Deoxyribonucleic Acid Ploidy Enhances the Cytological Prediction of Recurrent Transitional Cell Carcinoma of the Bladder

Markers of bladder cancer State of the art

Biomarkers are increasingly being applied to the clinical management of patients with bladder cancer. The biomarkers in current clinical use focus on bladder cancer detection. Biomarkers for prognosis and as intermediate endpoints for chemoprevention are being evaluated in clinical trials. This review provides an overview of the performance characteristics of current clinical markers and other markers that are currently under evaluation.

Analysis of fluorescence in situ hybridization, mtDNA quantification, and mtDNA sequence for the detection of early bladder cancer

We designed this study to test the sensitivities of cytology, the nuclear matrix protein 22 (NMP22) assay, and fluorescence in situ hybridization (FISH) in the early detection of urothelial carcinoma, and to identify mtDNA alterations in urinary epithelial cells. We collected 41 urine samples and 26 corresponding peripheral blood samples from patients with clinically suspected urothelial carcinoma. The FISH and NMP22 assays detected 92.1% of the cancers, and cytology detected 60.5%. In the low-grade group, NMP22 and FISH analyses were more sensitive than cytology, but in the high-grade group, all three methods showed approximately 90% sensitivity. Overall, the FISH and NMP22, or FISH and cytology assays combined detected 97.4% of cancers, while cytology with NMP22 detected 92.1%. In the low-grade group, the sensitivity of the three methods combined was above 80%, but in high-grade group, the combined sensitivity was approximately 100%. In the mtDNA control region, we detected characteristic heteroplasmic mtDNA substitution mutations in 1 patient and a mtDNA length heteroplasmic mutation in 303 polyC or 16184 poly C in 20 patients. Overall, urothelial carcinoma-specific mtDNA mutations were observed in 20 of the 26 patients (76.9%). The average mtDNA copy numbers in urine samples and corresponding peripheral blood samples (83.45 +/- 60.36 and 39.0 +/- 24.38, respectively) (mean +/- standard deviation [SD]) differed significantly (P < 0.001). The mtDNA copy numbers in the urine samples from patients with high-grade and low-grade tumors (81.83 +/- 67.78 and 86.49 +/- 46.69, respectively) did not differ significantly (P = 0.589). In conclusion, the FISH assay showed the highest sensitivity for detecting low-grade urothelial carcinoma, and mtDNA copy numbers in urine samples were higher than those in the corresponding peripheral blood samples. The frequency of mtDNA mutations in the D-loop region in patients with cancer was approximately 80% in our study. This report further supports the significance of genetic alteration in urothelial carcinoma and the clinical utility of the FISH, mtDNA quantitation polymerase chain reaction, mtDNA sequencing, and capillary electrophoresis for this purpose.

Detection of bladder cancer from the urine using fluorescence in situ hybridization technique

The authors report on their first experiences with the UroVysion fluorescence in situ hybridization (FISH) kit developed for the detection of bladder cancer. This new non-invasive diagnostic application of the FISH technique in the field of urology was elaborated to replace cystoscopy. The special urine examination method detects genetic alterations of the urothelial cells found in the urine, using fluorescent directlabeled DNA probes binding to the peri-centromeric regions of chromosomes 3, 7 and 17 as well as on the 9p21 locus. We aimed to evaluate the utility of UroVysion test in the light of the histological diagnosis. Urine samples from 43 bladder cancer patients and 12 patients with no or benign alterations were studied using a new application of FISH technique: the UroVysion reagent kit. The obtained FISH results were compared with the histological findings of the transurethral surgical resection specimens. The study rated the specificity and sensitivity of the technique 100% and 87%, respectively. Therefore, the technique could well fit into the diagnostic process of bladder carcinomas. Statistical analyses showed significant correlation between tumor progression and the severity of the genetic alterations detected by this FISH technique. Furthermore, positive correlation was found between tumor grade and the proportion of tumor cells showing genetic abnormality. The noninvasiveness, the robustness of evaluation and the high specificity/sensitivity are all in favor of this technique. The disadvantages are the higher costs of the technical background and the required future clinical studies to determine whether this technique can replace cystoscopy.

