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Electrochemotherapy with Cisplatin: Clinical Experience in Malignant Melanoma Patients¹

Gregor Sera², Borut tabuc, Maja emaar, Damijan Miklavi and Zvonimir Rudolf

Institute of Oncology [G. S., B. S., M. ., Z. R.], and Faculty of Electrical Engineering, University of Ljubljana [D. M.], SI-1000 Ljubljana, Slovenia

	ABSTRACT

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Electrochemotherapy consists of chemotherapy followed by local application of electric pulses to the tumor to increase drug delivery into the cells. The aim of this Phase II clinical study was to evaluate the antitumor effectiveness of electrochemotherapy using intratumoral cisplatin administration on cutaneous tumor nodules in malignant melanoma patients. In 10 patients, 133 tumor nodules of different sizes were treated: (a) 82 tumor nodules were treated with electrochemotherapy; (b) 27 tumor nodules were treated with cisplatin; (c) 2 tumor nodules were treated with electric pulses; and (d) 22 tumor nodules were untreated. Four weeks after therapy, 78% objective responses were obtained in the electrochemotherapy group, and 38% objective responses were obtained in the cisplatin group. Exposure of tumor nodules to electric pulses without cisplatin treatment had no effect on tumor growth. Electrochemotherapy was well tolerated by all patients, and a good cosmetic effect was obtained, with only minimal scarring and a slight depigmentation of the skin. At 124 weeks of follow-up, a 77% control rate of the tumor nodules treated by electrochemotherapy was observed, compared to 19% for those that were treated with cisplatin only (P < 0.0001). Our results clearly demonstrate that electrochemotherapy with cisplatin is a highly effective approach for treatment of cutaneous malignant melanoma nodules. The advantages of this therapy include its simplicity, the short duration of treatment sessions, low cisplatin doses, and insignificant side effects, as well as the fact that it can be done on an outpatient basis.

	INTRODUCTION

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High doses of drugs, which often cause systemic toxicity, are usually needed for effective chemotherapy. In addition, the lack of selectivity of chemotherapeutic agents for tumor cells has raised the call for the development of new drug delivery systems (1) . A local increase in plasma membrane permeability, i.e., exposure of the tumor nodule to electric pulses (electroporation), results in increased uptake of chemotherapeutics into the tumor cells. Therefore, lower doses of these drugs are needed to achieve a good antitumor effect, thus making this therapy less toxic (2 , 3) .

Enhanced delivery of chemotherapeutic drugs to tumor cells by electroporation is termed electrochemotherapy (2) . Electrochemotherapy has been shown to be successful for drugs such as bleomycin and cisplatin, which normally exhibit impeded transport through the plasma membrane. The increased antitumor effectiveness of bleomycin and cisplatin combined with electric pulses has already been demonstrated in experimental and clinical studies (4, 5, 6, 7, 8, 9, 10, 11) . In clinical studies, electrochemotherapy with bleomycin given i.v. or intratumorally was performed on cutaneous and s.c. tumor nodules of head and neck carcinomas, malignant melanomas, basal cell carcinomas, adenocarcinomas, and Kaposi’s sarcomas (10 , 12, 13, 14, 15, 16, 17, 18) . Objective responses were obtained for the majority of the electrochemotherapy-treated nodules, whereas nodules that were exposed only to electric pulses or treated only with bleomycin did not respond.

The first clinical study of electrochemotherapy with intratumoral application of cisplatin was performed on patients with malignant melanomas, squamous cell carcinomas, and basal cell carcinomas (11) . In that study, only two patients with malignant melanomas were included. Electrochemotherapy with cisplatin was effective in the treatment of cutaneous tumor nodules, and its antitumor effectiveness was comparable to that of electrochemotherapy with bleomycin.

Cutaneous metastases of malignant melanomas arising after chemoimmunotherapy in patients without concomitant dissemination to other organs raise the problem of optimal treatment approach, especially in patients who have already undergone extensive surgical treatment. In the present Phase II clinical study, the antitumor effectiveness of electrochemotherapy with cisplatin was compared to that of intratumoral injection of cisplatin alone. Ten malignant melanoma patients who had been treated previously with surgery or chemoimmunotherapy and had a total of 133 cutaneous tumor nodules were included in this study.

