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Key predictors of prolonged overall treatment time in head and neck cancer radiotherapy

Published online by Cambridge University Press:  28 August 2025

Piyapasara Toapichattrakul Open the ORCID record for Piyapasara Toapichattrakul [Opens in a new window] ,
Pooriwat Muangwong Open the ORCID record for Pooriwat Muangwong [Opens in a new window] ,
Jiraporn Khorana Open the ORCID record for Jiraporn Khorana [Opens in a new window]  and
Imjai Chitapanarux Open the ORCID record for Imjai Chitapanarux [Opens in a new window]
Piyapasara Toapichattrakul
Affiliation:
Division of Radiation Oncology, Department of Radiology, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand
Pooriwat Muangwong
Affiliation:
Division of Radiation Oncology, Department of Radiology, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand
Jiraporn Khorana
Affiliation:
Division of Pediatric Surgery, Department of Surgery, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand Department of Biomedical Informatics and Clinical Epidemiology, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand Clinical Surgical Research Center, Department of Surgery, Faculty of Medicine, Chiang Mai University, Chiang Mai 50200, Thailand
Imjai Chitapanarux*
Affiliation:
Division of Radiation Oncology, Department of Radiology, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand
*
Corresponding author: Imjai Chitapanarux; Emails: imjai@hotmail.com/imjai.chitapanarux@cmu.ac.th
Rights & Permissions [Opens in a new window]

Abstract

Introduction:

Prolonged overall treatment time (OTT) in radiotherapy (RT) for head and neck cancer (HNC), particularly beyond 49 days, has been linked to poorer tumour control and survival, primarily due to accelerated tumour repopulation. Identifying modifiable factors contributing to treatment delays may help improve outcomes. This study aimed to evaluate the association between pre-treatment clinical, nutritional and inflammatory factors and prolonged OTT.

Methods:

We retrospectively analysed patients with non-metastatic HNC treated with definitive or postoperative RT (with or without chemotherapy) between 2020 and 2022. Pre-treatment factors included Eastern Cooperative Oncology Group (ECOG) performance status, tumour stage, treatment modality, body mass index (BMI), weight loss, sarcopenia (via C3 computed tomography imaging), neutrophil-to-lymphocyte ratio (NLR) and absolute lymphocyte count. Logistic regression was used to identify predictors of prolonged OTT (> 49 days).

Results:

Among 465 patients, 287 (61·7%) experienced prolonged OTT. Multivariable analysis identified ECOG status (OR 1·42, p = 0·004), significant weight loss > 5% (OR 1·26, p = 0·036), concurrent chemotherapy (OR 1·96, p = 0·005), NLR (OR 1·03, p = 0·041) and sarcopenia (OR 1·18, p = 0·042) as independent predictors. Patient-related delays accounted for 53·3% of OTT prolongation, while public holidays contributed to 42·5%.

Conclusions:

Several modifiable pre-treatment factors—including poor performance status, pre-treatment weight loss, sarcopenia and systemic inflammation—were independently associated with OTT prolongation. These findings provide evidence to support early, patient-tailored interventions such as prehabilitation and intensive nutritional counselling before and during RT. In addition, system-level strategies, including staffing adjustments and compensatory scheduling during public holidays, may further reduce avoidable treatment delays and enhance care delivery.

Keywords

Factorhead and neck canceroverall treatment timeradiotherapy

Information

Type
Original Article
Information
Journal of Radiotherapy in Practice , Volume 24 , 2025 , e37
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Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press

Introduction

Head and neck cancer (HNC) is the seventh most common cancer globally and remains among the top five cancers in Thailand. Reference Tangjaturonrasme, Vatanasapt and Bychkov1 Radiotherapy (RT) is a key treatment modality and can be delivered in radical, postoperative or palliative settings. 2 For curative intent, RT typically requires 5–7 weeks to complete the full prescribed dose. However, treatment-related toxicities frequently lead to unplanned interruptions. Reference Giddings3 These interruptions have been shown to adversely affect treatment outcomes.

