Elisabeth D. Geijsen

Hyperthermia, cisplatin and radiation trimodality treatment: a promising cancer treatment? A review from preclinical studies to clinical application.

This review discusses available clinical and experimental data and the underlying mechanisms involved in trimodality treatment consisting of hyperthermia, cisplatin and radiotherapy. The results of phase I/II clinical trials show that trimodality treatment is effective and feasible in various cancer types and sites with tolerable toxicity. Based on these results, phase III trials have been launched to investigate whether significant differences in treatment outcome exist between trimodality and standard treatment. In view of the clinical interest, it is surprising to find so few preclinical studies on trimodality treatment. Although little information is available on the doses of the modalities and the treatment sequence resulting in the largest degree of synergistic interaction, the results from in vivo and in vitro preclinical studies support the use of trimodality treatment for cancer patients. Animal studies show an improvement in treatment outcome after trimodality treatment compared with mono- and bimodality treatment. Studies in different human tumour cell lines show that a synergistic interaction can be obtained between hyperthermia, cisplatin and radiation and that this interaction is more likely to occur in cell lines which are more sensitive to cisplatin.

Definitive chemoradiation for patients with inoperable and/or unresectable esophageal cancer: locoregional recurrence pattern

A locoregional recurrence after definitive chemoradiation (dCRT) for patients with inoperable or unresectable esophageal cancer occurs in about 50% of the patients and is a major cause of failure with a poor prognosis. The aim of this study was to determine the pattern of locoregional recurrence and its prognostic factors after dCRT in order to search for improvements in radiation treatment. We retrospectively reviewed 184 patients treated with external beam radiotherapy (50.4 Gray/28 fractions), combined with weekly concurrent paclitaxel and carboplatin. Locoregional recurrences were defined by clinical signs of recurrent or progressive disease, combined with progression on computed tomography/positron emission tomography-computed tomography scan, or suspicious endoscopic findings and/or histological proof of recurrence. The site of locoregional recurrence was analyzed with respect to the borders of the radiation fields. After a mean follow up of 22.8 months, 76 patients (41%) had evidence of locoregional recurrence. The 3-years locoregional recurrence-free rate was 45%. The majority of locoregional recurrences occurred within 12 months, nearly all within 24 months. The majority of these patients failed at the site of the primary tumor (86%). Infield locoregional recurrences at the site of the lymph nodes only occurred in 1% compared with 57% at the site of the primary tumor only. Outfield locoregional lymph node recurrences occurred in 22%, without infield recurrence occurred in only 4% of all patients. The 1-, 3-, and 5-year overall survival was 65%, 28%, and 21%, respectively. The current analysis demonstrates that a locoregional recurrence after dCRT occurs in 41% of the patients, the majority at the site of the primary tumor. These data suggest a benefit of dose intensification of the primary tumor, but not at the site of the lymph nodes. Higher radiation doses should be assessed with prospective trials.

Prospective treatment planning to improve locoregional hyperthermia for oesophageal cancer

Background: In the Academic Medical Center (AMC) Amsterdam, locoregional hyperthermia for oesophageal tumours is applied using the 70 MHz AMC-4 phased array system. Due to the occurrence of treatment-limiting hot spots in normal tissue and systemic stress at high power, the thermal dose achieved in the tumour can be sub-optimal. The large number of degrees of freedom of the heating device, i.e. the amplitudes and phases of the antennae, makes it difficult to avoid treatment-limiting hot spots by intuitive amplitude/phase steering. Aim: Prospective hyperthermia treatment planning combined with high resolution temperature-based optimization was applied to improve hyperthermia treatment of patients with oesophageal cancer. Methods: All hyperthermia treatments were performed with ‘standard’ clinical settings. Temperatures were measured systemically, at the location of the tumour and near the spinal cord, which is an organ at risk. For 16 patients numerically optimized settings were obtained from treatment planning with temperature-based optimization. Steady state tumour temperatures were maximized, subject to constraints to normal tissue temperatures. At the start of 48 hyperthermia treatments in these 16 patients temperature rise (ΔT) measurements were performed by applying a short power pulse with the numerically optimized amplitude/phase settings, with the clinical settings and with mixed settings, i.e. numerically optimized amplitudes combined with clinical phases. The heating efficiency of the three settings was determined by the measured ΔT values and the ΔT-ratio between the ΔT in the tumour (ΔToes) and near the spinal cord (ΔTcord). For a single patient the steady state temperature distribution was computed retrospectively for all three settings, since the temperature distributions may be quite different. To illustrate that the choice of the optimization strategy is decisive for the obtained settings, a numerical optimization on ΔT-ratio was performed for this patient and the steady state temperature distribution for the obtained settings was computed. Results: A higher ΔToes was measured with the mixed settings compared to the calculated and clinical settings; ΔTcord was higher with the mixed settings compared to the clinical settings. The ΔT-ratio was ∼1.5 for all three settings. These results indicate that the most effective tumour heating can be achieved with the mixed settings. ΔT is proportional to the Specific Absorption Rate (SAR) and a higher SAR results in a higher steady state temperature, which implies that mixed settings are likely to provide the most effective heating at steady state as well. The steady state temperature distributions for the clinical and mixed settings, computed for the single patient, showed some locations where temperatures exceeded the normal tissue constraints used in the optimization. This demonstrates that the numerical optimization did not prescribe the mixed settings, because it had to comply with the constraints set to the normal tissue temperatures. However, the predicted hot spots are not necessarily clinically relevant. Numerical optimization on ΔT-ratio for this patient yielded a very high ΔT-ratio (∼380), albeit at the cost of excessive heating of normal tissue and lower steady state tumour temperatures compared to the conventional optimization. Conclusion: Treatment planning can be valuable to improve hyperthermia treatments. A thorough discussion on clinically relevant objectives and constraints is essential.

