Current uses of isolated limb perfusion in the clinic and a model system for new strategies

Isolated limb perfusion with melphalan is the treatment of choice for multiple (small) melanoma-in-transit metastases. The use of tumour necrosis factor alpha (TNFalpha) in isolated limb perfusion is successful for treatment of locally advanced limb soft-tissue sarcomas and other large tumours; this approach can avoid the need for amputation. TNFalpha was approved in Europe after a multicentre trial in patients with locally advanced soft-tissue sarcomas, deemed unresectable by an independent review committee; the response rate to isolated limb perfusion with TNFalpha plus melphalan was 76% and the limb was saved in 71% of patients. Moreover, the trial showed the efficacy of isolated limb perfusion of TNFalpha and melphalan against various other limb-threatening tumours such as skin cancers and drug-resistant bony sarcomas. Laboratory models of isolated limb perfusion have helped to elucidate mechanisms of action and to develop new treatment modalities. They have identified TNFalpha-mediated vasculotoxic effects on the tumour vasculature and have shown that addition of TNFalpha to the perfusate results in an increase of three to six times in uptake of melphalan or doxorubicin by tumours. New vasoactive drugs and new mechanisms of action are being discovered. Moreover, isolated limb perfusion is an effective modality for gene therapy mediated by an adenoviral vector. Various clinical phase I-II studies can be expected in the next few years.     

Technology insight: Utility of TNF-alpha-based isolated limb perfusion to avoid amputation of irresectable tumors of the extremities

Isolated limb perfusion (ILP) with melphalan is effective in the treatment of small multiple melanoma intransit metastases and is utilized widely for this indication. The treatment is much less effective against bulky melanoma metastases and has uniformly failed in the treatment of irresectable extremity soft tissue sarcomas. The addition of tumor-necrosis factor-alpha (TNF-alpha) to this treatment approach has changed the situation dramatically. High response rates and limb-salvage rates have been reported in multicenter trials that combined ILP with TNF-alpha plus melphalan; these trials resulted in the approval of TNF-alpha for bulky melanoma metastases and soft tissue sarcomas in Europe in 1998. Subsequently, many doctors working in European centers have been trained, and a series of confirmatory reports from single institutions have now been published regarding the efficacy of the procedure. TNF-alpha has an early and a late effect; it enhances tumor-selective drug uptake during the perfusion, and plays an essential role in the subsequent selective destruction of the tumor vasculature. These effects result in a high response rate in bulky tumors, soft tissue sarcomas, bulky melanomas, and various other tumor types. This induction therapy therefore allows tumor remnants to be resected some 3 months after ILP thus avoiding limb amputation. TNF-alpha-based ILP is a well-established treatment that aims to avoid amputations regardless of the tumor size and type. It represents an important example of combination therapy that modulates the tumor vasculature and should be offered in high-volume tertiary referral centers.     

Recombinant human tumor necrosis factor: an efficient agent for cancer treatment

Recombinant human TNF (rhTNF) has a selective effect on endothelial cells in tumour angiogenic vessels. Its clinical use has been limited because of its property to induce vascular collapsus. TNF administration through isolated limb perfusion (ILP) for regionally advanced melanomas and soft tissue sarcomas of the limbs was shown to be safe and efficient. When combined to the alkylating agent melphalan, a single ILP produces a very high objective response rate. ILP with TNF and melphalan provided the proof of concept that a vasculotoxic strategy combined to chemotherapy may produce a strong anti-tumour effect. The registered indication of TNF-based ILP is a regional therapy for regionally spread tumours. In soft tissue sarcomas, it is a limb sparing neoadjuvant treatment and, in melanoma in-transit metastases, a curative treatment. Despite its demonstrated regional efficiency TNF-based ILP is unlikely to have any impact on survival. High TNF dosages induce endothelial cells apoptosis, leading to vascular destruction. However, lower TNF dosage produces a very strong effect that is to increase the drug penetration into the tumour, presumably by decreasing the intratumoural hypertension resulting in better tumour uptake. TNF-ILP allowed the identification of the role of alphaVbeta3 integrin deactivation as an important mechanism of antiangiogenesis. Several recent studies have shown that TNF targeting is possible, paving the way to a new opportunity to administer TNF systemically for improving cancer drug penetration. TNF was the first agent registered for the treatment of cancer that improves drug penetration in tumours and selectively destroys angiogenic vessels.     