Fascin-1 expression in papillary and invasive urothelial carcinomas of the urinary bladder

Fascin-1 is an actin-bundling protein that plays an important role in cell motility and adhesion. The level of fascin-1 is low or undetectable in normal epithelial cells. However, overexpression is reported in transformed epithelial cells and in several common types of carcinomas [Bioessays. 2002;24:359-361]. Up-regulation of fascin-1 is associated with higher grades and with aggressive tumors with poorer prognoses. We found no report on the role or the protein expression of fascin-1 in urothelial carcinomas (UCs) of the urinary bladder. In this study, we examined by immunohistochemistry the expression of fascin-1 in the normal human transitional epithelium, benign vesical lesions, and different types of UCs. We found no detectable fascin-1 in the normal transitional epithelium. There was no increase of fascin-1 expression in cystitis cystica, cystitis glandularis, nephrogenic adenoma (n = 10), inverted papilloma (n = 5), and classic exophytic papilloma (n = 4) or in adjacent transitional epithelia associated with these conditions. Patchy or diffusely weak fascin-1 expression was observed in 42% (5/12) of superficial papillary UCs (Ta), and 95% (19/20) of invasive UCs (T2 or higher) demonstrated diffuse strong staining for fascin-1. The microinvasive foci in the lamina propria of UC (T1, n = 8) were also positive for fascin-1, although they were not as strongly stained as in the deeply invasive tumors. Interestingly, the neoplastic cells in the tips of microinvasive carcinomas were distinctly positive for fascin-1. There were significant numbers of fascin-1-positive cells (>50% of the neoplastic cells) in UCs in situ (n = 10). These findings suggest an association between increased fascin-1 expression and increased invasiveness of carcinomas in the urinary bladder.

Laser scanning cytometry for the detection of neoplasia in urologic cytology specimens

BACKGROUND

The objective of the current pilot project was to assess the efficacy of laser scanning cytometry (LSC) for DNA ploidy analysis of atypical urologic cytology specimens to enhance the distinction between benign and malignant changes.

METHODS

Forty selected urologic cytology specimens that previously had been categorized as normal, atypical, or malignant were studied. Nuclear propidium iodide and fluorescence intensity measurements were converted to pixel values, which were used to create scattergrams that excluded debris and cell clusters from ploidy analysis, creating a gated (isolated) region of predominantly single cells for LSC ploidy analysis. Integral histograms then were created to show the number of cells present in diploid, tetraploid, and aneuploid peaks; these histograms also were used to assess DNA ploidy.

RESULTS

Ten normal specimens, 10 malignant specimens, and 20 atypical specimens were examined to assess the efficacy of LSC ploidy analysis. Normal and malignant specimens generated reference histograms for comparison with the atypical specimens and exhibited 90% specificity and 100% sensitivity. Ten atypical aneuploid specimens had histogram and scattergram patterns similar to those produced by malignant specimens and, using the cytometer's relocation feature, the presence of atypical cells was confirmed in the aneuploid regions.

CONCLUSIONS

The authors determined that DNA ploidy analysis of atypical urologic cytology specimens using LSC is a useful adjunct tool for identifying malignant specimens that lack sufficient cytologic criteria for diagnosis by light microscopy alone. However, LSC is time consuming and requires expensive equipment.

DNA cytometric features in biopsies of TaT1 urothelial cell cancer predict recurrence and stage progression more accurately than stage, grade, or treatment modality

OBJECTIVES

To compare retrospectively the predictive value for recurrence and stage progression of DNA ploidy and S-phase fraction by flow cytometry and highly automated ultrafast image cytometry (ICM) in biopsies of TaT1 urothelial cell carcinomas (UCCs) of the urinary bladder with stage, grade, other pathologic features, and treatment.

METHODS

Three experienced pathologists reviewed the stage and grade of 228 UCCs; 193 (85%) consensus cases were analyzed further. We had enough material for single-cell suspensions for both flow cytometry and ICM in 183 cases (94.8%). The 2001 European Society for Analytical Cellular Pathology standards for DNA ICM were followed. The predictive value of DNA features, classic prognosticators (stage, grade, carcinoma in situ, multicentricity), and treatment modality for recurrence and stage progression were analyzed with univariate (Kaplan-Meier) survival and multivariate (Cox model) regression analysis. Ta and T1 cases were analyzed separately.

