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Emerging Intravesical Therapies for Non Muscle Invasive Urothelial Carcinoma Marc C. Smaldone Fellow in Urologic Oncology, Fox Chase Cancer Center for Introduction Although BCG is the reference standard for high risk non-muscle invasive bladder cancer (NMIBC), up to one third of patients recur, and a substantial number of patients progress to muscle invasive disease1. In addition, use of BCG is limited due to local or systemic toxicity in approximately 20% of patients. As a result, use of alternative intravesical agents has sparked significant interest in patients that are intolerant to BCG or not candidates for cystectomy due to competing risks. Immunomodulatory Agents Interferon α2B (IFN), a host immune response modulator, has been utilized as both monotherapy and adjunct therapy in BCG refractory patients. The results of early investigations of IFN as monotherapy to prevent disease recurrence have been disappointing, demonstrating no benefit or inferior recurrence rates when compared to placebo controls2 or other intravesical agents (BCG, MMC, MMC/IFN)3. In contrast, results from initial trials investigating the combination of IFN and BCG have been more promising4. In a multicenter phase II trial, BCG plus IFN was administered in 536 BCG naïve patients and 467 BCG refractory patients with NMIBC. With a median follow up of 24 months, recurrence free rates were 59% and 45% in the BCG naïve and BCG refractory groups respectively; factors associated with tumor recurrence were tumor size >5cm, prior BCG failure, and tumor multifocality5. Based on contemporary data, BCG+IFN appears to be a well tolerated alternative for salvage therapy in select patients, but should not be considered equivalent to radical therapy in appropriate surgical candidates. Additional immunomodulatory agents that are currently in phase I and II trials include Bropirimine6, Keyhole-limpet Hemocyanin7, Mistletoe Lection8, and Mycobacterial Cell Wall Complexes9. Although the majority of these agents have exhibited encouraging response rates in small trials, further investigation is necessary before they can be recommended in BCG refractory or intolerant patients. Chemotherapeutic Agents In addition to Mitomycin C, which is described in a separate chapter, multiple chemotherapeutic agents are currently being investigated as primary and secondary therapy for non-muscle invasive bladder cancer. Early data suggested that the addition of intravesical chemotherapy to TUR yields a 14% reduction of tumor recurrence but has limited benefit with respect to disease progression10. However, two recent meta-analyses reported that recurrence rates following intravesical administration of chemotherapy may be reduced by as much as 70% when compared to TUR alone11, 12. Current efforts are focused on defining ideal treatment schedules, optimizing the efficacy of traditionally utilized therapies, and investigating novel chemotherapeutic agents. Thiotepa, an alkylating agent that inhibits nucleic acid synthesis by inducing DNA and RNA cross-linkage, is currently the only chemotherapeutic agent FDA approved for papillary TCC13. Although initial trials were encouraging, a meta-analysis of nine controlled trials reported only a modest 12% benefit with thiotepa therapy, and risk of systemic myelosuppression clinically limits its use10. Gemcitabine, a pyrimidine analog that inhibits cell growth and induces apoptosis, is currently utilized in systemic chemotherapeutic regimens for both localized and metastatic urothelial carcinoma14. Due to its high molecular weight (299.66 kDa) systemic toxicity is low, and a phase II trial reported recurrence rates for intermediate and high risk disease of 26% and 77% respectively following TUR15. A phase III trial randomizing gemcitabine or MMC for patients with recurrent disease reported 3 year disease free recurrence rates of 72% and 61% respectively16. While promising as both a primary and adjuvant therapy, further prospective comparison with contemporary agents are warranted, and clinical trials for BCG refractory disease are currently accruing. Doxorubicin, Epirubicin, and Valrubicin are anthracycline antibiotics that function as topoisomerase inhibitors and prevent protein synthesis. While high prevalence of local effects has hampered the use of doxorubicin, randomized trials have demonstrated that recurrence rates following treatment with