ORIGINAL ARTICLE Year : 2022  |  Volume : 18  |  Issue : 9  |  Page : 146-150

Comparative study of induction chemotherapy followed by chemoradiotherapy versus chemoradiotherapy alone in locally advanced head and neck cancer

Saroj Dhaka, Shankar Lal Jakhar, Neeti Sharma, Harvinder Singh Kumar, Rajesh Kumar
Department of Radiation Oncology, Acharya Tulsi Regional Cancer Treatment and Research Institute, SP Medical College, Bikaner, Rajasthan, India

Date of Submission17-Jul-2020Date of Decision16-Dec-2020Date of Acceptance25-Dec-2020Date of Web Publication28-May-2021

Correspondence Address:
Shankar Lal Jakhar
Acharya Tulsi Regional Cancer Treatment and Research Institute, SP Medical College, Bikaner, Rajasthan
India

Source of Support: None, Conflict of Interest: None

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DOI: 10.4103/jcrt.JCRT_936_20

Objective: Concurrent chemoradiotherapy (CTRT) is the standard treatment for patients with unresectable, nonmetastatic Locally advanced squamous cell cancer of head and neck (LASCCHN). The aim of this study to compare the efficacy and toxicity of induction chemotherapy (ICT) followed by CTRT versus standard CTRT alone in patients with LASCCHN.
Materials and Methods: Between January 2017 and September 2017, 100 patients with LASCCHN (Stage III and IV) were randomly assigned to two arms: 50 patients in each. Arm A treated by standard CTRT alone (a total 66 Gy in 33fr 2 Gy/# administered daily 5 days/week with 3 weekly inj. cisplatin 100 mg/m2 divided in two days) and Arm B received two cycles of ICT (TPF - inj. paclitaxel 175 mg/m2 on day 1, cisplatin 100 mg/m2 divided in 2 days and inj. 5FU 1 gm/m2 iv d1 and d2 ) followed by same CTRT. Assessment was done weekly during RT and 1, 3, 6, 12, and 18 months posttreatment for treatment response, toxicities, and progression-free survival (PFS).
Results: Total response was observed 79.1% and 82.1% in Arm A and Arm B, respectively (P = 0.705) at 6–8 weeks after the completion of treatment. Acute toxicities were significantly higher in ICT arm. The 18 months PFS was 57% versus 55% in Arm A and Arm B, respectively (x2 = 0.039, P = 0.8414).
Conclusion: Among the patients followed, this study failed to show benefit of ICT-CTRT over CTRT alone in patients of LASCCHN.

Keywords: Chemoradiotherapy, induction chemotherapy, unresectable locally advanced head and neck cancer

How to cite this article:
Dhaka S, Jakhar SL, Sharma N, Kumar HS, Kumar R. Comparative study of induction chemotherapy followed by chemoradiotherapy versus chemoradiotherapy alone in locally advanced head and neck cancer. J Can Res Ther 2022;18, Suppl S2:146-50
How to cite this URL:
Dhaka S, Jakhar SL, Sharma N, Kumar HS, Kumar R. Comparative study of induction chemotherapy followed by chemoradiotherapy versus chemoradiotherapy alone in locally advanced head and neck cancer. J Can Res Ther [serial online] 2022 [cited 2022 Dec 11];18, Suppl S2:146-50. Available from: https://www.cancerjournal.net/text.asp?2022/18/9/146/317069  > Introduction 

The incidence of squamous cell carcinoma of the head and neck (SCCHN) is increasing, and it is the sixth most common malignancy worldwide, with more than 70% of cases occurring in the developing world.[1] It is the third most common cancer in India, over 200,000 new cases are registered every year in India. The male-female ratio ranges from 2:1 to 4:1. About 90% of all head and neck cancers (HNCs) are squamous cell carcinomas, may be due to higher indulgence of alcohol, tobacco, and betel nut chewing. In our institute, Acharya Tulsi Regional Cancer Training and Research Institute 3671 new head and neck cases were registered in 2016.

SCCHN is a locoregional disease; distant metastases are rarely seen at the time of diagnosis. Radiotherapy and surgery are the treatments of choice, with radiotherapy being the favored treatment if organ conservation is concerned.[2] One of the most important biological factors related to the outcome of radiotherapy in squamous cell carcinoma is the proliferation of tumor stem cells during the treatment.[3] A prolonged overall treatment time might reduce the chance of tumor control,[4],[5],[6] and a substantial number of clinical reports show a reduction in overall treatment time might improve tumor control.[7],[8],[9] A shorter treatment time can be obtained by applying a concurrent chemoradiotherapy alone in advanced HNC. Various randomized trials have been investigated the efficacy of chemotherapy in locally advanced HNCs (LASCCHN). Chemotherapy has been used as induction treatment, concurrent with radiotherapy, or as adjuvant treatment after radiotherapy, surgery or both.[10],[11],[12],[13],[14],[15],[16]

The prognosis of patients with locally advanced squamous cell cancer of the head and neck is generally poor. Despite multimodality of treatment such as surgery and/or radical radiation therapy (RT), 50%–60% of patients recur within 2 years, and an additional 20%–30% of them develop distant metastasis.