RESULTS

Of the 228 cases, 88 (51.5%) recurred and 13 (7.6%) progressed. On univariate analysis, most of the DNA features studied were statistically significant. Treatment modality and grade were only prognostic for progression (not for recurrence) and only in Ta cases. On multivariate analysis, DNA ICM features performed best; the strongest recurrence predictor for Ta UCC was a DNA index (DI) of 1.0 versus all others, and for T1 UCC, a DI of less than 1.3 versus 1.3 or greater. The best stage progression predictor for Ta UCCs was a DI of 1.0 plus an S-phase fraction of less than 10%, and for T1 UCCs, a DI of less than 1.3 versus 1.3 or greater. With multivariate analysis, sex, age, grade, carcinoma in situ, multicentricity, and treatment modality were excluded once the DNA ICM features were selected.

CONCLUSIONS

DNA image cytometric features predict recurrence and stage progression in TaT1 UCC biopsies more accurately than classic prognostic factors, independent of treatment modality.

Prognostic value of proliferative activity and nuclear morphometry for progression in TaT1 urothelial cell carcinomas of the urinary bladder

OBJECTIVES

To analyze the predictive power of Ki67 area% (Ki67), mitotic activity index (MAI), p53 area% (p53), and the mean area of the 10 largest nuclei (MNA10) for progression of stage in 195 primary consecutive TaT1 urothelial cell carcinomas of the urinary bladder.

METHODS

Ki67- and p53-positive versus negative nuclei, MAI, and MNA10 using motorized systematic random sampling morphometry were determined. Kaplan-Meier curves and multivariate survival analysis (Cox model) were used to assess the prognostic value of the quantitative and classic clinicopathologic risk factors (age, sex, stage, grade, carcinoma in situ, multicentricity).

RESULTS

Thirteen (6.7%) of the 195 patients had progression (0 [0%] of 36 low-risk, 1 [1.1%] of 85 intermediate-risk, and 12 [16.2%] of 74 high-risk patients). In univariate analysis (all variables), the strongest predictors with the highest hazard ratios were Ki67 (threshold 25.0%), MAI (threshold 30), and MNA10 (threshold 170 microm2). In multivariate analysis, the strongest independent combinations for progression--MNA10 (170 microm2) plus MAI (threshold 30) and MNA10 (threshold 170 microm2) plus Ki67 (threshold 25.0%)--overshadowed all other features. p53 was weaker but, combined with Ki67, still predicted progression fairly well. In the total group, the sensitivity, specificity, and positive and negative predictive values of MNA10-MAI and MNA10-Ki67 at the thresholds mentioned were 100%, 89%, 38%, and 100%, respectively. These feature combinations were also strongest prognostically in the high-risk treatment group.

CONCLUSIONS

The combined biomarkers MNA10-MAI or MNA10-Ki67 are accurate, well reproducible, and easy to assess progression predictors in all patients with TaT1 urothelial cell carcinomas, as well as in high-risk (bacille Calmette-Guérin-treated) patients.

DD23 Biomarker: a prospective clinical assessment in routine urinary cytology specimens from patients being monitored for TCC

BACKGROUND

A prospective clinical study was conducted to assess the ability of the DD23 murine monoclonal antibody to enhance detection of bladder cancer in routine alcohol fixed urine cytology samples.

METHODS

Prospectively, 308 bladder cytology specimens were obtained from patients with a history of bladder cancer with a mean age of 71.4+/-11.9 (27% female, 73% male). Data included 121 biopsy-confirmed results and 187 cystoscopy results to assess presence or absence of cancer. Thirty-five normal cytology specimens were obtained from asymptomatic men and women between 55-85 years of age. Separate slides from the alcohol fixed cytology specimens were stained using the Papanicolaou (Pap) and Feulgen staining procedures. The DD23 assay was performed using an avidin-biotin alkaline phosphatase immunocytochemical procedure, with a single urothelial cell exhibiting intense immunostaining sufficient to make a positive call.

