The aim of the study was to examine the following: (a) the trajectory of external and internal head and neck lymphoedema (HNL) in patients with head and neck cancer (HNC) up to 12 months post-chemoradiotherapy (CRT) and (b) the relationship between HNL and swallowing function. Using a prospective longitudinal cohort study, external/internal HNL and swallowing were examined in 33 participants at 3, 6 and 12 months post-CRT. External HNL was assessed using the Assessment of Lymphoedema of the Head and Neck and the MD Anderson Cancer Centre Lymphoedema Rating Scale. Internal HNL was rated using Patterson’s Radiotherapy Oedema Rating Scale. Swallowing was assessed via clinical, instrumental and patient-reported measures. Associations between HNL and swallowing were examined using multivariable regression models. External HNL was prevalent at 3 months (71%), improved by 6 months (58%) and largely resolved by 12 months (10%). In contrast, moderate/severe internal HNL was prevalent at 3 months (96%), 6 months (84%) and at 12 months (65%). More severe penetration/aspiration and increased diet modification were associated with higher severities of external HNL (p=0.006 and p=0.031, respectively) and internal HNL (p<0.001 and p=0.007, respectively), and more diffuse internal HNL (p=0.043 and p=0.001, respectively). Worse patient-reported swallowing outcomes were associated with a higher severity of external HNL (p=0.001) and more diffuse internal HNL (p=0.002). External HNL largely resolves by 12 months post-CRT, but internal HNL persists. Patients with a higher severity of external and/or internal HNL and those with more diffuse internal HNL can be expected to have more severe dysphagia.
Hinweise
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Introduction
The use of chemoradiotherapy (CRT) treatment regimens have become increasingly used in the treatment of patients with locally advanced head and neck cancer (HNC) [1]. The addition of concurrent chemotherapy, along with enhanced radiotherapy delivery techniques and tumour-related factors have led to improved tumour response and survival rates in patients with HNC [2]. However, despite better management of disease, those treated with CRT continue to experience significant acute and chronic side effects [3, 4], which can be both functionally and psychologically debilitating for those in the survivorship phase of care [5].
Head and neck lymphoedema (HNL) is highly prevalent following HNC treatment [6] and develops when lymph fails to drain through the lymphatic vessels and/or when the lymphatic load exceeds the transport capacity of the lymphatic system [7, 8]. Up to 90% of patients with HNC may be affected by some form of HNL [6] which can develop externally on the soft tissues of the face and neck, internally within the oral cavity, pharynx or larynx, or as a combination of both [9]. The development of HNL has historically been attributed to surgical treatments, including the removal of lymphatic structures, vessels and nodes. However, the presence of significant tumour bulk and management via non-surgical treatment options, such as high-dose radiotherapy and concurrent chemotherapy, may also damage the lymphatic structures and disrupt the normal flow of lymph fluid [10, 11].
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It has been shown that patients are less likely to experience HNL with increasing time post-treatment [11]. This notion is consistent with the anecdotal view that HNL will eventually resolve with conservative management. However, recent studies have shown that HNL may not completely resolve [6, 12]. Ridner et al. [6] prospectively examined 83 HNC patients who had undergone some form of multimodal treatment and found that HNL was most prevalent 3 months post-treatment, with 90% of the cohort experiencing external HNL and 86% internal HNL. The severity of both external and internal HNL appeared to gradually improve from 12 to 18 months. However, 82% and 80% still had some degree of external and internal HNL at the completion of the study. Tribius et al. [12] reported similar results in a longitudinal study of 280 HNC patients who had also undergone surgery and postoperative radiotherapy (+/− chemotherapy). In their cohort, 80% had some degree of external and/or internal HNL at 3 months post-treatment, and 38% continued to have some degree of HNL at the end of the observation period (time varies).