Concurrent chemo-radiotherapy improves survival over RT and generally attributed to improved locoregional control. Induction chemotherapy (ICT) reduces metastasis incidences and cisplatin-based ICT and induces response rate of 80%–90%, with complete response rate (CR) rate to 20%–40% in LASCCHN.[17],[18],[19],[20]

Aims

To compare the efficacy and toxicity of ICT followed by CTRT versus standard CTRT alone in patients with LASCCHN. Primary end point is progression-free survival (PFS) and toxicity profile.

 > Materials and Methods 

This was a randomized, prospective study conducted at Acharya Tulsi Regional Cancer Treatment and Research Institute, Sardar Patel Medical College and associated group of hospitals, Bikaner.

Eligibility criteria

The study protocol included 100 patients of histologically proven previously untreated locally advanced squamous cell carcinoma of head and neck (LASCCHN) who were enrolled from January 2017 to September 2017.

Inclusion criteria

Age <70 yearsEastern Cooperative Oncology Group (ECOG) 0–2No previous history of malignancy oriented treatmentAdequate baseline haematological, cardiac, renal or liver functions tests.

Exclusion criteria

Distant metastasisRecurrent lesionsConcurrent malignanciesAssociated severe comorbiditiesHistory of previous treatment with any of the following modalities: Surgery, radiotherapy, and chemotherapyPregnant and lactating women.

The protocol was approved by hospital's institutional ethical committee, and all patients were properly informed and consented for the treatment study. Study design was intent to treat.

One hundred patients who fit the inclusion criteria were randomized into two arms of 50 each, by using the website (http:/www.randomisation.com). The arms were:

Arm A (CTRT alone)

A total 66Gy in 33fr (2Gy per fraction), administered daily (5 days per week) for 7 weeks (conventional fractionated radiotherapy) with 3 weekly inj. Cisplatin 100mg/m2 divided in two doses on D1, D22, and D43.

Arm B (ICT f/b CTRT)

Two cycles of induction chemotherapy each consisting of inj. Paclitaxel 175mg/m2 on day1, inj. Cisplatin 100mg/m2 divided in two doses on D1 and D2 and inj. 5FU 1gm/m2 on day 1 and 2; followed by 7 weeks of concurrent CTRT consist of standard RTOG regime with 3 weekly inj. Cisplatin 100 mg/m2 in two divided doses on D1, 22, 43 Plus RT by conventional fractionation.

Treatment volume was included primary tumor site plus neck node regions. Parallel opposed bilateral fields were planned. The dose was prescribed at midline. External-beam radiotherapy was given with RT parameter on cobalt-60 machines Theratron 780E/780C/Bhabhatron II with photon energies of 1.25MeV. Minimum treatment distance was ≥80 cm source to surface distance. Prophylactic granulocyte colony-stimulating factor (G-CSF) administration after 48 h of TPF chemotherapy cycle was implemented in the study. Prophylactic ciprofloxacin (500 mg PO bid) was given to TPF arm from days 6 to 12 after TPF chemotherapy cycle.

Patients were under monitoring after every course of chemotherapy and prior to and during radiotherapy. In each monitoring, patients were assessed for treatment response, control of symptoms, and any treatment-related morbidity by doing complete blood counts, biochemistry profile consisting of renal function test (RFT) and liver function test (LFT), ear, nose, throat (ENT) examination, chest X-ray, and ultrasonography (USG) abdomen. Toxicities including hematological, renal, biochemical, skin reactions, and disease response were assessed. After 6–8 weeks of completion of radiotherapy, patients were called for first follow-up visit and were assessed for treatment response and symptoms relief. Treatment response was assessed as per the RECIST criteria- Response Evaluation Criteria in Solid Tumors (V 1.1). Acute toxicities were assessed as per the RTOG/EORTC acute radiation morbidity scoring system. On first follow-up visit, complete general-physical examination, ENT examination, hemogram, RFT, RBS, and contrast-enhanced computed tomography head and neck were done for treatment response, and toxicity evaluation and metastatic workup were consist of chest X-ray, USG abdomen, and LFT. Statistical analysis was performed using the Chi-square test to compare tumor response and treatment-related toxicities between the study arm and control arm. P < 0.05 was considered statistically significant.