RESULTS

Pap-Feulgen cytopathology for the 308 cases yielded an overall sensitivity of 65.5% and a specificity of 85.1%, and the DD23 biomarker alone yielded a sensitivity of 80.5% and a specificity of 59.7%. Analysis of the voided urines only (n=164) yielded sensitivities of 61.0% and 73.2% and specificities of 86.2% and 67.5% for cytopathology and DD23 alone, respectively. Results in 49 bladder wash urine cytology cases produced a sensitivity of 70.2% and 100% and specificities of 92.3% and 61.5% for cytopathology and DD23 alone, respectively. In 133 patients that underwent biopsy or had positive cystoscopy results, cytopathology yielded a sensitivity of 65.5% and a specificity of 69.6% while DD23 yielded a sensitivity of 80.5% and a specificity of 58.7%. In 25 biopsy-confirmed low-grade cancers, DD23 improved cancer detection from 32% to 72% when compared to cytopathology. The DD23 biomarker had a specificity of 85.7% in 35 age-matched normal asymptomatic control specimens.

CONCLUSIONS

The DD23 biomarker is an adjuvant test that provides improved detection of bladder cancer in cytology specimens and enhances the sensitivity of the cytopathology diagnosis, especially in low-grade cancers.

Diagnostic performance of the urinary bladder carcinoma antigen ELISA test and multiparametric DNA/cytokeratin flow cytometry in urine voided samples from patients with bladder carcinoma

BACKGROUND

The objective of the current study was to comparatively analyze the sensitivity and specificity of flow cytometric DNA/cytokeratin 8/18 measurements and the urinary bladder carcinoma antigen (UBC) enzyme linked immunoabsorbent assay (ELISA) test for the detection of bladder carcinoma in voided urine samples.

METHODS

Eighty-one fresh urine voided samples, preserved frozen for a maximum period of 3 months, belonging to patients with an active bladder carcinoma (n = 37), patients who were free of disease as confirmed by cystoscopy (n = 19), patients receiving intravesical therapy (n = 17), and individuals with other benign and malignant conditions (n = 8), were collected. Flow cytometry measurements of thawed samples were based on the detection of cytokeratin (CK) 8+ and CK18+ cells using the 3F3 and 6D7 monoclonal antibodies alone or in combination with the measurement of cell DNA contents, after propidium iodide staining. Urinary bladder carcinoma antigen test was measured by ELISA.

RESULTS

Patients were grouped according to the presence (n = 44) or absence (n = 29) of bladder carcinoma as confirmed by cystoscopy, and taking cutoffs of 9.7 microg/L for UBC-ELISA, 75% for the percentage of 3F3 (+) and 6D7 (+) cells, and 10.6% for the proportion of hyperdiplod cells that suggested a specificity of 83%, the individual sensitivity obtained for each parameter was 77%, 5%, 9%, and 77%, respectively. The presence of DNA aneuploid populations showed a relatively low sensitivity (36%) although it was the most specific parameter (93%). Combining UBC antigen test with the proportion of cells showing DNA content higher than 2n increased to 89% the sensitivity of the UBC antigen alone. However, false-positive results for both techniques were found in individuals with urologic diseases other than bladder carcinoma and in patients receiving intravesical therapy.

CONCLUSIONS

The authors' results suggest that the combined use of the UBC antigen test and DNA/cytokeratin flow cytometry double stainings for the analysis of freshly obtained urine voided samples, cryopreserved to assure cellular integrity, is of great clinical utility for the detection of tumor recurrence in patients with bladder carcinoma.

Quantitative nuclear grade (QNG): a new image analysis-based biomarker of clinically relevant nuclear structure alterations

This review addresses the potential clinical value of using quantitative nuclear morphometry information derived from computer-assisted image analysis for cancer detection and predicting outcomes such as tumor stage, recurrence, and progression. Today's imaging technology uses sophisticated hardware platforms coupled with powerful and user-friendly software packages that are commercially available as complete image analysis systems. There are many different mathematically derived nuclear morphometric descriptors (NMD's) (i.e. texture features) that can be calculated by these image analysis systems, but for the most part, these NMD's quantify nuclear size, shape, DNA content (ploidy), and chromatin organization (i.e. texture, both Markovian and non-Markovian) parameters. We have utilized commercially available image analysis systems and the NMD's calculated by these systems to create a mathematical solution, termed quantitative nuclear grade (QNG), for making clinical, diagnostic, and prognostic outcome predictions in both prostate and bladder cancer. A separate computational model is calculated for each outcome of interest using well-characterized and robust training, testing, and validation patient sample sets that adequately represent the selected population and clinical dilemma. A specific QNG solution may be calculated either by non-parametric statistical methods or non-linear mathematics employed by artificial neural networks (ANNs). The QNG solution, a measure of genomic instability, provides a unique independent variable to be used alone or to be included in an algorithm to assess a specific clinical outcome. This approach of customization of the nuclear morphometric descriptor (NMD) information through the calculation of a QNG solution mathematically adjusts for redundancy of features and reduces the complexity of the inputs used to create decision support tools for patient disease management. J. Cell. Biochem. Suppl. 35:151-157, 2000.