The palliative value of tumor necrosis factor alpha-based isolated limb perfusion in patients with metastatic sarcoma and melanoma

BACKGROUND: Both patients with soft tissue sarcoma (STS) and patients with melanoma have limited treatment possibilities once the tumor has metastasized systemically. In patients with extremity STS or bulky melanoma in-transit metastases, the local tumor burden may be so problematic that, even in patients with systemically metastasized disease, an amputation may be inevitable. Isolated limb perfusion (ILP) has proven to be an excellent, local, limb-saving treatment option in patients with locally advanced extremity tumors. In this study, the authors investigated the palliative value of the ILP procedure to avoid amputation in patients who had Stage IV STS and melanoma. METHODS: From 1991 to 2003, of 339 tumor necrosis factor alpha (TNF)-based ILPs, 51 procedures were performed for either Stage IV STS (n = 37 patients) or Stage IV melanoma (n = 14 patients). All patients underwent an ILP with TNF and melphalan of the upper limb (n = 4 patients) or the lower limb (n = 47 patients) with 26-140 mg melphalan and 2-4 mg TNF. RESULTS: The overall response in patients with Stage IV STS was 84%, and their median survival was 12 months after ILP. Limb salvage was achieved in 36 of 37 patients, with 1 patient undergoing amputation due to treatment toxicity. In the patients with Stage IV melanoma, the complete response rate was 43%. All patients with melanoma preserved their limb during a median survival of 7 months. CONCLUSIONS: TNF-based ILP is an excellent procedure that provided tumor control and limb salvage for the short survival of patients with metastasized, very bulky, limb-threatening tumors of the extremity.     

The αVβ3/αVβ5 integrin inhibitor cilengitide augments tumor response to melphalan isolated limb perfusion in a sarcoma model

Isolated limb perfusion (ILP) with melphalan and tumor necrosis factor (TNF)‐α is used to treat bulky, locally advanced melanoma and sarcoma. However, TNF toxicity suggests a need for better‐tolerated drugs. Cilengitide (EMD 121974), a novel cyclic inhibitor of alpha‐V integrins, has both anti‐angiogenic and direct anti‐tumor effects and is a possible alternative to TNF in ILP. In this study, rats bearing a hind limb soft tissue sarcoma underwent ILP using different combinations of melphalan, TNF and cilengitide in the perfusate. Further groups had intra‐peritoneal (i.p.) injections of cilengitide or saline 2 hr before and 3 hr after ILP. A 77% response rate (RR) was seen in animals treated i.p. with cilengitide and perfused with melphalan plus cilengitide. The RR was 85% in animals treated i.p. with cilengitide and ILP using melphalan plus both TNF and cilengitide. Both RRs were significantly greater than those seen with melphalan or cilengitide alone. Histopathology showed that high RRs were accompanied by disruption of tumor vascular endothelium and tumor necrosis. Compared with ILP using melphalan alone, the addition of cilengitide resulted in a three to sevenfold increase in melphalan concentration in tumor but not in muscle in the perfused limb. Supportive in vitro studies indicate that cilengitide both inhibits tumor cell attachment and increases endothelial permeability. Since cilengitide has low toxicity, these data suggest the agent is a good alternative to TNF in the ILP setting.     

Isolated limb perfusion for soft tissue sarcoma: Current practices and future directions. A survey of experts and a review of literature

Soft tissue sarcomas constitute 1% of adult malignant tumors. They are a heterogeneous group of more than 50 different histologic types. Isolated limb perfusion is an established treatment strategy for locally advanced sarcomas. Since its adoption for sarcomas in 1992, after the addition of TNFα, few modifications have been done and although indications for the procedure are essentially the same across centers, technical details vary widely. The procedures mainly involves a 60 min perfusion with melphalan and TNFα under mild hyperthermia, achieving a limb preservation rate of 72–96%; with an overall response rates from 72 to 82.5% and an acceptable toxicity according to the Wieberdink scale. The local failure rate is 27% after a median follow up of 14–31 months compared to 40% of distant recurrences after a follow up of 12–22 months. Currently there is no consensus regarding the benefit of ILP per histotype, and the value of addition of radiotherapy or systemic treatment. Further developments towards individualized treatments will provide a better understanding of the population that can derive maximum benefit of ILP with the least morbidity.     