From a radiobiological perspective, prolonged overall treatment time (OTT) compromises tumour control through accelerated repopulation of surviving clonogenic cells, typically beginning after the fourth week of RT. In HNC, where tumour cells can double within 4–5 days, treatment interruption allows these clonogens to rapidly repopulate. Reference Withers, Taylor and Maciejewski4 Recent studies have further reinforced this concept, demonstrating that accelerated repopulation contributes to poorer clinical outcomes, including reduced local control, progression-free survival and overall survival. Reference Yao, Jin and Wang5Reference Cannon, Geye and Hartig8 This effect is especially pronounced in nasopharyngeal carcinoma (NPC), where OTT exceeding 49–70 days has been shown to significantly impact survival. Reference Yao, Jin and Wang5,Reference Sekarutami, Gondhowiardjo and Yuliasti9 In our setting, particularly in Thailand, such prolongation is less often caused by the pre-treatment logistical delays or waiting time and more commonly results from unplanned interruptions occurring after RT has already commenced.

One factor contributing to treatment interruption is cancer cachexia, which is highly prevalent among HNC patients. Reference Cederholm, Jensen and Correia10 Simple and accessible indicators—such as BMI (using WHO cut-offs for Asians), significant weight loss (> 5% within three months) and pre-treatment weight—can offer useful insights into a patient’s nutritional status and their ability to tolerate intensive therapy. Reference Cederholm, Jensen and Correia1015 Sarcopenia, in particular, has emerged as a key factor associated with treatment tolerance. Reference Wendrich, Swartz and Bril16,Reference Bentahila, Giraud and Decazes17 Although traditionally assessed using dual-energy X-ray absorptiometry or whole-body imaging, cross-sectional imaging from RT planning computed tomography (CT) scans can provide practical alternatives. While the skeletal muscle index (SMI) at the L3 level is the standard reference, the cross-sectional area (CSA) at the C3 level—routinely captured in HNC simulation scans—has shown strong correlation with L3-SMI and is increasingly used in clinical practice. Reference Zwart, van der Hoorn and van Ooijen18Reference Swartz, Pothen and Wegner21

In addition, systemic inflammatory markers such as the neutrophil-to-lymphocyte ratio (NLR) and absolute lymphocyte count (ALC), which are easily obtained from routine blood tests, reflect the interplay between systemic inflammation and immune status. Although both NLR and ALC have been associated with prognosis in HNC—including overall survival and disease progression Reference Yang, Zhao and Liang22Reference Du, Ni and Jiang24 —their role in predicting treatment interruptions or prolonged OTT has not been clearly established and remains an area of interest.

Although these pre-RT clinical parameters—BMI, weight loss, inflammatory markers and sarcopenia—are routinely collected in RT centres, their predictive value for prolonged OTT remains uncertain. This study aims to evaluate whether these simple and widely available pre-treatment factors are associated with prolonged OTT in HNC patients. In addition to these biological and nutritional indicators, patient-related (e.g., age, performance status) and disease-related factors (e.g., tumour staging, treatment modality and concurrent chemotherapy) may also contribute to treatment prolongation. Identifying which of these factors are significantly associated with prolonged OTT, particularly those that are modifiable, may support timely interventions such as intensive dietary counselling or prehabilitation to prevent treatment interruption and improve adherence and outcomes. Reference Talwar, Donnelly and Skelly25

Materials and Methods

Study design, population and participant recruitment

This retrospective cohort study was conducted at the Faculty of Medicine, Chiang Mai University, to evaluate patients diagnosed with HNC who underwent RT between 2020 and 2022. Eligible patients (aged ≥ 18 years) with histologically confirmed squamous cell carcinoma were included, while those with recurrent or metastatic disease were excluded. Additionally, patients who did not undergo CT simulation for RT planning were excluded.

Treatment protocol

All patients received treatment based on a multidisciplinary tumour board decision. For NPC, radical RT was prescribed at a dose of 70 Gy in 33–35 fractions. Induction chemotherapy, with or without concurrent platinum-based chemotherapy, was administered based on clinical indications. For non-NPC, patients received either postoperative RT (60–70 Gy in 30–35 fractions) or definitive RT (70 Gy in 33–35 fractions), with or without chemotherapy as indicated. All patients were treated with either three-dimensional conformal RT or intensity-modulated RT.