 > Results 

The baseline patients and tumor characteristics are described in [Table 1]. All characteristics were balanced. The treatment-related toxicities are described in [Table 2]. The treatment response on different follow-up visits is shown in [Table 3], [Table 4], [Table 5], [Table 6] to evaluate local control and PFS. The median follow-up was 18 months (6 months, 12 months, and 18 months).

Most of patients had ECOG performance status 1 and 2, median age 59 years, male gender, median weight 53 kg, and Stage III and IV in both arms. During the treatment, 2 and 4 patients lost from follow-up in Arm A and Arm B, respectively; while 1 patient expired after receiving two cycles of chemotherapy. A total of 48 and 45 patients were received CTRT in Arm A and Arm B, respectively. Sixteen patients showed >5% of weight loss during study; 7(14.6%) and 9(20%) patients from arm A and arm B respectively.

The follow-up was done after 6–8 weeks after completion of chemoradiotherapy, 18 and 24 patients had CR in study and control arm for any stage (X2 = 2.38, P = 0.126), which was insignificant. Although total 38 and 37 patients had regression (x2 = 0.14, P = 0.705), 7 and 5 patients had stable disease and 3 and 3 patients had progression of disease in Arm A and Arm B, respectively.

Toxicities

There was no Grade 4 hematological and nonhematological toxicities found in both arms. During the induction TPF, hematological toxicities in terms of anemia and neutropenia were higher in TPF arm. Grade 3 neuropathy was found only in two patients of TPF arm (4.4%). Stomatitis and skin reactions of Grade 3 were also higher in TPF arm. The symptoms relief was slightly better and earlier achieved in the control arm.

The subsequent follow-ups done at 3 months, 6 months, 12 months, and 18 months were done to evaluate PFS. Few patients were lost to follow-up at different visits. Although the patients those followed, 6 months' PFS was found 77% v/s 75.6% (P = 0.853), 12 months PFS was found 67.4% versus 66% (P = 0.126), and 18 months PFS was found 57% versus 55% (x2 = 0.039, P = 0.8414) in Arm A and Arm B, respectively.

Local control and PFS were calculated by using the Chi-square test. Differences in both arms were identified as statistically significant if P < 0.05.

 > Discussion 

Treatment of HNC is a multimodality approach, including surgery, chemotherapy, and radiotherapy according to the site and stage of the disease. More than 75% of HNC patients require RT, which can be given either alone or concurrently with chemotherapy.[21],[22] As per Delaney et al.'s study, RT was indicated at some point in 74% of all patients with head and neck carcinoma.

The purpose of this study was to verify the potential impact of ICT on treatment outcome, toxicity, and PFS in patients with locally advanced SCCHN. Our study showed 37.5% versus 53.3% CR rate and 79.1% versus 82.1% total response rate (CR + PR) (P = 0.705) at 6–8 weeks of treatment completion in CTRT versus ICT-CTRT arms respectively, which was similar to a study by Hitt et al.[17] Published in annals of Oncology 2014. The 18 months' PFS was found 57% versus 55% in Arm A and Arm B, respectively (x2 = 0.039, P = 0.8414), which is also similar to this above study.

No any patient showed Grade 4 toxicities. The most reported Grade 2–3 hematologic toxicities was anemia and neutropenia, and the most reported non hematological toxicities included stomatitis, skin reactions, dysphagia, and nausea and vomiting. The toxicities were significantly higher in ICT-CTRT arm, which is also similar to above discussed study.

Four patients in TPF arm were lost to follow-up as they got relief by ICT, so they did not turn up for subsequent CTRT.

The prevalence of human papilloma virus (HPV) association in oropharyngeal cancers is roughly 25%. HPV status, which is a prognostic factor in HNCs, was unknown in our study and could be a confounding factor.

The expected higher proportion of febrile neutropenia in Arm B (ICT-CTRT) was controlled with prophylactic G-CSF. The toxicity-related deaths were zero in both arms.

 > Conclusion 

The present study represents the cohort of locally advanced head and neck cancer treated with induction CT and CTRT in single institute. The results of this study are matched with some previous studies cited in the literature. On basis of our findings, this study conclude that addition of induction TPF chemotherapy before concurrent CTRT in unresectable LASCCHN has failed to show any significant advantage in terms of CR rates, toxicity profiles, and PFS.

Acknowledgments

The authors would like to thank the doctors and support staff of the Department of Radiation Oncology, Acharya Tulsi Regional Cancer Treatment and Research Institute, Bikaner, Rajasthan, India.

Financial support and sponsorship

Nil

Conflicts of interest

There are no conflicts of interest.

 

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  [Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6]