The high prevalence of HNL in patients following HNC treatment is concerning as HNL has been associated with a wide range of physical, functional and psychological issues [13‐17]. In particular, patients who have more severe external and internal HNL have been shown to experience increasing dysphagia [13, 16‐19] and have more severe laryngeal penetration and/or aspiration, experience more pharyngeal residue, require increased diet modification and have more self-reported symptom burden in relation to eating solid foods [13, 16‐19]. However, the relationship between HNL and dysphagia has only been examined in cross-sectional samples with heterogeneous populations, and it is unclear if the relationship remains at different time points post-treatment. The primary aim of this study was therefore to explore the trajectory of external and internal HNL in patients with HNC who have been treated with CRT and describe the changes in HNL location and severity over a 12-month period. It also aimed to explore the relationship between external and internal HNL and the presence of dysphagia, including penetration–aspiration status, functional diet status and patient-reported swallowing outcomes during this time period.
Material and Methods
A longitudinal cohort study design was used. It forms part of a larger study that has been described in further detail elsewhere [16]. Ethics approval was obtained from Hunter New England Human Research Ethics Committee (15/02/18/4.07), University of Queensland Medical Research Ethics Committee (2015000362) and Calvary Mater Newcastle Research Governance Unit (SSA/15/HNE/45).
Participants
Participants were prospectively recruited from the Radiation Oncology Clinic at the Calvary Mater Hospital Newcastle, Australia, using a convenience sampling strategy. Recruitment occurred from September 2015 to July 2018, and follow-up continued until November 2019. Eligibility criteria included the following: (1) new diagnosis of oral, nasopharyngeal, oropharyngeal, laryngeal or hypopharyngeal cancer; and (2) planned to receive curative CRT. Exclusion criteria included the following: (1) treated with palliative intent; (2) recurrent or metastatic disease; (3) pre-existing comorbidity conditions that may result in HNL (e.g. trauma), or impact swallowing, voice or speech function (e.g. neurological injury or insult); or (4) unable to provide informed consent.
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Procedure
Measures were collected at 3, 6 and 12 months post-treatment. A chart review was undertaken for each participant prior to each time point to ensure ongoing disease-free status. External HNL, internal HNL and swallowing were assessed at each time point.
Assessment of Head and Neck Lymphoedema
External HNL was assessed with two assessments. It was primary graded with the MD Anderson Cancer Centre (MDACC) Lymphoedema Rating Scale [8] which uses 5 points to capture HNL across the continuum of soft swelling to fibrosis. For the purposes of this study, 0 was classified as normal, 1a mild, 1b moderate, 2 severe and 3 profound external HNL. The secondary assessment included the Assessment of Lymphoedema of the Head and Neck (ALOHA) [20] which utilises surface tape measurements and the tissue dielectric constant (TDC) measured with a MoisureMeterD (MMD; Delfin Technologies Ltd, Kuopio, Finland). The participant's weight is also recorded. The standardised setup positioning protocol was applied and tape measurements were taken at the lower neck circumference, upper neck circumference and length from ear to ear. For the TDC measure, the 2.5-mm MMD probe was placed on the skin surface 8 cm below the lower lip edge (3 measurements taken). Both the ALOHA tape measurement system and TDC measure have demonstrated strong inter-rater reliability [21]. Normative values for the TDC [22] were also used as reference data. It was routine clinical care to refer patients onto the physiotherapy department for further assessment and management when external HNL was identified.
Internal HNL was assessed via transnasal laryngoscopy. The presence, location and severity of internal HNL was rated with Patterson’s Radiotherapy Oedema Rating Scale [23] (scale recently revised [24]). This scale includes 13 laryngopharyngeal sites and ratings of normal, mild, moderate or severe are available to rate each site. The scale has shown moderate agreement for inter-rater reliability and very good agreement for intra-rater reliability [23]. To further assist with rating determinations, an education package was developed which included images of HNL at different severity levels and at each site. Twenty percent of the total recordings were re-rated by the primary investigator at least 3 months after the initial rating, and a second speech pathologist to assess intra- and inter-rater reliability.