Data collection

Pre-treatment factors were collected from electronic medical records prior to the first fraction of RT. These included age, sex, height, weight, primary tumour site, stage, Eastern Cooperative Oncology Group (ECOG) performance status, treatment modality and complete blood count results. ECOG performance status was assessed using the standard ECOG 0–5 scale. Reference Oken, Creech and Tormey26 We calculated the NLR as an inflammatory status marker and the ALC as an immune status marker. NLR was determined by dividing the neutrophil count by the lymphocyte count (cells/µL), while ALC was calculated by multiplying the white blood cell count by 1000 and the percentage of lymphocytes. Reference Homkham, Muangwong and Pisprasert27

In this study, we assessed nutritional status using BMI, significant weight loss and sarcopenia status. BMI was calculated using the formula: weight (kg)/height2 (m2). Significant weight loss was assessed by reviewing medical records for the patient’s weight 3 months before the start of RT and defined as a weight loss of more than 5% within this period Reference Gioulbasanis, Baracos and Giannousi28 . Sarcopenia status was evaluated by using CT simulation CSA at the C3 vertebral level. The CSA was contoured by a radiation oncologist using a fixed Hounsfield unit range of –29 to 150, encompassing the sternocleidomastoid and paravertebral muscles. If a patient had a gross invasion of one sternocleidomastoid muscle, the measurement was duplicated from the contralateral side. However, if the paravertebral muscles were invaded, CSA assessment could not be performed. After contouring, the CSA at C3 was converted into the CSA at L3 and SMI using a specific equation described by Swatz et al. Reference Swartz, Pothen and Wegner21 The cut-off value of SMI for diagnosing sarcopenia was set at 43·2 cm2/m2. Reference Wendrich, Swartz and Bril16,Reference Chargi, Bril, Emmelot-Vonk and de Bree29

$$\begin{align} CSA\;at\;L3( {c{m^2}}) = & 27.304 + 1.363 \times CSA\;at\;C3\left( {c{m^2}} \right) - 0.671 \\& \times Age + 0.640 \times weight\left( {kg} \right) + 26.442 \times Sex\end{align}$$
$$SMI\left( {c{m^2}/{m^2}} \right) = CSAat\;L3\;\left( {c{m^2}} \right)/height\;\left( {{m^2}} \right)\;$$

Overall treatment time was defined as the number of days from the start to the completion of RT. Patients who did not complete RT as scheduled were classified as having a prolonged OTT. The cut-off for OTT was set at 49 days or more, based on studies on NPC. Reference Yao, Jin and Wang5

Data analysis

Statistical analyses were conducted using Stata version 16. Patient characteristics were analysed based on data type. Continuous variables were evaluated using either the t-test or the rank-sum test, while categorical variables were assessed using Fisher’s exact test. A two-tailed p-value of < 0·05 was considered statistically significant. To address missing laboratory data and enhance accuracy, predictive capability and statistical power, we employed multiple imputation using the chained equations (MICE) method. Missing values were estimated via predictive mean matching, incorporating diagnosis and patient demographic factors (age, sex, OTT, concurrent chemotherapy and treatment modality) as independent variables. This process generated 20 imputed datasets, which were compared with the original datasets to ensure consistency and reliability. Following imputation, logistic regression coefficients were combined across the 20 datasets using Rubin’s rules to calculate odds ratios. Univariable and multivariable analyses were performed to evaluate associations between clinical factors and outcomes, with standard errors clustered by primary diagnosis (NPC vs. non-NPC).

Study size consideration

A retrospective chart review was conducted, and 30 cases were initially contoured as a pilot study to assess five preselected candidate predictors: ECOG performance status, BMI, NLR, staging, concurrent chemotherapy and sarcopenia. The incidence of prolonged OTT was estimated at 50%, resulting in a 1:1 group distribution. The required sample size was calculated based on either proportion or mean (standard deviation), using an alpha level of 0·05 and 80% power. Given the available data, a minimum of 354 cases were collected.

Results

Of the 465 patients enrolled in the study, 178 (38·3%) completed RT within 49 days (non-prolonged OTT), while 287 (61·7%) experienced delays or incomplete treatment (prolonged OTT), as illustrated in Figure 1, the STROBE (Strengthening the Reporting of Observational Studies in Epidemiology) flowchart of this study. Table 1 shows that there were no significant differences in age, sex or ECOG status between the two groups. However, the prolonged OTT group had a lower median weight (50 kg vs. 52 kg, p = 0·010) and BMI (19·39 kg/m2 vs. 20·33 kg/m2, p = 0·015). A higher proportion of patients in the prolonged OTT group were underweight (41·3% vs. 30·6%), though this difference was not statistically significant (p = 0·070). In terms of disease characteristics, there were no differences in cancer type distribution, but advanced-stage disease (stage III–IV) was more frequent in the prolonged OTT group (90·9% vs. 78·1%, p < 0·001). Treatment modalities were similar between the groups, but a higher percentage of patients in the prolonged OTT group received concurrent chemotherapy (80·1% vs. 64·0%, p < 0·001).