epirubicin is inferior to BCG17, 18, which has limited its use to immediate post-operative instillation, BCG refractory disease, and carcinoma in situ. A recent multi-institutional study investigating the role of valrubicin in 90 patients with refractory carcinoma in-situ reported a 21% complete response rate and 10% remained disease free over a ten year follow up period19. Based on this data, valrubicin is currently the only intravesical agent FDA approved for the treatment of BCG refractory urothelial carcinoma. Apaziquone, an alkylating agent that results in cell death, is currently in the early phases of investigation with promising results. In the largest clinical experience to date, Van der Heigden et al. reported a complete histologic response rate in 67% of 46 patients with NMIBC at one month, and recurrence free rates at one and two years in complete responders was 57% and 50%20, 21. Docetaxel and Paclitaxel belong to a class of cytotoxic agents (taxoids) that induce cell death by inhibiting the polymerization of microtubules. Also used as second line systemic therapy in metastatic urothelial carcinoma, a recent phase I trial reported a 22% durable complete response rate in patients with recurrent refractory disease with 61% failed treatment at a median of 48 months22. A recent update of this series reported one and two year recurrence free survival rates of 45% and 32% respectively23. Suramin, a polysulphonated naphthylurea and a potent antagonist of vascular endothelial growth factor, has demonstrated potent anti-tumor activity in bench studies24 and phase I studies have demonstrated minimal local or systemic toxicity25. With acceptable side effect profiles and promising efficacy, each of the above mentioned agents is currently the focus of studies investigating their role as both a primary agent for non muscle invasive bladder cancer as well as BCG refractory disease. Increasing Bladder Wall Penetration, Prolonging Residence Time, and Site Directed Targeting A number of novel chemical and physical approaches have been utilized in an effort to increase bladder wall penetration and enhance chemotherapeutic efficacy. Chemical methods of increasing bladder wall permeability include use of dimethyl sulfoxide (DMSO), Chitosan, Polycarbophil, and Hyaluronidase26. Initially utilized in the treatment of patients with interstitial cystitis, DMSO has been shown to induce and alter inflammatory tissue responses and neurotransmission, but concerns still exist regarding systemic absorption when administered with chemotherapeutic agents27. Permeability enhancers that enhance drug transport by rearrangement of cellular tight junctions (Chitosan; Polycarbophil) or hydrolization of the bladder mucosal hyaluronan network (Hyaluronidase) have also been investigated28. Physical methods to enhance permeability by urothelial disruption include hyperthermia, electromotive drug administration (EMDA), and photodynamic therapy (PDT). Hyperthermia has been shown to enhance the efficacy of chemotherapeutic agents to inhibit DNA synthesis and repair, increase cell membrane permeability, and alter intracellular drug transport, and initial trials investigating hyperthermia + MMC versus MMC alone following TUR have reported reduced recurrence rates in the combination therapy group 29. EMDA, which utilizes iontophoresis to create a potential difference across the bladder wall, has been shown to increase drug transport through biologic membranes and to enhance the effectiveness of intravesical agents when compared to passive administration alone. Initial trials investigating EMDA in combination with MMC have reported encouraging recurrence free intervals when compared to MMC alone, BCG alone, and when used sequentially in combination with BCG 30. PDT, which utilizes the photosensitizing agent 5-aminolaevulinic acid (ALA) to selectively destroy malignant cells following exposure to light, is currently in the early phases of investigation in patients with NMIBC refractory to traditional intravesical agents31. Prolonging bladder mucosal exposure to intravesically administered chemotherapy is challenging due to agent insolubility in the aqueous form and immediate evacuation with voiding, which has led to interest in the development of sustained-retention delivery platforms26. Delivery platforms currently being investigated in experimental models that show exciting potential include bioadhesive