In addition to the 13 site ratings, three internal HNL summary variables were also generated: (1) a ‘maximum severity score’ which reflected the maximum severity rating obtained across the 13 internal sites; (2) a ‘sum severity score’ which was generated by allocating each severity rating a score (i.e. normal = 0, mild = 1, moderate = 2, severe = 3) and adding the scores across the 13 internal sites; and (3) the ‘number of internal sites affected by HNL’ was generated by counting the number of internal sites identified as having HNL (three severity variations—any severity; moderate or severe; or severe). The ‘maximum severity score’ and ‘number of internal sites affected by HNL’ have previously been used in the literature [6, 9, 16, 18]. The ‘sum severity score’ was novel.
Assessment of Swallowing
The swallowing assessment included clinical, instrumental and patient-reported outcome measures. The Mann Assessment of Swallowing Ability—Cancer (MASA-C) [25] was used to grade oral musculature, cranial nerve and clinical swallowing ability. It has a maximum score of 200 which indicates swallowing within normal limits, whilst a score of 185 or less indicates the presence of dysphagia [25]. The Functional Oral Intake Scale (FOIS) [26] was used to grade functional diet status. The FOIS classifies diet status as non-oral (scores 1–3) or oral (scores 4–7) and considers the number of diet consistencies tolerated, and the need for special preparations or compensations.
For instrumental assessment, a fiberoptic endoscopic evaluation of swallowing (FEES) was performed. Participants’ swallowed two mouthfuls of blue dyed water, the size of which were self-determined, and the Penetration–Aspiration Scale (PAS) [27] was used to grade laryngeal penetration and aspiration events on the worse of the two swallows. PAS scores of 1–2, indicating that material does not enter the airway or material enters the airway, remains above the true vocal folds and is ejected, were considered normal. Scores of 3–8 were considered dysfunctional [28]. Twenty percent of the total FEES recordings were re-rated as per the reliability protocol described above.
Finally, the Vanderbilt Head and Neck Symptom Survey (VHNSS) (v2.0) Plus General Symptom Scale [29] was used to examine self-perceived symptom burden in relation to swallowing ability and nutritional status. It was given to participants to independently complete and return. VHNSS questions use a Likert scale where a score of 0 indicates no symptoms and 10 indicates severe symptoms. Consistent with prior research [29], questions from four symptom subscales, the swallow general (questions 5–13), swallow solids (questions 5, 7, 8 and 10), swallow liquids (questions 6 and 9) and nutrition (questions 1–4), were summed and then collapsed and classified as mild (scores 1–3), moderate (scores 4–6) and severe (7–10).
At the study centre, it was routine clinical care for all participants to receive regular speech pathology assessment and management for their swallowing, voice and speech function throughout their CRT, and up to 3 months post-treatment. After this time, review was only provided on an as-needed basis.
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Statistical Methods
Analyses were conducted by the primary investigator (CJ) and study statistician (MB) using the statistical software package Stata 16 [30]. Cohen’s kappa coefficient was used to assess the intra- and inter-rater reliability of the Patterson Radiotherapy Oedema Rating Scale and PAS ratings, which were observed via the transnasal laryngoscopy and FEES assessments (20% subsample). Linear weights (Kw) were applied [31] and the strength of agreement was classified as slight (Kw 0–0.20), fair (Kw 0.21–0.40), moderate (Kw 0.41–0.60), substantial (Kw 0.61–0.80) and almost perfect (Kw 0.81–1) [32].
Paired t-tests were used to examine the changes in continuous variables between time points (i.e. 3 vs. 6 months and 6 vs. 12 months). Wilcoxon signed-rank test was used to examine the changes in categorical variables between time points. Linear regression models were used to examine the associations between time points in the ALOHA tape measurement system and changes in weight. Shapiro–Wilk was used to assess the normality of residuals.