Isolated limb perfusion with melphalan,tumour necrosis factor‐alpha and oncolytic vaccinia virus improves tumour targeting and prolongs survival in a rat model of advanced extremity sarcoma

Isolated limb perfusion (ILP) is a treatment for advanced extremity sarcoma and in‐transit melanoma. Advancing this procedure by investigating the addition of novel agents, such as cancer‐selective oncolytic viruses, may improve both the therapeutic efficacy of ILP and the tumour‐targeted delivery of oncolytic virotherapy. Standard in vitro assays were used to characterise single agent and combinatorial activities of melphalan, tumour necrosis factor‐alpha (TNF‐α) and Lister strain vaccinia virus (GLV‐1h68) against BN175 rat sarcoma cells. An orthotopic model of advanced extremity sarcoma was used to evaluate survival of animals after ILP with combinations of TNF‐α, melphalan and GLV‐1h68. We investigated the efficiency of viral tumour delivery by ILP compared to intravenous therapy, the locoregional and systemic biodistribution of virus after ILP, and the effect of mode of administration on antibody response. The combination of melphalan and GLV‐1h68 was synergistic in vitro. The addition of virus to standard ILP regimens was well tolerated and demonstrated superior tumour targeting compared to intravenous administration. Triple therapy (melphalan/TNF‐α/GLV‐1h68) resulted in increased tumour growth delay and enhanced survival compared to other treatment regimens. Live virus was recovered in large amounts from perfused regions, but in smaller amounts from systemic organs. The addition of oncolytic vaccinia virus to existing TNF‐α/melphalan‐based ILP strategies results in survival advantage in an immunocompetent rat model of advanced extremity sarcoma. Virus administered by ILP has superior tumour targeting compared to intravenous delivery. Further evaluation and clinical translation of this approach is warranted.     

Isolated limb perfusion: the European experience

Isolated limb perfusion (ILP) is a method of cancer treatment allowing the administration of high doses of anticancer agents in a limb surgically isolated from systemic circulation. By using continuous leakage monitoring and using the drug melphalan, a high complete remission rate is obtained in patients with melanoma. In patients with sarcomas, ILP with tumor necrosis factor and melphalan represents a neoadjuvant treatment for limb-sparing surgery. This treatment is the first demonstration of an active anti-angiogenic regimen in the clinic.     

Nitric oxide synthase inhibition results in synergistic anti-tumour activity with melphalan and tumour necrosis factor alpha-based isolated limb perfusions

Nitric oxide (NO) is an important molecule in regulating tumour blood flow and stimulating tumour angiogenesis. Inhibition of NO synthase by L-NAME might induce an anti-tumour effect by limiting nutrients and oxygen to reach tumour tissue or affecting vascular growth. The anti-tumour effect of L-NAME after systemic administration was studied in a renal subcapsular CC531 adenocarcinoma model in rats. Moreover, regional administration of L-NAME, in combination with TNF and melphalan, was studied in an isolated limb perfusion (ILP) model using BN175 soft-tissue sarcomas. Systemic treatment with L-NAME inhibited growth of adenocarcinoma significantly but was accompanied by impaired renal function. In ILP, reduced tumour growth was observed when L-NAME was used alone. In combination with TNF or melphalan, L-NAME increased response rates significantly compared to perfusions without L-NAME (0-64% and 0-63% respectively). An additional anti-tumour effect was demonstrated when L-NAME was added to the synergistic combination of melphalan and TNF (responses increased from 70 to 100%). Inhibition of NO synthase reduces tumour growth both after systemic and regional (ILP) treatment. A synergistic anti-tumour effect of L-NAME is observed in combination with melphalan and/or TNF using ILP. These results indicate a possible role of L-NAME for the treatment of solid tumours in a systemic or regional setting.     

Isolated Limb Perfusion for Malignant Melanoma: Systematic Review on Effectiveness and Safety

Background.

Isolated limb perfusion (ILP) involves the administration of chemotherapy drugs directly into a limb involved by locoregional metastases. Unresectable locally advanced melanoma of the limbs represents one of the clinical settings in which ILP has demonstrated benefits.

Methods.