microspheres32, hydrogel systems, and liposomes33. Magnetically targeted carrier (MTC) therapy is another intriguing experimental treatment modality that utilizes a magnet placed externally on the skin covering a predetermined bladder site to localize drug containing magnetic particles in tumors and provide prolonged exposure to higher drug concentrations34. While still in the initial investigatory period, these novel methods of enhancing the delivery and maximizing the efficacy of existing intravesical agents demonstrate significant promise and clinical trial results are eagerly anticipated. The management of patients with NMIBC refractory or intolerable to BCG with or without maintenance therapy due to local or systemic toxicity constitutes a growing management challenge, particularly in patients that are not suitable for or refuse cystectomy. In addition, conflicting definitions of BCG refractory disease and inclusion of Ta in addition to T1 tumors in contemporary trials has resulted in a growing body of data that is difficult to interpret and apply clinically26. In spite of these limitations, exciting progress is being made in the optimization, identification, and development of these promising new intravesical therapies. While promising, it will likely be several more years at minimum to determine if these emerging treatment strategies will supplant BCG or surgical resection in NMIBC that is refractory to intravesical therapy. References 1. Hall, M. C., Chang, S. S., Dalbagni, G. et al.: Guideline for the management of nonmuscle invasive bladder cancer (stages Ta, T1, and Tis): 2007 update. J Urol, 178: 2314, 2007 2. Portillo, J., Martin, B., Hernandez, R. et al.: Results at 43 months' follow-up of a doubleblind, randomized, prospective clinical trial using intravesical interferon alpha-2b in the prophylaxis of stage pT1 transitional cell carcinoma of the bladder. Urology, 49: 187, 1997 3. Braasch, M. R., Bohle, A., O'Donnell, M. A.: Risk-adapted use of intravesical immunotherapy. BJU Int, 102: 1254, 2008 4. O'Donnell, M. A., Krohn, J., DeWolf, W. C.: Salvage intravesical therapy with interferonalpha 2b plus low dose bacillus Calmette-Guerin is effective in patients with superficial bladder cancer in whom bacillus Calmette-Guerin alone previously failed. J Urol, 166: 1300, 2001 5. Joudi, F. N., Smith, B. J., O'Donnell, M. A.: Final results from a national multicenter phase II trial of combination bacillus Calmette-Guerin plus interferon alpha-2B for reducing recurrence of superficial bladder cancer. Urol Oncol, 24: 344, 2006 6. Sarosdy, M. F., Tangen, C. M., Weiss, G. R. et al.: A phase II clinical trial of oral bropirimine in combination with intravesical bacillus Calmette-Guerin for carcinoma in situ of the bladder: a Southwest Oncology Group Study. Urol Oncol, 23: 386, 2005 7. Lamm, D. L., Dehaven, J. I., Riggs, D. R.: Keyhole limpet hemocyanin immunotherapy of bladder cancer: laboratory and clinical studies. Eur Urol, 37 Suppl 3: 41, 2000 8. Elsasser-Beile, U., Leiber, C., Wolf, P. et al.: Adjuvant intravesical treatment of superficial bladder cancer with a standardized mistletoe extract. J Urol, 174: 76, 2005 9. Morales, A., Phadke, K., Steinhoff, G.: Intravesical mycobacterial cell wall-DNA complex in the treatment of carcinoma in situ of the bladder after standard intravesical therapy has failed. J Urol, 181: 1040, 2009 10. Lamm, D. L., Riggs, D. R., Traynelis, C. L. et al.: Apparent failure of current intravesical chemotherapy prophylaxis to influence the long-term course of superficial transitional cell carcinoma of the bladder. J Urol, 153: 1444, 1995 11. Huncharek, M., Geschwind, J. F., Witherspoon, B. et al.: Intravesical chemotherapy prophylaxis in primary superficial bladder cancer: a meta-analysis of 3703 patients from 11 randomized trials. J Clin Epidemiol, 53: 676, 2000 12. Huncharek, M., McGarry, R., Kupelnick, B.: Impact of intravesical chemotherapy on recurrence rate of recurrent superficial transitional cell carcinoma of the bladder: results of a meta-analysis. Anticancer Res, 21: 765, 2001 13. Heney, N. M., Koontz, W. W., Barton, B. et al.: Intravesical thiotepa versus mitomycin C in patients with Ta, T1 and TIS transitional cell carcinoma of the bladder: a phase III prospective randomized study. J Urol, 140: 1390, 1988 14. Stadler, W. M., Kuzel, T., Roth, B. et al.: Phase II study of single-agent gemcitabine in previously untreated patients with metastatic