Toward Online Adaptive Hyperthermia Treatment Planning: Correlation Between Measured and Simulated Specific Absorption Rate Changes Caused by Phase Steering in Patients

PURPOSE Hyperthermia is the clinical application of heat, in which tumor temperatures are raised to 40°C to 45°C. This proven radiation and chemosensitizer significantly improves clinical outcome for several tumor sites. Earlier studies of the use of pre-treatment planning for hyperthermia showed good qualitative but disappointing quantitative reliability. The purpose of this study was to investigate whether hyperthermia treatment planning (HTP) can be used more reliably for online adaptive treatment planning during locoregional hyperthermia treatments. METHODS AND MATERIALS This study included 78 treatment sessions for 15 patients with non-muscle-invasive bladder cancer. At the start of treatments, temperature rise measurements were performed with 3 different antenna settings optimized for each patient, from which the absorbed power (specific absorption rate [SAR]) was derived. HTP was performed based on a computed tomography (CT) scan in treatment position with the bladder catheter in situ. The SAR along the thermocouple tracks was extracted from the simulated SAR distributions. Correlations between measured and simulated (average) SAR values were determined. To evaluate phase steering, correlations between the changes in simulated and measured SAR values averaged over the thermocouple probe were determined for all 3 combinations of antenna settings. RESULTS For 42% of the individual treatment sessions, the correlation coefficient between measured and simulated SAR profiles was higher than 0.5, whereas 58% showed a weak correlation (R of <0.5). The overall correlation coefficient between measured and simulated average SAR was weak (R=0.31; P<.001). The measured and simulated changes in average SAR after adapting antenna settings correlated much better (R=0.70; P<.001). The ratio between the measured and simulated quotients of maximum and average SARs was 1.03 ± 0.26 (mean ± SD), indicating that HTP can also correctly predict the relative amplitude of SAR peaks. CONCLUSIONS HTP can correctly predict SAR changes after adapting antenna settings during hyperthermia treatments. This allows online adaptive treatment planning, assisting the operator in determining antenna settings resulting in increased tumor temperatures.

Elective re-irradiation and hyperthermia following resection of persistent locoregional recurrent breast cancer: A retrospective study

Purpose: To analyse the therapeutic effect and toxicity of re-irradiation (re-RT) combined with hyperthermia (HT) following resection or clinically complete remission (CR) of persistent locoregional recurrent breast cancer in previously irradiated area. Methods and materials: Between 1988 and 2001, 78 patients with high risk recurrent breast cancer underwent elective re-RT and HT. All patients received extensive previous treatments, including surgery and high-dose irradiation (≥50Gy). Most had received one or more lines of systemic therapy; 44% had been treated for ≥ one previous locoregional recurrences. At start of re-RT + HT there was no macroscopically detectable tumour following surgery (96%) or chemotherapy (CT). Re-RT typically consisted of eight fractions of 4Gy, given twice weekly. Hyperthermia was added once a week. Results: After a median follow up of 64.2 months, three-year survival was 66%. Three- and five-year local control rates were 78% and 65%. Acute grade 3 toxicity occurred in 32% of patients. The risk of late ≥ grade 3 toxicity was 40% after three years. Time interval to the current recurrence was found to be most predictive for local control in univariate and multivariate analysis. The extensiveness of current surgery was the most relevant treatment related factor associated with toxicity. Conclusions: For patients experiencing local recurrence in a previously radiated area, re-irradiation plus hyperthermia following minimisation of tumour burden leads to a high rate of local control, albeit with significant toxicity. The latter might be reduced by a more fractionated re-RT schedule.