Figure 1. STROBE flow chart.

Table 1. Baseline characteristics of the overall cohort

Abbreviations: ALC, absolute lymphocyte count; BMI, body mass index (kg/m2); ECOG, Eastern Cooperative Oncology Group; IQR, interquartile range; kg, kilograms; NLR, neutrophil-to-lymphocyte ratio; NPC, nasopharyngeal carcinoma; RT, radiotherapy; SD, standard deviation.

* Statistically significant (p-value <0.05).

a BMI classification according to the WHO criteria for Asian populations.

b Significant weight loss is defined as a weight loss of more than 5% in the past 3 months.

c Sarcopenia status was determined by converting C3 measurements to the skeletal muscle index (SMI), with a cut-off value of 43·2 cm2/m2 for defining sarcopenia.

Univariable and multivariable analysis

Univariable analysis (Table 2) identified significant associations with prolonged OTT: ECOG status (OR 1·27, p = 0·001), underweight (OR 1·65, p = 0·045), advanced stage (OR 2·81, p = 0·048), concurrent chemotherapy (OR 2·27, p < 0·001), NLR (OR 1·04, p = 0·013), ALC (OR 0·99, p = 0·025), sarcopenia (OR 1·19, p = 0·036) and postoperative treatment (OR 1·28, p = 0·010). Age, sex and weight loss were non-significant. Multivariable analysis confirmed independent predictors: ECOG status (OR 1·42, p = 0·004), weight loss (OR 1·26, p = 0·036), concurrent chemotherapy (OR 1·96, p = 0·005), NLR (OR 1·03, p = 0·041) and sarcopenia (OR 1·18, p = 0·042).

Table 2. Factors significantly associated with prolonged overall treatment time, clustered by primary cancer site (NPC vs. non-NPC)

Abbreviations: 95% CI, 95% confidence interval; ALC, absolute lymphocyte count; ECOG, Eastern Cooperative Oncology Group; NLR, neutrophil-to-lymphocyte ratio; NPC, nasopharyngeal carcinoma; OR, odds ratio; RT, radiotherapy.

* Statistically significant (p-value <0.05).

a Significant weight loss is defined as a weight loss of more than 5% in the past 3 months.

b BMI classification according to the WHO criteria for Asian populations.

c Sarcopenia status was determined by converting C3 measurements to the skeletal muscle index (SMI), with a cut-off value of 43·2 cm2/m2 for defining sarcopenia.

Among the 287 patients who experienced prolonged RT treatment, the most common causes of delay were patient-related factors (53·3%), which included severe acute toxicity (grade ≥ 3), fatigue and the need for re-planning due to anatomical changes. Public holidays accounted for 42·5% of delays, while COVID-19 infection or risk of exposure contributed to 3·1%. Only 1·0% of delays were related to machine malfunction (Table 3).

Table 3. Causes of radiotherapy prolongation (n = 287 patients)

Discussion

Prolonged OTT has long been recognized as a critical factor influencing treatment outcomes in HNC RT. In our cohort, only 38·3% of patients completed RT within the recommended 49-day period, which is markedly lower than previously reported rates. Reference Hua, Ou-Yang and Zou7 We found that 53·3% of the delays were attributable to patient-related factors, followed by 42·5% due to public holidays. In contrast, COVID-19-related disruptions and machine malfunctions were infrequent. While some delays may reflect systemic issues, such as scheduling around holidays, a substantial proportion stemmed from patient-level challenges—many of which may be modifiable. These findings underscore the importance of identifying contributing factors early, with the goal of minimizing treatment interruptions and preserving the therapeutic benefit of RT.

Among disease-related factors, concurrent chemoradiotherapy was independently associated with prolonged OTT, likely due to its known toxicity burden. Reference Ghosh-Laskar, Kalyani and Gupta30,Reference Van den Bosch, van der Schaaf and van der Laan31 While it remains standard for curative treatment in locally advanced HNC, this finding highlights the importance of early supportive intervention in vulnerable patients. ECOG performance status also showed a significant association with treatment delay. Notably, even a small shift from ECOG 0 to 1, indicating only mild restriction in physically strenuous activity, was associated with a 1·5-fold increase in the risk of prolonged OTT. In clinical settings, differentiating between ECOG scores can be subjective, yet this finding highlights that even subtle reductions in functional capacity may meaningfully impact treatment continuity. Functional status, however, may be improved with interventions such as prehabilitation or symptom management.