Regression models were used to examine associations between the swallowing and the HNL variables. A model was fitted for each HNL and swallowing variable (i.e. 6 × 17 models—all reported in Table 1). Linear regression models were used to examine the relationships between the HNL variables (explanatory) and the FOIS, MASA-C and VHNSS subscale scores (response). Logistic regression models were used to examine the relationships between the HNL variables (explanatory) and PAS scores (response), since 56% of the total observations (n = 48/86) had a normal PAS score (i.e. scores 1–2). Backwards stepwise methodology was employed during the fitting of these models to account for possible effects of other variables, such as age, tumour and nodal stage, and external HNL treatment. Data from the 3, 6 and 12 month time points were merged to create one main dataset (i.e. 86 observations on 33 participants). This was undertaken due to the small sample size at each time point and the low variability of the HNL and swallowing outcomes (i.e. most outcomes were tightly clustered around the mean). Clustered standard errors were used in the models, since more than one observation was made on each participant and this accounted for the time point variable [33]. Significance was set at p < 0.05.
Table 1
Relationships between swallowing outcomes and HNL via regression modelling
Response variables (possible range)
PAS (1–2 vs. 3–8)a
FOIS (1–7)b
MASA-C (40–200)2
VHNSS solids (0–50)2
VHNSS liquids (0–20)2
VHNSS nutrition (0–40)2
Explanatory variables
Odds ratio
p
β
p
β
p
β
p
β
p
β
p
External HNLc
3.5
<0.01
− 0.7
0.04
− 9.4
<0.01
4.5
<0.01
1.8
0.04
3.7
0.05
Max internal HNL
5.2
<0.01
− 0.4
0.01
− 5.6
<0.01
2.1
0.19
− 0.3
0.44
0.4
0.76
Sum internal HNL
1.2
<0.01
− 0.1
0.01
− 0.7
<0.01
0.4
0.02
0.0
0.46
0.1
0.35
Number of internal sites
1.6
0.04
− 0.2
<0.01
− 1.7
<0.01
1.1
<0.01
0.3
0.04
0.7
0.03
Individual internal sites
Base of tongue
1.2
0.57
0
0.95
− 1.5
0.27
− 1.0
0.41
− 0.3
0.17
0.2
0.86
Posterior pharyngeal wall
2.1
0.07
− 0.2
0.24
− 2.4
0.12
1.2
0.43
− 0.6
0.15
− 0.5
0.70
Epiglottis
2.5
<0.01
− 0.3
0.10
− 3.6
0.02
2.3
0.07
− 0.3
0.53
− 0.2
0.87
Pharyngoepiglottic folds
2.4
<0.01
− 0.4
0.02
− 4.5
0.01
2.5
0.02
0.1
0.87
0.7
0.49
Aryepiglottic folds
4.3
<0.01
− 0.6
<0.01
− 6.6
<0.01
3.0
0.02
0.5
0.22
1.7
0.12
Interarytenoid space
2.3
0.01
− 0.5
0.01
− 5.5
0.01
3.1
0.01
0.5
0.22
1.2
0.18
Cricopharyngeal prominence
3.3
<0.01
− 0.5
0.01
− 5.9
<0.01
3.4
<0.01
0.6
0.09
1.5
0.14
Arytenoids
3.4
<0.01
− 0.4
0.03
− 5.2
0.01
3.4
0.01
0.6
0.12
1.6
0.25
False vocal folds
2.3
0.05
− 0.3
0.09
− 4.9
0.01
2.8
0.02
0.5
0.12
1.2
0.34
True vocal folds
1.9
0.33
− 0.8
0.28
− 13
0.18
4.1
0.61
4.0
0.28
− 3.6
0.49
Anterior commissure
2.8
−
−
0.52
− 3.5
0.10
0.2
0.86
0.3
0.56
− 0.1
0.96
Valleculae
1.8
0.14
− 0.2
0.15
− 3.1
0.02
− 0.5
0.62
− 0.5
0.16
0.7
0.45
Pyriform sinus
3.9
<0.01
− 0.5
0.01
− 5.8
<0.01
3.2
<0.01
0.4
0.29
0.7
0.41
PAS penetration-aspiration scale, FOIS functional oral intake scale, MASA-C mann assessment of swallowing ability—Cancer, VHNSS vanderbilt head and neck symptom survey, p = p-value
Bold type indicates statistical significance p < 0.05
aLogistic regression with response PAS=1 or 2, with standard errors clustered on participant
bLinear regression, with standard errors clustered on participant
cDetermined by the MDACC Scale rating only
Results
Forty-two participants were recruited at the start of CRT (Fig. 1). There was attrition of two participants due to recurrent/residual disease and three participants due to complications with comorbidities. Only participants with complete data for at least two of the three follow-up time points were included in the analysis, which necessitated the removal of four participants who only had data at one time point. Of the remaining 33 participants, 20 had complete data at all three time points, and 13 had complete data at two time points. There were a total of 86 observations (n = 24 at 3 months, n = 31 at 6 months and n = 31 at 12 months). There was an overall attrition rate of 21%, and participation rates of 73% at 3 months and 94% at 6 and 12 months. Note that participants remained in the study if a time point was missed.