A systematic review of the literature on ILP for patients with unresectable locally advanced melanoma of the limbs was conducted. MEDLINE, EMBASE, and Cochrane database searches were conducted to identify studies fulfilling the following inclusion criteria: hyper- or normothermic ILP with melphalan with or without tumor necrosis factor (TNF) or other drugs providing valid data on clinical response, survival, or toxicity. To allocate levels of evidence and grades of recommendation the Scottish Intercollegiate Guidelines Network system was used.

Results.

Twenty-two studies including 2,018 ILPs were selected with a clear predominance of observational studies (90.90%) against experimental studies (9.10%). The median complete response rate to ILP was of 58.20%, with a median overall response rate of 90.35%. ILP with melphalan yielded a median complete response rate of 46.50%, against a 68.90% median complete response rate for melphalan plus TNF ILP. The median 5-year overall-survival rate was 36.50%, with a median overall survival interval of 36.70 months. The Wieberdink IV and V regional toxicity rates were 2.00% and 0.65%, respectively.

Conclusions.

ILP is effective in achieving clinical responses in patients with unresectable locally advanced melanoma of the limbs. The disease-free and overall survival rates provided by ILP are acceptable. ILP is safe, with a low incidence of severe regional and systemic toxicity.     

TNF-based isolated limb perfusion in unresectable extremity desmoid tumours.

BACKGROUND: Desmoid tumours are soft tissue sarcomas with local aggressive behaviour and a high rate of local recurrence after treatment. Although they do not tend to metastasise systemically, the local aggressiveness can lead to situations in which limb-preserving surgery cannot be performed without severe disability. As isolated limb perfusion (ILP) with TNF and melphalan has proven to be extremely effective in the treatment of soft tissue sarcoma, we studied its potential in locally advanced extremity desmoid tumours. METHODS: Prospectively maintained database in a tertiary referral centre. Between 1991 and 2003, 12 ILP procedures were performed in 11 patients for locally advanced desmoid tumours. Local surgical therapy with preservation of limb function was impossible in all patients due to large or multifocal tumours, multiple recurrences or extensive previous treatment. Perfusions were performed with 4-3mg TNF and 10-13 mg/l limb volume melphalan form leg and arm perfusions, respectively. RESULTS: Overall response rate was 75%: Two complete responses were recorded (17%) and seven patients had a partial response (58%). Amputation could be avoided in all cases. Local control was obtained after 10/12 ILPs and in the other two patients through repeat ILP and systemic chemotherapy, thus leading to an overall local control rate of 100%. Local toxicity was mild and systemic toxicity was absent in all patients. CONCLUSION: ILP is a very effective treatment option in the multimodality treatment of limb desmoid tumours. It should be considered in patients with aggressive and disabling disease where resection without important functional sacrifice is impossible.     

Isolated limb perfusion for unresectable extremity sarcoma: results of 2 single-institution phase 2 trials

BACKGROUND:

Controversy has surrounded the role of isolated limb perfusion (ILP) for unresectable extremity sarcomas. However, there remains a group of sarcoma patients for whom amputation is the only potential treatment. Because systemic therapies are limited, the authors evaluated ILP in an effort to provide a limb‐salvage option.

METHODS:

Since 1995, patients with unresectable extremity sarcomas were entered in 2 prospective trials using ILP. Study 1 used tumor necrosis factor (TNF) and melphalan in the perfusion circuit at hyperthermic temperatures (39‐41°C). Study 2 used doxorubicin at normothermic temperatures. All ILPs were performed using the standard, previously described technique.

RESULTS:

Seventeen patients were entered into study 1; there were 10 (58%) partial responses, 1 (6%) near complete response (CR), 1 (6%) CR, and 5 (30%) no response/minor response. Fourteen patients died of their disease, with a median follow‐up of 17 months. Seven (41%) patients maintained their limb intact until the time of death. Twelve patients were entered into study 2; there were no partial or CRs and 2 (20%) minor responses. With a median follow‐up of 35 months, there are 3 patients alive (2 with their extremity intact and 1 with an amputation). Six patients developed myonecrosis with creatine phosphokinase levels up to 54,000 U/dL.

CONCLUSIONS:

Although doxorubicin is active systemically, TNF and melphalan appear to have greater activity and less toxicity during ILP. Future clinical trials are needed to clearly identify the role for ILP in patients with unresectable extremity sarcomas. Cancer 2011. © 2011 American Cancer Society.     