Diagnostic accuracy of DNA image cytometry and urinary cytology with cells from voided urine in the detection of bladder cancer

OBJECTIVES

To assess the potential of DNA image cytometry in screening for bladder cancer, compare it with conventional urinary cytology, and evaluate its possible use in routine urinary evaluation. Urinary cytology is still the most common method for detection of bladder cancer in routine clinical use. The considerable shortcomings of urinary cytology include its low sensitivity in low-grade carcinomas and its poor reproducibility.

METHODS

Spontaneously voided urine specimens from 40 patients with grade 1 (n = 27), grade 2 (n = 10), and grade 3 (n = 3) histologically proven transitional cell carcinoma and 40 patients with symptomatic urologic disease of the bladder were analyzed by cytology and DNA image cytometry. The DNA content was determined by use of the CM-1 Cytometer according to the guidelines in the ESACP Consensus Report on Standardization of DNA Image Cytometry.

RESULTS

Urinary cytology yielded an overall sensitivity of 47.5%. Conventional analysis of DNA histograms measuring the presence of DNA stemline aneuploidy (1.8c > stemline ploidy [STP] > 2.2c) revealed a sensitivity of 62.5%; applying the stemline interpretation according to Böcking et al. increased the overall sensitivity to 75%. The specificity of both methods was 100%. DNA image cytometry demonstrated a high sensitivity in grade 1 tumors (70.4%) compared with cytology (26%).

CONCLUSIONS

In light of its highly improved sensitivity compared with urinary cytology, DNA image cytometry should be used to evaluate suspect urothelial cells in urinary cytology specimens. Since the method provides more objective and reproducible results with a specificity comparable to that of cytology, we encourage its primary application in the screening for bladder cancer, provided these results can be confirmed in a multicenter evaluation study.

Influence of season on the incidence of DNA hypodiploidy in urinary cytology

OBJECTIVE

This study was conducted to determine if an incidence of hypodiploidy in urinary specimens is related to seasonal temperature changes.

MATERIALS AND METHODS

DNA ploidy was evaluated on 10,846 urinary specimens fixed in buffered alcohol (MOPSO/NaCl + ETOH) and received over a one year period from numerous sites throughout the United States. The percentage of hypodiploid (DNA index < 0.8) cases was evaluated in each month. As a control, DNA ploidy results from 3, 755 prostate biopsies, fixed in 10% neutral buffered formalin, received during the winter and summer months of the same year, were evaluated.

RESULTS

The average percentage of hypodiploidy in cytologic specimens during the summer months was 19.6% compared to 5. 4% in the winter and early spring months (range: 20.6-4.8%). The average percentage of hypodiploid cells in histologic specimens was 0.8% for both the summer and winter months (range: 1.73-0.36%).

CONCLUSIONS

The rate of hypodiploidy in urinary cytology seems to be temperature related. The hypodiploidy rate of histologic specimens fixed in formalin shows no fluctuation with the seasons.

Diagnosis and prediction of recurrence and progression in superficial bladder cancers with DNA image cytometry and urinary cytology

OBJECTIVE

To investigate the roles of urinary cytology and image cytometric analysis of nuclear DNA ploidy pattern in the diagnosis and prediction of recurrence and/or progression of superficial bladder cancers.

PATIENTS AND METHODS

Aliquots of catheterized urine from 92 patients with primary (23) or previous (69) superficial bladder cancers were assessed using urine cytology and image-analysis cytometry independently.