Preoperative chemoradiation combined with regional hyperthermia for patients with resectable esophageal cancer

Purpose: To analyse the treatment results of neo-adjuvant chemoradiation combined with regional hyperthermia in patients with resectable esophageal cancer. Patients and methods: Between August 2003 and December 2004, 28 patients entered a phase II study combining chemoradiation over a 4.5-week period with five sessions of regional hyperthermia. Chemotherapy consisted of carboplatin (AUC = 2) and paclitaxel (50 mg/m2) and radiotherapy of 41.4 Gy in 1.8 Gy daily fractions. Locoregional hyperthermia was applied using the AMC phased array of four 70 MHz antennas, aiming at a stable tumor temperature of 41°C for one hour. Carboplatin was infused during the hyperthermia session. Esophageal resection was planned at 6–8 weeks after the end of radiotherapy. The majority of the patients had a T3 tumor (86%) and were cN+ (64%). Median follow-up for survivors was 37 months (range 31–46). Results: Twenty-five patients (89%) completed the planned neo-adjuvant treatment and acute toxicity was generally mild. Twenty-six patients were operated on. A pathologically CR, PRmic, PR and SD were seen in 19%, 27%, 31% and 23% respectively. All patients had a R0 resection. In-field locoregional control during follow up for the operated patients was 100%. Quality of life was good for patients without disease progression. Survival rates at one, two and three years were 79%, 57% and 54% respectively. Conclusion: Neo-adjuvant chemoradiation combined with regional hyperthermia followed by esophageal resection for patients with esophageal cancer resulted in good locoregional control and overall survival.

Combining Mitomycin C and Regional 70 MHz Hyperthermia in Patients with Nonmuscle Invasive Bladder Cancer: A Pilot Study

PURPOSE Despite intravesical therapy with immunotherapy or chemotherapy intermediate and high risk nonmuscle invasive bladder cancer is associated with a high risk of recurrence and progression to muscle invasive bladder carcinoma. While intravesical hyperthermia combined with mitomycin C has proved effective to treat nonmuscle invasive bladder cancer, there is less experience with invasive regional 70 MHz hyperthermia and mitomycin C. Therefore, we examined the safety and feasibility of this treatment combination for intermediate and high risk nonmuscle invasive bladder cancer. MATERIALS AND METHODS Between 2009 and 2011, 20 patients with intermediate and high risk nonmuscle invasive bladder cancer were treated with intravesical mitomycin C (40 mg) combined with regional hyperthermia. Treatment consisted of 6 weekly sessions followed by a maintenance period of 1 year with 1 hyperthermia-mitomycin C session every 3 months. Regional hyperthermia was administered using a 70 MHz phased array system with 4 antennas. Toxicity was scored using CTC (Common Toxicity Criteria) 3.0. RESULTS The records of 18 of 20 patients could be analyzed. Median followup was 46 months. Of the 18 patients 15 (83%) completed the induction period of 6 treatments. Four patients (22%) discontinued treatment because of physical complaints without exceeding grade 2 toxicity. Toxicity scored according to CTC 3.0 was limited to grade 1 in 43% of cases and grade 2 in 14%. Mean T90 and T50 bladder temperatures were 40.6C and 41.6C, respectively. The 24-month recurrence-free survival rate was 78%. CONCLUSIONS Treatment with regional hyperthermia combined with mitomycin C in patients with intermediate and high risk nonmuscle invasive bladder cancer is feasible with low toxicity and excellent bladder temperatures.