Prerequisites for effective isolated limb perfusion using tumour necrosis factor alpha and melphalan in rats.

An isolated limb perfusion (ILP) model using soft tissue sarcoma-bearing rats was used to study prerequisites for an effective ILP, such as oxygenation of the perfusate, temperature of the limb, duration of the perfusion and concentration of tumour necrosis factor (TNF). Combination of 50 microg TNF and 40 microg melphalan demonstrated synergistic activity leading to a partial and complete response rate of 71%. In comparison to oxygenated ILP, hypoxia was shown to enhance anti-tumour activity of melphalan alone and TNF alone but not of their combined use. Shorter perfusion times decreased anti-tumour responses. At a temperature of 24-26 degrees C, anti-tumour effects were lost, whereas temperatures of 38-39 degrees C or 42-43 degrees C resulted in higher response rates. However, at 42-43 degrees C, local toxicity impaired limb function dramatically. Synergy between TNF and melphalan was lost at a dose of TNF below 10 microg in 5 ml perfusate. We conclude that the combination of TNF and melphalan has strong synergistic anti-tumour effects in our model, just as in the clinical setting. Hypoxia enhanced activity of melphalan and TNF alone but not the efficacy of their combined use. For an optimal ILP, minimal perfusion time of 30 min and minimal temperature of 38 degrees C was mandatory. Moreover, the dose of TNF could be lowered to 10 microg per 5 ml perfusate, which might allow the use of TNF in less leakage-free or less inert perfusion settings.     

Isolated limb perfusion with melphalan for femoral metastases of breast cancer: case report

BACKGROUND AND OBJECTIVES: Complications of bone destruction occur in 10-29% of breast cancer patients with skeletal metastases. Palliative treatment consists of systemic chemotherapy, hormonal treatment, radiotherapy, and/or surgery in the case of (impending) fracture. A case is presented where isolated limb perfusion was applied for this indication. METHODS: A 43-year-old woman with extensive femoral metastases of breast cancer with impending fracture was treated with isolated limb perfusion (ILP) with melphalan. Radiotherapy had resulted only in pain reduction, and intramedullary fixation was opted against because stable fixation was considered not feasible due to the location of the metastases. ILP with high-dose melphalan (10-20 times the amount that can be administered systemically) under normothermic (37-38 degrees C) conditions, resulted in partial remission and reossification. RESULTS: One year after ILP, until her death 2 years later, due to progressive metastases at other sites, the patient was able to bear weight again on her left leg. CONCLUSIONS: In selected patients with symptomatic large bone metastases from breast cancer, and no other treatment options, ILP with melphalan may be used for successful palliation.     

Melan-A specific CD8+ T lymphocytes after hyperthermic isolated limb perfusion: A pilot study in patients with in-transit metastases of malignant melanoma

Abstract

Purpose: Isolated limb perfusion (ILP) with hyperthermia is an effective treatment for in-transit metastases of malignant melanoma in the extremities. Preclinical studies have shown that hyperthermia may induce an immunogenic death of tumour cells. We therefore decided to study whether ILP may induce tumour-specific immune responses in the clinical setting.

Method: The number of Melan-A/Mart-1 specific CD8+ T cells, as well as other phenotypically different immune cells, was recorded in peripheral blood in 12 HLA-A2+ patients with in-transit metastases undergoing hyperthermic ILP with melphalan.

Results: All patients underwent ILP without any complication and with an overall response rate of 83%. No substantial changes in the number of circulating T-cells, B-cells, NK-cells or monocytes were observed during follow-up. Four out of 12 patients showed an elevation of Melan-A+ CD8+ T-cells 4 weeks after ILP.

Conclusion: We here report our preliminary observations that a small increase in tumour-specific T-cells could be seen in a subpopulation of patients after ILP. However, much more work is necessary to fully delineate the systemic immune response to hyperthermic ILP.     