Fig. 1
Number of participants by time point. Recruitment occurred at the start of CRT. Participation in the 3-month time point was low. Participants often declined this study appointment due to the recency of treatment and some anxiety surrounding their post-treatment PET-CT scan results. In such cases, their first participation was at 6 months
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Participants were predominantly male and under 65 years of age (Table 2). The vast majority presented with early-stage oropharyngeal tumours had advanced nodal metastases and human papilloma virus (HPV)-positive disease. All participants were treated with intensity-modulated radiation therapy (IMRT) or volumetric-modulated arc therapy (VMAT). Most received conventional radiation treatment of 70 Gy/35# and three cycles of high-dose cisplatin. All participants were disease free at the time of participation.
Table 2
Demographic, disease and treatment data
Characteristic
n = 33
Age (years) (mean (SD))
59.9 (7.7)
% (n)
Gender
Male
91 (30)
Female
9 (3)
Primary site
Nasopharyngeal
3 (1)
Oropharyngeal
91 (30)
Laryngeal
6 (2)
T classification
T 1–2
67 (22)
T 3–4
30 (10)
T X
3 (1)
N classification
N 0
6 (2)
N 1
6 (2)
N 2–3
88 (29)
TNM staging
Stage 0
3 (1)
Stage I
3 (1)
Stage III
9 (3)
Stage IVA
82 (27)
Stage IVB
3 (1)
HPV status
Positive
76 (25)
Negative
24 (8)
Radiation treatment
70Gy/35#
94 (31)
Other
6 (2)
Chemotherapy
Cisplatin
70 (23)
Cetuximab
24 (8)
Other
6 (2)
Baseline FOIS
Levels 4–6
27 (9)
Level 7
73 (24)
Percentages may not total 100 due to rounding
T tumour, N nodal, HPV human papillomavirus, SD standard deviation, FOIS functional oral intake scale
Intra- and Inter-rater Reliability: Patterson Radiotherapy Oedema Rating Scale and Penetration–Aspiration Scale
Eighteen of the 86 transnasal laryngoscopy and FEES assessments were re-rated. The intra-rater reliability of the Patterson Radiotherapy Oedema Rating Scale ratings (13 internal sites) was on average, substantial (Kw = 0.83). The sites with the highest agreement (almost perfect) were the true vocal folds, cricopharyngeal prominence and posterior pharyngeal wall (Kw = 1, 0.95, 0.91, respectively). The sites with the lowest agreement (substantial) were the false vocal folds, anterior commissure and interarytenoid space (Kw = 0.60, 0.74, 0.74, respectively). The intra-rater reliability for the PAS ratings was perfect (Kw = 1).
The inter-rater reliability of the Patterson Radiotherapy Oedema Rating Scale ratings was on average, moderate (Kw = 0.44). The sites with the highest agreement (substantial) were the aryepiglottic folds, epiglottis and cricopharyngeal prominence (Kw = 0.69, 0.68, 0.64, respectively). The sites with the lowest agreement (slight) were the true vocal folds, base of tongue and false vocal folds (Kw = 0, 0.12, 0.15, respectively). The inter-rater reliability for the PAS was substantial (Kw = 0.78).