	PATIENTS AND METHODS

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Patient Eligibility.
From October 1995 to November 1997, 10 patients with histologically confirmed malignant melanomas were eligible to be included in this Phase II clinical trial (Table 1) . All of them had recurrent or PD³ with measurable cutaneous nodules and had received prior treatment or refused other standard treatment, i.e., radiotherapy, surgery, or chemoimmunotherapy. Other eligibility criteria were as follows: (a) Eastern Cooperative Oncology Group performance status of 0–1; (b) normal renal function; (c) normal blood tests and biochemistry; and (d) life expectancy of more than 3 months. A treatment-free interval of at least 3 weeks was required after previously applied therapy, except for surgery. During the trial, all patients were excluded from conventional chemotherapy protocols as well as from any other kind of treatment. National ethics committee approval and written informed consent from each patient were obtained before beginning the study.

Cisplatin (cis-diamminedichloroplatinum II; Platinol; Bristol-Myers Squibb, Vienna, Austria) was dissolved in 0.9% NaCl solution at a concentration of 2 mg/ml and administered intratumorally at doses ranging from 0.25–2 mg, depending on the size of the tumor nodule (approximately 1 mg/100 mm³). Tumor nodules larger than 200 mm³ were treated with 2 mg of cisplatin, regardless of the volume. The interval between cisplatin administration and the application of electric pulses was 1–2 min. Square wave electric pulses of 100 µs, 910 V amplitude (amplitude to electrode distance ratio, 1300 V/cm), and frequency of 1 Hz were delivered through two parallel stainless steel electrodes with rounded tips and inner distance between them 7 mm (thickness, 1 mm; width, 7 mm; length, 14 mm) with an electropulsator Jouan GHT 1287 (Jouan, Saint Herblaine, France). Electrical parameters were controlled using an HM 205–3 oscilloscope (Hameg Instruments, Frankfurt am Main Germany). Each run of electric pulses was delivered in two trains of four pulses, with a 1-s interval, in two perpendicular directions. Good contact between the electrodes and the skin was assured by means of a conductive gel. Nodules larger than 7 mm in diameter were treated with several runs of electric pulses administered in adjacent positions to assure adequate coverage of the whole tumor area (2–25 runs in 47 nodules). Electrochemotherapy was performed on an outpatient basis; when repeated treatment sessions were needed, there was a 4-week interval between them.

Treatment Evaluation.
After each treatment session, patients were kept in a recovery room for 2 h. Before they were released, hemodynamic and cardiological parameters were examined. At 4-week intervals, patients were examined on an outpatient basis by the team of the same experts that performed the therapy to evaluate treatment response and possible side effects. Tumor nodules were measured with a caliper and photographed. The volume of tumor nodules was calculated by the formula V = a x b x c x /6, where a, b, and c represent the diameters of the tumor nodule. Response to treatment was scored after 4 weeks, according to the WHO guidelines (19) , as follows: (a) CR, absence of any trace of the tumor; (b) PR, a more than 50% reduction in tumor volume; (c) NC, a less than 50% reduction of tumor volume and no tumor enlargement more than 25%; and (d) PD, tumor volume enlarged more than 25%. The duration of CR was calculated as the interval between the date when the CR was first recorded and the date of tumor progression (19) . Observation time was calculated as the interval between the date of the first treatment and the end of follow-up on August, 21 1998.

Statistical Analysis.
Statistical calculations were performed using a personal computer and a Biomedical statistical software package (BMDP). The differences in the distribution of patients according to the objective responses were tested using contingency table analysis and Fisher’s exact test. Local tumor control was estimated as a function of time by the Kaplan-Meier product limit method, and the difference between the curves was analyzed by means of the log-rank test. Data from patients who were alive or dead without recurrence were used as censored data. Statistical significance was tested at the 5% level.

	RESULTS

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Of the 10 patients included in this study, 6 patients had recurrent metastases in the skin that were refractory to chemoimmunotherapy, and 4 patients had visceral metastases. At the end of follow-up, six patients were without evidence of local recurrence of the disease, whereas the remaining four patients with visceral metastases had died due to cerebral metastases (one patient) and/or visceral spread (three patients).

Treatment Response.
In the electrochemotherapy-treated group, the median volume of the nodules was 61 mm³ (range, 2–39270 mm³). Four weeks after therapy, objective responses were observed in 64 of 82 (78%) nodules, CRs were observed in 56 of 82 (68%) nodules, and PRs were observed in 8 of 82 (10%) nodules. PD was observed in 6 of 82 (7%) nodules, and NC was observed in 12 of 82 (15%) nodules (Table 2) . In 10 of these nodules, a CR was obtained later on, at 8 weeks after beginning therapy. In the cisplatin-treated group, the median volume of tumor nodules was 67 mm³ (range, 6–2094 mm³) and did not differ significantly (P > 0.05) from those in the electrochemotherapy group. Objective responses were obtained in 10 of 27 (38%) nodules, CR was obtained in 5 of 27 (19%) nodules, and PR was obtained in 5 of 27 (19%) nodules. Most of the nodules were resistant to therapy: PD was observed in 9 of 27 (33%) nodules, and NC was observed in 8 of 27 (30%) nodules.