Isolated Limb Perfusion with Melphalan and TNF-α in the Treatment of Extremity Sarcoma

Opinion statement Isolated limb perfusion (ILP) with chemotherapy alone has uniformly failed in the treatment of irresectable extremity soft tissue sarcomas. The addition of tumor necrosis factor-alpha (TNF-α) to this treatment approach contributed to a major step forward in the treatment of locally advanced extremity soft tissue sarcoma (STS). High response rates and limb salvage rates have been reported in multicenter trials, which combined ILP with TNF-α plus melphalan, which resulted in the approval of TNF-α for this indication in Europe in 1998. Subsequently a series of confirmatory single institution reports on the efficacy of the procedure have now been published. TNF-α has an early and a late effect; it enhances tumor-selective drug uptake during the perfusion and plays an essential role in the subsequent selective destruction of the tumor vasculature. These effects result in a high response rate in high-grade soft tissue sarcomas. This induction therapy thus allows for resection of tumor remnants some 3 months after ILP and thus avoidance of limb amputation. TNF-α-based ILP is a well-established treatment to avoid amputations. It represents an important example of tumor vasculatory-modulating combination therapy and should be offered in large volume tertiary referral centers.     

Isolated limb perfusion with tumour necrosis factor-alpha and melphalan for unresectable bone sarcomas of the lower extremity.

AIMS: Isolated limb perfusion (ILP) with recombinant tumour necrosis factor-alpha (rTNF-alpha) and melphalan has recently been reported to induce major tumour responses and permit limb salvage in over 80% of patients with unresectable soft-tissue sarcomas of the extremities. We investigated whether TNF-based ILP could allow limb-sparing surgery in patients with primary, recurrent or metastatic bone sarcoma to the lower extremity who met the criteria for an amputation and had failed or refused chemotherapy. METHODS: From August 1992 to December 1997, we employed ILP with rTNF-alpha and melphalan in 13 patients with unresectable bone sarcoma of the lower extremity, all of whom were candidates for amputation. The aim was to reduce tumour size and allow the performance of a limb-sparing surgery (LSS). RESULTS: Following ILP, none of the patients had severe local toxicity and only one patient experienced significant systemic side-effects. LSS was subsequently performed in nine of the 13 patients. LSS was feasible in an additional three patients but was not performed because of the emergence of diffused metastatic disease. CONCLUSIONS: ILP with rTNF-alpha and melphalan can allow limb salvage in patients wih locally advanced bone sarcomas who had failed standard treatment options. Its potential role in the treatment of unresectable bone sarcomas of the extremities merits further evaluation.     

Regional toxicity after isolated limb perfusion with melphalan and tumour necrosis factor- alpha versus toxicity after melphalan alone.

AIMS: To determine whether the addition of high-dose tumour necrosis factor-alpha (TNF alpha) to isolated limb perfusion (ILP) with melphalan increases acute regional tissue toxicity compared to ILP with melphalan alone. METHODS: A retrospective, multivariate analysis of toxicity after normothermic (37--38 degrees C) and 'mild' hyperthermic (38--40 degrees C) ILPs for melanoma was undertaken. Normothermic ILP with melphalan was performed in 294 patients (70.8%), 'mild' hyperthermic ILP with melphalan in 71 patients (17.1%) and 'mild' hyperthermic ILP with melphalan combined with TNF alpha in 50 patients (12.0%). Toxicity was nil or mild (grades I--II according to Wieberdink et al.) in 339 patients (81.7%), and more severe acute regional toxicity (grades III--V) developed in 76 patients (18.3%). A stepwise logistic regression procedure was performed for the multivariate analysis of prognostic factors for more severe toxicity. RESULTS: On univariate analysis, 'mild' hyperthermic ILP with melphalan plus TNF alpha significantly increased the incidence of more severe acute regional toxicity compared to normothermic and 'mild' hyperthermic ILP with melphalan alone (36% vs 16% and 17%; P=0.0038). However, after ILP using TNF alpha no grade IV (compartment compression syndrome) or grade V (toxicity necessitating amputation) reactions were seen. Significantly more severe toxicity was seen after ILPs performed between 1991 and 1994 compared with earlier ILPs (33%vs 14%P=0.0001). Also, women had a higher risk of more severe toxicity than men (22% vs 7%; P=0.0007). After multivariate analysis, prognostic factors which remained significant were: sex (P=0.0013) and either ILP schedule (P=0.013) or treatment period (P=0.0003). CONCLUSIONS: Regional toxicity after 'mild' hyperthermic ILP with melphalan and TNF alpha was significantly increased compared to ILP with melphalan alone. This may be caused by increased thermal enhancement of melphalan due to the higher tissue temperatures (39--40 degrees C) at which the melphalan in the TNF alpha-ILPs was administered or by an interaction between high-dose TNF alpha and melphalan. Copyright Harcourt Publishers Limited.     