Head and Neck Lymphoedema: General Presentation
All participants had some form of HNL at each time point (Table 3). At 3 months, the majority (71%) had combined external and internal HNL, and the majority (58%) continued to have combined HNL at 6 months. However, by 12 months, most participants had internal HNL only (90%).
Table 3
Head and neck lymphoedema prevalence and outcome measures by time point
HNL type
3 mths, n = 24
6 mths, n = 31
12 mths, n = 31
p, 3 vs. 6 mths
p, 6 vs. 12 mths
No HNL
0
0
0
Both external and internal HNLa
71 (17)
58 (18)
10 (3)
Internal HNL only
29 (7)
42 (13)
90 (28)
External HNL onlya
0
0
0
0.059
<0.001b
External HNL outcome measures
MDACC Scale (% (n))
No visible oedema (0)
29 (7)
42 (13)
90 (28)
Soft visible oedema (1a)
63 (15)
48 (15)
6 (2)
Soft pitting oedema (1b)
8 (2)
10 (3)
3 (1)
0.089
<0.001b
TDC (Mean (SD))
29.8 (8.7)
27.7 (9.6)
21.3 (8.8)
0.167
0.002c
Tape measurements (cm) (Mean (SD))
Lower neck
42.3 (4.6)
41.6 (3.7)
40.5 (4.6)
0.005
0.151c
Upper neck
44.9 (5.2)
43.6 (4.5)
42.2 (4.9)
0.019
0.220c
Ear to ear
25.5 (1.9)
26.0 (2.7)
25.1 (2.1)
0.028
0.032b
Weight (kg) (Mean (SD))
74.9 (16.1)
76.3 (14.4)
80.3 (12.4)
0.903
0.010b
External HNL treatment (% (n))
Yes
13 (3)
26 (8)
10 (3)
No
88 (21)
77 (24)
90 (28)
0.083
0.059b
Internal HNL outcome measures
Maximum severity (all sites) (% (n))
Normal
0
0
0
Mild
4 (1)
16 (5)
35 (11)
Moderate
38 (9)
48 (15)
48 (15)
Severe
58 (14)
35 (11)
16 (5)
0.011
0.013b
Sum severity (all sites)
Mean (SD)
18.9 (5.9)
15.8 (7.7)
9.7 (6.5)
Range
10–28
6–32
2–29
0.009
<0.001b
Number of sites (any severity)
Mean (SD)
10.5 (1.5)
9.9 (2.2)
7.0 (2.9)
Range
7–12
5–13
2-12
0.022
<0.001c
Number of sites (moderate/severe)
Mean (SD)
6.4 (3.1)
4.5 (4.0)
2.2 (2.9)
Range
0–11
0–13
0–10
0.017
<0.001c
Number of sites (severe)
Mean (SD)
2.0 (2.2)
1.4 (2.3)
0.5 (1.4)
Range
0–6
0–9
0–7
0.053
0.007c
Internal site severity (Mod or Severe % (n))
Arytenoids
67 (16)
52 (16)
29 (9)
0.083
0.007b
Epiglottis
63 (15)
52 (16)
35 (11)
0.046
0.317b
Pharyngoepiglottic folds
63 (15)
45 (14)
26 (8)
0.020
0.002b
Aryepiglottic folds
67 (16)
42 (13)
19 (6)
0.020
<0.001b
Valleculae
67 (16)
26 (8)
10 (3)
0.003
0.004b
Posterior pharyngeal wall
54 (13)
58 (18)
29 (9)
0.739
0.001b
Interarytenoid space
58 (14)
42 (13)
23 (7)
0.096
0.006b
Pyriform sinus
50 (12)
29 (9)
10 (3)
0.003
<0.001b
Base of tongue
42 (10)
35 (11)
23 (7)
0.698
0.006b
Cricopharyngeal prominence
58 (14)
35 (11)
16 (5)
0.002
0.010b
False vocal folds
29 (7)
26 (8)
0
0.364
<0.001b
Anterior commissure
17 (4)
10 (3)
3 (1)
0.216
0.021b
True vocal folds
4 (1)
3 (1)
0
0.583
0.317b
Percentages may not total 100 due to rounding
HNL head and neck lymphoedema, MDACC MD Anderson cancer centre, TDC tissue dielectric constant, mths months, SD standard deviation, pp-value
aDetermined by the MDACC Scale rating only
bWilcoxon signed-rank test
cPaired t-test
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External Head and Neck Lymphoedema: Prevalence, Location and Severity
