neuron model will fail to cap-Fig. 4. Examples of spectra illustrating differences between different WCX2 chip batches for a single urine sample 3335. Spectrum A shows the initial result on the chip BB460run as part of the initial training set using the settings shown in the text. The remaining spectra on chips DU081, AB058, CN651, and DZ145 all from different batches were generated1 year later using settings that had been adjusted to account for the decay in intensity because of instrument performance with laser intensity of 215 and detector voltage of 2200 V.6979SELDI AND NEURAL-NETWORK ANALYSIS OF URINE PROTEINS IN RCCture highly complex interactions between input variables, it alsoprevents the detection of spurious interactions through over-fitting tothe training set. (By way of comparison with traditional statisticaltechniques, the use of 5 neurons in the hidden layer is roughlyequivalent to limiting a factor analysis or principal components anal-ysis to the top 5 factors). An element of over-fitting may haveoccurred with the artificial neural network, which would account forthe 15% drop in predictive accuracy with the initial blind test samples,but we feel that this is then unlikely to account for an additional drop10 months later, although there may be a minor contribution.Fig. 5. Representative examples of SELDIWCX2 spectra from urine samples used in theneural-network training set (laser intensity 210)and subsequently rerun 18 months later after laserreplacement (laser intensity 190).6980SELDI AND NEURAL-NETWORK ANALYSIS OF URINE PROTEINS IN RCC

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