View larger version (20K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Local tumor control curves for the electrochemotherapy group (82 nodules) and the cisplatin group (27 nodules). Local tumor control was estimated using the Kaplan-Meier product limit method, and the difference between the curves was analyzed by means of a log-rank test.

Treatment Tolerance.
No significant deviations of hemodynamic or cardiological parameters from normal values were noticed after the treatment procedures. The intratumoral route of cisplatin injection was tolerable, although it was associated with some pain, which dissipated after several minutes. No local or systemic toxicity resulted after cisplatin administration. Application of electric pulses induced instantaneous contractions of the muscles located beneath the site of the treatment that disappeared immediately afterward. No exulceration was observed in nodules treated with cisplatin or electrochemotherapy. Erythema and a slight edema were observed in patients treated with electrochemotherapy at the site of the treated areas and remained for 2 weeks. Thereafter, a superficial scab was formed on these nodules, which fell off in approximately 4 weeks. A good cosmetic effect was obtained, with minimal scarring and a slight depigmentation of the skin.

	DISCUSSION

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Results of the present Phase II clinical study on cutaneous tumor nodules of malignant melanoma demonstrate that electrochemotherapy with cisplatin is an effective treatment with insignificant side effects. The objective response rate, its median duration, and local tumor control rate at the end of follow-up of electrochemotherapy-treated nodules were significantly higher compared to nodules treated with cisplatin alone.

Compared to electrochemotherapy with bleomycin, electrochemotherapy with cisplatin is equally effective. In a study on four different tumor types (i.e., basal cell carcinoma, malignant melanoma, Kaposi’s sarcoma, and squamous cell carcinoma), Heller et al. (18) demonstrated that electrochemotherapy with bleomycin results in 99.3% objective responses. When only malignant melanoma cases were considered, CRs were seen in 89.3% of treated nodules within 12 weeks (18) , which is comparable to the results of this study with a CR of 68% observed at 4 weeks and a 77% control rate at 124 weeks of follow-up. These results support our previous study on electrochemotherapy with cisplatin in which two of four patients had malignant melanoma (11) . In all 14 of the tumor nodules treated using electrochemotherapy with cisplatin, a CR was recorded, with a median duration of local tumor control of 28 weeks.

In patients without visceral, cerebral, and/or bone metastases, especially in heavily pretreated patients, the problem of cutaneous tumor nodules is quite specific. Standard treatments for such patients are comprised of surgery, immunotherapy, chemotherapy, and radiotherapy. Cisplatin, especially in combination with other chemotherapeutics, is one of the most effective treatments for malignant melanoma. Our first electrochemotherapy treatment was performed on cutaneous tumor nodules in patients who were on ongoing, systemic, cisplatin-containing chemotherapy. In tumor nodules that were additionally treated with electric pulses, a better response rate was obtained. Based on our experience gained in this clinical study as well as in some of our preclinical studies demonstrating that intratumoral cisplatin injection is more effective than i.v. injection, we decided to perform the present Phase II clinical study using intratumoral cisplatin administration (7 , 8 , 11) .

The data of the present study clearly show that percutaneous application of electric pulses to the tumor potentiates the effectiveness of cisplatin. Intratumoral cisplatin administration has the advantage over i.v. administration because it is an exclusively local treatment and has some antitumor effect on its own. Because only low cisplatin doses were needed to produce a pronounced antitumor effect, the treatment is safe, has insignificant side effects, and can be performed on an outpatient basis. Furthermore, after electrochemotherapy, tumor areas may exist that could not be adequately exposed to electric pulses; therefore, in those areas, reduction of tumor burden is expected to be due to cisplatin cytotoxicity. In addition, if, after the first electrochemotherapy session, the tumor nodule is not completely eradicated, the remaining tumor mass can be retreated in the following electrochemotherapy sessions.

In some tumors treated by electrochemotherapy, CR was not recorded after 4 weeks, but was recorded later on. This observation is in accordance with our preclinical studies, in which we demonstrated that tumors treated by electrochemotherapy with cisplatin regressed slowly compared to tumors treated by electrochemotherapy with bleomycin (2 , 4 , 7, 8, 9) . The possible underlying mechanism for this observation is apoptosis, which is the predominant manner of cell death after cisplatin therapy. Therefore, for additional studies, an 8-week interval is recommended for the evaluation of patients.