A systematic review of regional hyperthermia therapy in bladder cancer

Abstract Context: Bladder cancer therapy remains suboptimal as morbidity and mortality remain high amongst those with non-muscle-invasive and muscle-invasive disease. Regional hyperthermia therapy (RHT) is a promising adjunctive therapy being tested in multiple clinical contexts. Objective: The aim of this study was to systematically review the literature on the efficacy and toxicity of RHT. Evidence acquisition: This systematic review was registered with the PROSPERO database (Registration number: CRD42015025780) and was conducted according to the Preferred Reporting Items for Systematic reviews and Meta-Analyses (PRISMA) guidelines. We queried PubMed, EMBASE, and Cochrane libraries. Two reviewers reviewed abstracts independently and a third reviewer arbitrated disagreements. The last search was performed on 28 August 2015. A descriptive analysis was performed and quality assessment was conducted using the Newcastle-Ottawa Quality Assessment Scale for observational studies, and the Cochrane Risk of Bias Assessment Tool for trials. Evidence synthesis: We identified 859 publications in the initial search, of which 24 met inclusion criteria for full-text review. Of these, we were able to obtain data on the outcomes of interest for 15 publications. Conclusions: The review underscores the limited nature of the evidence; definitive conclusions are elusive. However, the promising results of RHT in the setting of intravesical chemotherapy, chemotherapy and radiotherapy show a trend towards legitimate efficacy.

Relation between body size and temperatures during locoregional hyperthermia of oesophageal cancer patients

Purpose. To analyse the relation between patients’ body size and temperatures during locoregional hyperthermia for oesophageal cancer. Methods. Patients were treated with neo-adjuvant chemoradiotherapy plus hyperthermia, given with the AMC-4 waveguide system. Temperatures were measured at tumour location in the oesophageal lumen using multisensor thermocouple probes. Systemic temperature rise (ΔTsyst) was monitored rectally. Steady-state tumour temperatures were expressed in terms of T90, T50 and T10, averaged over the five hyperthermia sessions, and correlated with patients’ body mass, dorsoventral and lateral diameter and fat layer thickness, measured at tumour level using a CT scan made in treatment position. Fat percentage (Fat%) was estimated using diameters and fat layer thickness. Effective tumour perfusion (Wb) was estimated from the temperature decay during the cool-down period. Results. Temperatures were inversely related to body mass, diameters, fat layer thickness, and fat percentage. The strongest univariate correlations were found with lateral fat layer thickness, lateral diameter, and body mass. An increase in lateral diameter (28→42 cm), or in lateral fat layer thickness (0→40 mm) or in body mass (50→120 kg) all yielded a ∼1.5°C decrease in tumour temperature rise. Multivariate correlation analysis proved that the combination of Fat%, ΔTsyst and Wb was most predictive for the achieved tumour temperatures, accounting for 81 ± 12% of the variance in temperatures. Conclusions. Intra-oesophageal temperatures during locoregional hyperthermia are inversely related to patients’ body size parameters, of which fat percentage is the most significant prognostic factor. These findings could be used to define inclusion criteria of new studies on intrathoracic hyperthermia.

Development of Late Toxicity and International Prostate Symptom Score Resolution After External-Beam Radiotherapy Combined With Pulsed Dose Rate Brachytherapy for Prostate Cancer

PURPOSE To investigate the development of gastrointestinal (GI) toxicity, genitourinary (GU) toxicity, erectile dysfunction, and International Prostate Symptom Score (IPSS) resolution in a cohort of patients treated with external-beam radiotherapy (EBRT) followed by a brachytherapy pulsed dose rate (PDR) boost. METHODS AND MATERIALS Between 2002 and 2008, 110 patients were treated with 46-Gy EBRT followed by PDR brachytherapy (24.96-28.80 Gy). The investigated outcome variables, GI toxicity, GU toxicity, erectile dysfunction, and IPSS were prospectively scored at several time points during follow-up. Association between time (as continuous and categorical variable) and the outcome variables was assessed using generalized linear models. RESULTS No statistically significant association was found between time (continuous) and GI toxicity (odds ratio [OR], 0.97; 95% confidence interval [CI], 0.89-1.06), GU toxicity (OR, 0.97; 95% CI, 0.91-1.03), erectile dysfunction (OR, 1.06; 95% CI, 0.99-1.11), and IPSS (-0.11; 95% CI, -0.41-0.20). Also, no statistically significant association was found between these variables and time as a categorical variable. GU toxicity was associated with IPSS resolution (OR, 1.16; 95% CI, 1.09-1.24). Posttreatment IPSS was associated with pretreatment IPSS (0.52; 95% CI, 0.25-0.79). CONCLUSIONS No accumulation of high-grade toxicity over time could be established for a group of patients treated with EBRT and PDR brachytherapy for prostate cancer, probably because high-grade late toxicity resolves with time. Also, differences in IPSS values among patients are smaller after treatment than before treatment.