urothelial cancer. J Clin Oncol, 15: 3394, 1997 15. Bartoletti, R., Cai, T., Gacci, M. et al.: Intravesical gemcitabine therapy for superficial transitional cell carcinoma: results of a Phase II prospective multicenter study. Urology, 66: 726, 2005 16. Addeo, R., Caraglia, M., Bellini, S. et al.: Randomized phase III trial on gemcitabine versus mytomicin in recurrent superficial bladder cancer: evaluation of efficacy and tolerance. J Clin Oncol, 28: 543, 2009 17. Lamm, D. L., Blumenstein, B. A., Crawford, E. D. et al.: A randomized trial of intravesical doxorubicin and immunotherapy with bacille Calmette-Guerin for transitional-cell carcinoma of the bladder. N Engl J Med, 325: 1205, 1991 18. van der Meijden, A. P., Brausi, M., Zambon, V. et al.: Intravesical instillation of epirubicin, bacillus Calmette-Guerin and bacillus Calmette-Guerin plus isoniazid for intermediate and high risk Ta, T1 papillary carcinoma of the bladder: a European Organization for Research and Treatment of Cancer genito-urinary group randomized phase III trial. J Urol, 166: 476, 2001 19. Steinberg, G., Bahnson, R., Brosman, S. et al.: Efficacy and safety of valrubicin for the treatment of Bacillus Calmette-Guerin refractory carcinoma in situ of the bladder. The Valrubicin Study Group. J Urol, 163: 761, 2000 20. van der Heijden, A. G., Moonen, P. M., Cornel, E. B. et al.: Phase II marker lesion study with intravesical instillation of apaziquone for superficial bladder cancer: toxicity and marker response. J Urol, 176: 1349, 2006 21. Hendricksen, K., van der Heijden, A. G., Cornel, E. B. et al.: Two-year follow-up of the phase II marker lesion study of intravesical apaziquone for patients with non-muscle invasive bladder cancer. World J Urol, 27: 337, 2009 22. Laudano, M. A., Barlow, L. J., Murphy, A. M. et al.: Long-term clinical outcomes of a phase I trial of intravesical docetaxel in the management of non-muscle-invasive bladder cancer refractory to standard intravesical therapy. Urology, 75: 134, 2009 23. Barlow, L. J., McKiernan, J. M., Benson, M. C.: The novel use of intravesical docetaxel for the treatment of non-muscle invasive bladder cancer refractory to BCG therapy: a single institution experience. World J Urol, 27: 331, 2009 24. Gansler, T., Vaghmar, N., Olson, J. J. et al.: Suramin inhibits growth factor binding and proliferation by urothelial carcinoma cell cultures. J Urol, 148: 910, 1992 25. Ord, J. J., Streeter, E., Jones, A. et al.: Phase I trial of intravesical Suramin in recurrent superficial transitional cell bladder carcinoma. Br J Cancer, 92: 2140, 2005 26. Smaldone, M. C., Casella, D. P., Welchons, D. R. et al.: Investigational therapies for nonmuscle invasive bladder cancer. Expert Opin Investig Drugs, 19: 371, 2010 27. Chen, D., Song, D., Wientjes, M. G. et al.: Effect of dimethyl sulfoxide on bladder tissue penetration of intravesical paclitaxel. Clin Cancer Res, 9: 363, 2003 28. Hobarth, K., Maier, U., Marberger, M.: Topical chemoprophylaxis of superficial bladder cancer with mitomycin C and adjuvant hyaluronidase. Eur Urol, 21: 206, 1992 29. Colombo, R., Da Pozzo, L. F., Salonia, A. et al.: Multicentric study comparing intravesical chemotherapy alone and with local microwave hyperthermia for prophylaxis of recurrence of superficial transitional cell carcinoma. J Clin Oncol, 21: 4270, 2003 30. Di Stasi, S. M., Giannantoni, A., Stephen, R. L. et al.: Intravesical electromotive mitomycin C versus passive transport mitomycin C for high risk superficial bladder cancer: a prospective randomized study. J Urol, 170: 777, 2003 31. Berger, A. P., Steiner, H., Stenzl, A. et al.: Photodynamic therapy with intravesical instillation of 5-aminolevulinic acid for patients with recurrent superficial bladder cancer: a single-center study. Urology, 61: 338, 2003 32. Le Visage, C., Rioux-Leclercq, N., Haller, M. et al.: Efficacy of paclitaxel released from bioadhesive polymer microspheres on model superficial bladder cancer. J Urol, 171: 1324, 2004 33. Tyagi, P., Chancellor, M. B., Li, Z. et al.: Urodynamic and immunohistochemical evaluation of intravesical capsaicin delivery using thermosensitive hydrogel and liposomes. J Urol, 171: 483, 2004 34. Leakakos, T., Ji, C., Lawson, G. et al.: Intravesical administration of doxorubicin to swine bladder using magnetically targeted carriers. Cancer Chemother Pharmacol, 51: 445, 2003 Marc C. Smaldone, MD Fellow in Urologic Oncology, Fox Chase Cancer Center