Although resistance of tumor cells to cisplatin represents a specific problem, we did not observe the development of resistance in up to four sessions. This topic was addressed in our previous study, which demonstrated that electroporation of cisplatin-resistant cells in vitro potentiates the cell killing induced by cisplatin (20) . Also, in our previous clinical study, we did not observe the development of resistance in squamous cell carcinomas: the patient was treated in six consecutive sessions; and a good antitumor effect was observed each time (11) .

Recently, we have provided data that the application of electric pulses induces a reduction in tumor blood flow in addition to increasing the delivery of cisplatin into the tumor cells by electroporation (7 , 9 , 21 , 22) . This reduction of tumor blood flow, which lasts for several hours, as demonstrated in experimental tumors, may have additional implications on the antitumor effectiveness of cisplatin. Therefore, entrapment of the drug in the tumors caused by a reduction of tumor blood flow prolongs the exposure of tumor cells to cisplatin and enhances its effectiveness (7 , 9) .

In conclusion, this Phase II clinical study demonstrates the high effectiveness of electrochemotherapy with cisplatin on malignant melanoma nodules. The advantages of this therapy are its simplicity, the short duration of treatment sessions, low cisplatin doses, insignificant side effects, and, due to all of the above, the fact that it can be performed on outpatient basis. Therefore, this must be considered the treatment of choice not only for patients in whom the cutaneous disease is in progression, but also in less advanced clinical cases. Optimization of electric field distribution in the tumors by numerical modeling and testing of new types and configuration of electrodes (23, 24, 25) will lead to advances in this therapy, which will, in turn, enable the treatment of tumors located deeper in the body.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Supported by the Ministry of Science and Technology of the Republic of Slovenia.

² To whom requests for reprints should be addressed, at Institute of Oncology Ljubljana, Zaloka 2, SI-1000 Ljubljana, Slovenia. Phone/Fax: 386-61-133-74-10; E-mail: gsersa{at}onko-i.si

³ The abbreviations used are: PD, progressive disease; CR, complete response; PR, partial response; NC, no change.

Received 10/29/98; revised 6/24/99; accepted 9/14/99.