The MDACC Scale demonstrated that external HNL was most prevalent at 3 months (71%), with a small improvement at 6 months (58%) and a large improvement at 12 months (10%) (Table 3). There was a significant reduction in the MDACC Scale score between 6 and 12 months (z = 3.873, p < 0.001), but not between 3 and 6 months (z = 1.698, p = 0.089). When external HNL was present across the three time points, it was largely considered mild (MDACC Scale rating 1a). Descriptive analysis also revealed the most frequently involved site was the submental region, which was affected in all participants who had external HNL at 3 and 12 months, and all but one participant at 6 months.
Both statistical and clinical improvements were also evident in the ALOHA’s TDC value and the tape measurements of the upper and lower neck circumferences (Table 3). Significant improvements in the TDC were found between 6 and 12 months (t26 = − 3.376, p = 0.002, 95% confidence interval (CI) = [− 10.0, − 2.4], although still slightly outside the normal range at 12 months [22]), but not between 3 and 6 months (t19 = − 1.436, p = 0.167, 95% CI = (− 7.2, 1.3)). In contrast to the MDACC Scale and TDC, significant improvements in the tape measurement of the upper and lower neck circumference were found between 3 and 6 months (t19 = − 2.553, p = 0.019, 95% CI = (− 3.0, − 0.3) and t19 = − 3.142, p = 0.005, 95% CI = (− 1.8, − 0.4), respectively), but not between 6 and 12 months (t27 = 1.254, p = 0.220, 95% CI = (− 0.8, 3.2) and t27 = 1.478, p = 0.151, 95% CI = (− 0.4, 2.7), respectively). However, between 6 to 12 months, an increase in body weight was significantly related to an increase in upper and lower neck circumferences (F(1,26) = 6.07, p = 0.021 and F(1,26) = 7.16, p = 0.013, respectively), an effect unseen in the other external HNL measurements.
Although the general trend was for external HNL to improve in the study cohort, individual case analysis revealed that 6% of the total cohort had a worse MDACC Scale score between 3 and 6 months. Nine percent also had a worse TDC between 3 and 6 months, whilst 3% has a worse TDC between 6 and 12 months.
All participants who presented with external HNL at 3 months were referred to the physiotherapy department for further assessment and management. However, only 39% of participants who had ongoing external HNL at 6 months had received external HNL therapy (Table 3). Of the three participants who still had external HNL at 12 months, all had previously received treatment and were continuing self-management at home.
Internal Head and Neck Lymphoedema: Prevalence, Location and Severity
All participants had some degree of internal HNL at each time point (Table 3). The maximum severity score indicates that most participants had moderate or severe internal HNL at 3 months (96%), 6 months (84%) and 12 months (65%). The number of internal sites affected by moderate or severe internal HNL also improved over time. At 3 months, participants had on average 6.4 of 13 internal sites that were moderate or severe, but this reduced to 4.5 sites at 6 months, and 2.2 sites at 12 months. Significant improvements in the maximum severity score and number of internal sites affected by moderate or severe HNL were found between 3 and 6 months (z = − 2.530, p = 0.011 and t21 = − 2.584, p = 0.017, 95% CI = (− 3.1, − 0.3), respectively), and 6 and 12 months (z = − 2.496, p = 0.013 and t28 = − 4.838, p < 0.001, 95% CI = (− 2.5, − 1.0), respectively).