RESULTS

Of the 23 primary superficial transitional cell carcinomas (TCCs), 11 (48%) were detected by urinary cytology while 12 (52%) were detected by image-analysis cytometry (P>0.05) and 13 (57%) were revealed by combined cytology and cytometry. Of 42 recurrent superficial TCCs, 29 (69%) were detected by urinary cytology, whilst 19 (45%) were diagnosed by cytometry (P<0.05) and 29 (69%) by combined cytology and cytometry. The degree of ploidy in relation to pathological stage and/or grade showed an increasing frequency of aneuploid pattern in more invasive and undifferentiated tumours, but with no statistical significance (P>0.05). The positivity of DNA image cytometry had no significant association (P>0.05) with tumour recurrence and/or progression.

CONCLUSIONS

DNA image cytometry can provide a limited but not significant advantage over urinary cytology in the detection of primary superficial TCCs, but it does not seem to be indicated for the prediction of tumour recurrence and/or progression.

Chromosome 9 monosomy by fluorescence in situ hybridization of bladder irrigation specimens is predictive of tumor recurrence

PURPOSE

Bladder irrigation specimens are effective for sampling the urothelium for detection of recurrent bladder cancer. These specimens can be evaluated by cytology or quantitative techniques. Proliferation and ploidy changes are readily detected using deoxyribonucleic acid (DNA) cytometry. Tumor associated chromosomal aberrations can be assayed using fluorescence in situ hybridization (FISH). The prognostic values of DNA cytometry, and chromosome 9 and 9p21 FISH on exfoliated cells from bladder irrigation specimens from 61 bladder cancer patients were evaluated.

MATERIALS AND METHODS

A total of 61 consecutive bladder irrigation specimens were obtained during cystoscopy. DNA cytometry was performed by image analysis. FISH was performed using a centromeric chromosome 9 probe and a cosmid contig (COSp16) probe to the CDKN2A/p16 tumor suppressor region of 9p21. Proportional hazards regression analysis was performed with statistical software to test the predictor variables of initial patient status (presence of tumor), COSp16 fraction (the proportion of COSp16 signals relative to centromeric probe signals), monosomic and hyperdisomic fractions of the chromosome 9 probe, and hyperdiploid fraction from DNA cytometry. Median time to recurrence was calculated using statistical software survival analysis.

RESULTS

Initial patient status and monosomy of chromosome 9 were predictive of bladder cancer recurrence (p <0.0001 and p = 0.0073, respectively). The 11 patients with chromosome 9 monosomy fractions greater than 15% and a visible tumor had a median time to recurrence of 105 days. In contrast, only 8 of the 25 patients with chromosome 9 monosomy fractions less than 15% and no visible tumor had recurrence within 560 days. Median time to recurrence was 185 days for 6 patients with chromosome 9 monosomy fractions greater than 15% and no visible tumor, and 225 for 19 with chromosome 9 monosomy fractions less than 15% and a visible tumor. Hyperdiploid fraction was suggestive but not predictive of bladder cancer recurrence (p = 0.078). COSp16 and hyperdisomic fractions were not predictive of bladder tumor recurrence (p = 0.11 and p = 0.30, respectively).

CONCLUSIONS

Chromosome 9 monosomy by FISH was predictive of bladder tumor recurrence. Furthermore, our findings support the hypothesis that losses of tumor suppressor genes on chromosome 9 are critical, perhaps initiating genetic events in bladder cancer.

Bladder tumor markers: need, nature and application. 1. Nucleus-based markers

Urothelial tumors are common: their diagnosis and long-term management represent a large part of most urologists' workload. The majority of such tumors are 'superficial' and are mostly managed by repeated cystoscopic surveillance and treatment. A smaller but significant group of patients either start with, or subsequently progress to, more invasive disease, thus requiring an alternative and more invasive treatment. Maximizing the benefit/risk ratio of the diagnosis and the various treatment options of bladder tumors requires the availability of a reliable tumor marker. The concept of tumor markers encompasses the utilization of any detectable deviation from normality that is indicative of neoplasia. For bladder cancer, most of these markers are present in urine. In this part of the review we examine, from the clinician's point of view, the literature verdict on older techniques such as cytology and cytometry, as well as the current status of new nucleus-based tests such as P53, telomerase, NMP22 and Ki67.