	REFERENCES

Top ABSTRACT INTRODUCTION PATIENTS AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Langer R. New methods of drug delivery. Science (Washington DC), 249: 1527-1533, 1990.[Abstract/Free Full Text]
2. Mir L. M., Orlowski S., Belehradek J., Jr., Teissie J., Rols M. P., Sera G., Miklavi D., Gilbert R., Heller R. Biomedical applications of electric pulses with special emphasis on antitumor electrochemotherapy. Bioelectrochem. Bioenerg., 38: 203-207, 1995.[CrossRef]
3. Rols M. P., Teissie J. Electropermeabilization of mammalian cells. Quantitative analysis of the phenomenon. Biophys. J., 58: 1089-1098, 1990.[Medline]
4. Sera G., emaar M., Miklavi D. Antitumor effectiveness of electrochemotherapy with cis-diamminedichloroplatinum(II) in mice. Cancer Res., 55: 3450-3455, 1995.[Abstract/Free Full Text]
5. Mir L. M., Orlowski S., Belehradek J., Jr., Paoletti C. Electrochemotherapy potentiation of antitumor effect of bleomycin by local electric pulses. Eur. J. Cancer, 27: 68-72, 1991.
6. Heller R., Jaroszeski M., Leo-Messina J., Perrot R., Van Voorhis N., Reintgen D., Gilbert R. Treatment of B16 mouse melanoma with the combination of electropermeabilization and chemotherapy. Bioelectrochem. Bioenerg., 36: 83-87, 1995.[CrossRef]
7. emaar M., Milai R., Miklavi D., Dolan V., Sera G. Intratumoral cisplatin administration in electrochemotherapy: antitumor effectiveness, sequence dependence and platinum content. Anti-Cancer Drugs, 9: 525-530, 1998.[Medline]
8. emaar M., Miklavi D., Vodovnik L., Jarm T., Rudolf Z., tabuc B., ufer T., Sera G. Improved therapeutic effect of electrochemotherapy with cisplatin by intratumoral drug administration and changing of electrode orientation for electropermeabilization on EAT tumors in mice. Radiol. Oncol., 29: 121-127, 1995.
9. emaar M., Miklavi D., anar J., Dolan V., Golouh R., Sera G. Increased platinum accumulation in SA-1 tumor cells after in vivo electrochemotherapy with cisplatin. Br. J. Cancer, 79: 1386-1391, 1999.[CrossRef][Medline]
10. Mir L. M., Glass L. F., Sera G., Teissie J., Domenge C., Miklavi D., Jaroszeski M. J., Orlowski S., Reintgen D. S., Rudolf Z., Belehradek M., Gilbert R., Rols M. P., Belehradek J., Jr., Bachaud J. M., DeConti R., tabuc B., emaar M., Coninx P., Heller R. Effective treatment of cutaneous and subcutaneous malignant tumors by electrochemotherapy. Br. J. Cancer, 77: 2336-2342, 1998.[Medline]
11. Sera G., tabuc B., emaar M., Janar B., Miklavi D., Rudolf Z. Electrochemotherapy with cisplatin: potentiation of local cisplatin antitumor effectiveness by application of electric pulses in cancer patients. Eur. J. Cancer, 34: 1213-1218, 1998.
12. Rudolf Z., tabuc B., emaar M., Miklavi D., Vodovnik L., Sera G. Electrochemotherapy with bleomycin: the first clinical experience in malignant melanoma patients. Radiol. Oncol., 29: 229-235, 1995.
13. Domenge C., Orlowski S., Luboinski B., De Baere T., Belehradek J., Jr., Mir L. M. Antitumor electrochemotherapy. New advances in the clinical protocol. Cancer (Phila.), 77: 956-963, 1996.
14. Heller R., Jaroszeski M., Glass F., Messina J. L., Rapaport D. P., Fenske N. A., Gilbert R., Mir L. M., Reintgen D. S. Phase I/II trial for the treatment of cutaneous and subcutaneous tumors using electrochemotherapy. Cancer (Phila.), 77: 964-971, 1996.[CrossRef][Medline]
15. Reintgen, D. S., Jaroszeski, M. J., and Heller, R. Electrochemotherapy, a novel approach to cancer. Skin Cancer Foundation, 14: 17–19, 83, 1996.
16. Glass L. F., Jarozseski M., Gilbert R., Reintgen D. S., Heller R. Intralesional bleomycin-mediated electrochemotherapy in 20 patients with basal cell carcinoma. J. Am. Acad. Dermatol., 37: 596-599, 1997.[CrossRef][Medline]
17. Panje W. R., Hier M. P., Garman G. R., Harrel E., Goldman A., Bloch I. Electroporation therapy of head and neck cancer. Ann. Otol. Rhinol. Laryngol., 107: 779-785, 1998.[Medline]
18. Heller R., Jaroszeski M. J., Reintgen D. S., Puleo C. A., DeConti R. C., Gilbert R. A., Glass L. F. Treatment of cutaneous and subcutaneous tumors with electrochemotherapy using intralesional bleomycin. Cancer (Phila.), 83: 148-157, 1998.[CrossRef][Medline]
19. WHO Handbook for Reporting Results of Cancer Treatment, Vol. 48, pp. 22–27. Geneva: WHO Offset Publications, 1979.
20. emaar, M., Sera, G., and Miklavi, D. Electrochemotherapy with cisplatin in treatment of tumor cells resistant to cisplatin. Anticancer Res., 18: 4463–4466, 1 1998.
21. Sera G., Beravs K., emaar M., Miklavi D., Demar F. Contrast enhanced MRI assessment of tumor blood volume after application of electric pulses. Electro- Magnetobiol., 17: 297-304, 1998.
22. Sera G., emaar M., Parkins C. S., Chaplin D. J. Tumour blood flow changes induced by application of electric pulses. Eur. J. Cancer, 35: 672-677, 1999.
23. Miklavi D., Beravs K., emrov D., emaar M., Demar F., Sera G. The importance of electric field distribution for effective in vivo electroporation of tissues. Biophys. J., 74: 2152-2158, 1998.[Medline]
24. Gilbert R., Jaroszeski M., Heller R. Novel electrode designs for electrochemotherapy. Biochim. Biophys. Acta, 1334: 9-14, 1997.[Medline]
25. Mir L. M., Devauchelle P., Quintin-Colonna F., Delisle F., Doliger S., Fradelizi D., Belehradek J., Jr., Orlowski S. First clinical trial of cat soft-tissue sarcomas treatment by electrochemotherapy. Br. J. Cancer, 76: 1617-1622, 1997.[Medline]

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