Isolated limb perfusion with tumor necrosis factor-alpha and melphalan for patients with unresectable soft tissue sarcoma of the extremities

BACKGROUND: Since 1992, isolated limb perfusion (ILP) with tumor necrosis factor-alpha (TNFalpha) and melphalan has been used for the treatment of patients with unresectable soft tissue sarcomas of the extremities. The authors retrospectively studied the results of limb salvage surgery using TNFalpha-ILP at their institution. METHODS: From 1992 to 2001, 49 patients (mean age, 51 years; range, 14-85 years) underwent ILP for unresectable soft tissue sarcomas of the extremities. All patients received melphalan and TNFalpha (four patients also received interferon-gamma). The median follow-up was 26 months (range, from 2 days to 103 months). RESULTS: In 1 patient (2%) who died 2 days after undergoing ILP, response and acute limb toxicity could not be assessed. One patient (2%) attained a clinical complete response (2%), 23 patients (47%) attained a clinical partial response, 17 patients (35%) demonstrated no change, and 7 patients (14%) had tumor progression. Thirty-one patients (63%) underwent tumor resection. Histologic material also was available from eight amputations and three punctures/biopsies. Pathologic response was complete in 4 patients (8%), partial in 14 patients (29%), and no change was observed in 24 patients (49%). Final response, based on both clinical and pathologic assessment in which pathology was decisive, was complete in 4 patients (8%) and partial in 27 patients (55%), resulting in a final overall response rate of 63%. Local control with preservation of the limb was attained in 28 patients (57%). Four of 32 patients (13%) who had been rendered tumor free by ILP with or without undergoing resection and radiation therapy, developed a local recurrence. The 5-year disease specific survival rate was 48% for the 49 patients. Acute limb toxicity after ILP was a mild Grade 1-2 reaction in 35 patients (71%) patients, a Grade 3 reaction in 12 patients (25%), and a Grade 4 reaction in 1 patient (2%). Three major ILP-related complications were encountered, including arterial thrombosis in two patients and a fulminant Clostridial infection leading to death in one patient. There were no severe cardiovascular reactions after ILP. CONCLUSIONS: In patients with unresectable soft tissue sarcomas of the limbs who underwent ILP with TNFalpha and melphalan followed by resection of the tumor remnant when possible, a 63% overall tumor response rate and a 57% local control rate with limb preservation was achieved.     

Outcome and prognostic factor analysis of 217 consecutive isolated limb perfusions with tumor necrosis factor-alpha and melphalan for limb-threatening soft tissue sarcoma

BACKGROUND: Extensive and mutilating surgery is often required for locally advanced soft tissue sarcoma (STS) of the limb. As it has become apparent that amputation for STS does not improve survival rates, the interest in limb-preserving approaches has increased. Isolated limb perfusion (ILP) with tumor necrosis factor-alpha (TNF) and melphalan is successful in providing local tumor control and enables limb-preserving surgery in a majority of cases. A mature, large, single-institution experience with 217 consecutive ILPs for STS of the extremity is reported. METHODS: At a prospectively maintained database at a tertiary referral center, 217 ILPs were performed from July 1991 to July 2003 in 197 patients with locally advanced STS of the extremity. ILPs were performed at mild hyperthermic conditions with 1-4 mg of TNF and 10-13 mg/L limb-volume melphalan (M) for leg and arm perfusions, respectively. RESULTS: The overall response rate was 75%. Limb salvage was achieved in 87% of the perfused limbs. Median survival post-ILP was 57 months and prognostic factors for survival were Trojani grade of the tumor and ILP for single versus multiple STS. The procedure could be performed safely, with a perioperative mortality of 0.5% in all patients with no age limit (median age, 54 yrs; range, 12-91). Systemic and locoregional toxicity were modest and easily manageable. CONCLUSION: TNF+M-based ILP can provide limb salvage in a significant percentage of patients with locally advanced STS and has therefore gained a permanent place in the multimodality treatment of STS.