Systemic inflammation and nutritional status also showed meaningful associations with treatment duration. Pre-treatment NLR was an independent predictor of prolonged OTT, suggesting that elevated baseline inflammation may impair treatment tolerance. Although ALC was not significant in multivariable analysis, it remains a relevant marker of immune competence and has been previously linked to survival outcomes in HNC. Reference Yang, Zhao and Liang22,Reference Cho, Kim and Yoon23,Reference Panje, Riesterer and Glanzmann32Reference Price, Mistry and Betts34 Regarding nutrition, both significant weight loss (> 5% within 3 months prior to RT) and CT-defined sarcopenia were independently associated with treatment prolongation. We assessed muscle mass using CSA at the C3 vertebral level, a validated surrogate for L3 skeletal muscle index in HNC patients. Despite variation in diagnostic cut-offs, sarcopenia has consistently been associated with impaired treatment adherence and survival. Reference Kasahara, Kono and Sato35,Reference Kasahara, Shigetomi and Sato36 Together, these findings underscore the interconnected roles of inflammation, malnutrition and physical deconditioning—all of which are potentially modifiable through early interventions.

Multimodal prehabilitation, incorporating physical exercise, nutritional support and psychosocial interventions, has been proposed as a comprehensive approach to improve treatment tolerance in HNC. Reference Harris and Marignol37,Reference De Pasquale, Mancin and Matteucci38 Structured programmes that combine aerobic, resistance and flexibility training have shown potential benefits in preserving skeletal muscle mass and function. Reference Lin, Cheng and Yen39 Immune-enhancing nutrition, as well as intensive nutritional counselling by dietitians, has been associated with improved adherence and attenuated rises in inflammatory markers such as the NLR during RT. Reference Homkham, Muangwong and Pisprasert27,Reference Britton, Baker and Wolfenden40 Although fully integrated multimodal prehabilitation remains in the feasibility-testing phase, initial findings suggest it may offer synergistic benefits across physical, nutritional and psychological domains. Reference Groen, de Vries and Mulder41 Further prospective trials are warranted to confirm its clinical impact.

At the system level, public holidays falling on weekdays accounted for a substantial proportion of delays. Addressing this issue may involve scheduling staff coverage or applying altered fractionation in cases where continuity is disrupted. Even short unplanned treatment gaps, particularly those occurring after the onset of accelerated repopulation, may warrant compensatory dosing of approximately 0·8 Gy per missed day to maintain tumour control, as recommended in recent radiobiological guidelines. Reference Mirestean, Zara and Iancu42

This study has several limitations. First, its retrospective design may introduce selection bias and limit causal inference. Second, although we included a range of pre-treatment variables, unmeasured confounding factors—such as comorbidities, socio-economic status and patient motivation—could influence treatment adherence. Third, the use of ECOG performance status and sarcopenia cut-offs may be subject to inter-observer variability and population-specific differences. Lastly, as this was a single-centre study, the generalizability of our findings may be limited. Further validation in multi-institutional cohorts and prospective settings is warranted.

In conclusion, prolonged OTT remains a critical issue in head and neck RT. This study identifies several modifiable pre-treatment factors—including poor performance status, systemic inflammation, weight loss and sarcopenia—that are independently associated with treatment delay. These findings support integrating early nutritional and functional interventions into routine care. In parallel, system-level strategies such as improving scheduling around public holidays may help reduce avoidable interruptions and improve treatment outcomes.

Acknowledgements

We sincerely thank all the staff in the Division of Radiation Oncology and the Department of Biomedical Informatics and Clinical Epidemiology for their invaluable contributions to this study. Their expertise, dedication and support were essential to the completion of this research.

Financial support

This work was supported by the Faculty of Medicine, Chiang Mai University (Grant Number 36–67).

Competing interests

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Ethical consideration

The study protocol was reviewed and approved by the Faculty of Medicine, Chiang Mai University Institutional Review Board (EXP-2566–0172–000300) in accordance with the Declaration of Helsinki. The requirement for informed consent was waived due to the retrospective analysis of anonymized clinical data, with all patient information handled.

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Figure 0

Figure 1. STROBE flow chart.

Figure 1

Table 1. Baseline characteristics of the overall cohort

Figure 2

Table 2. Factors significantly associated with prolonged overall treatment time, clustered by primary cancer site (NPC vs. non-NPC)

Figure 3

Table 3. Causes of radiotherapy prolongation (n = 287 patients)