Once again, whilst the general trend was for internal HNL to improve, 12% of the total cohort had an increased number of internal sites involving HNL between 3 and 6 months, and 3% between 6 and 12 months. Nine percent also had a worse sum severity score between 3 and 6 months, and 3% had a worse maximum severity score between 3 and 6 months.
The location and severity of internal HNL at individual sites is shown in Fig. 2. Of note, only five of 13 individual sites significantly improved (p < 0.05) between both 3 and 6 months and 6 and 12 months. These included the cricopharyngeal prominence, pyriform sinus, valleculae, pharyngoepiglottic folds and the aryepiglottic folds.
Fig. 2
Location and severity of internal head and neck lymphoedema by time point
×
Swallowing Outcomes
A third of the cohort had a dysfunctional PAS score (i.e. scores 3–8) at 3 months, indicating some degree of laryngeal penetration or aspiration with thin fluids during the FEES assessment (Table 4). By 12 months, only 13% had a dysfunctional PAS score. Ninety-two percent scored 185 or less on the MASA-C at 3 months, indicating the presence of dysphagia; but by 12 months, only 55% scored 185 or less. Most participants (79%) required some form of diet modification (FOIS scores 4–6) at 3 months, and 68% still required diet modification at 12 months. Seventy-four (of the total 86) VHNSS questionnaires were returned from 32 participants. The presence and severity of individual symptoms are reported in Table 4.
Table 4
Swallowing outcome measures by time point
Outcome measures
3 mths, n = 24, % (n)
6 mths, n = 31, % (n)
12 mths, n = 31, % (n)
p, 3 vs. 6 mths
p, 6 vs. 12 mths
PAS
Level 1-2
67 (16)
65 (20)
87 (27)
Levels 3-6
21 (5)
16 (5)
13 (4)
Levels 7-8
13 (3)
19 (6)
0
0.317
0.077a
FOIS
Level 1
4 (1)
3 (1)
0
Levels 2-3
0
0
0
Levels 4-6
83 (20)
74 (23)
68 (21)
Level 7
13 (3)
23 (7)
32 (10)
0.046
0.180a
MASA-C
Mean (SD)
177 (9.2)
178 (13.7)
186 (7.6)
Range
154-187
120-192
174-198
0.450
0.001b
VHNSS subscale questions (Mean (SD))
n = 20
n = 27
n = 27
Swallow general
Longer to eat due to swallowing (q13)
5.2 (3.4)
5.1 (4.0)
3.9 (3.2)
0.264
0.423b
Swallowing takes great effort (q12)
3.0 (2.3)
2.9 (2.7)
2.2 (2.1)
0.627
0.418b
Swallow solids
Trouble eating certain solid foods (q5)
6.2 (2.9)
5.3 (3.4)
4.1 (3.1)
0.083
0.204c
Food stuck in mouth (q7)
3.3 (2.4)
3.0 (2.5)
2.1 (1.5)
0.937
0.024c
Food stuck in throat (q8)
3.0 (2.5)
4.0 (3.0)
2.6 (2.1)
0.667
0.083c
Cough after swallow (q11)
2.4 (2.3)
2.3 (2.4)
1.7 (1.8)
0.097
0.259c
Choke or strangle on solid foods (q10)
1.8 (1.9)
2.6 (2.6)
1.4 (0.8)
1.000
0.136c
Swallow liquids
Choke or strangle on liquids (q9)
1.7 (1.7)
1.7 (1.8)
1.1 (0.5)
0.054
0.188c
Trouble drinking thin liquids (q6)
1.6 (2.0)
2.3 (2.4)
1.0 (0.2)
0.370
0.014c
Nutrition
Lost appetite (q2)
3.6 (2.3)
3.2 (3.3)
2.0 (2.2)
0.685
0.004c
Liquid supplements to maintain weight (q3)
3.6 (3.1)
2.3 (2.2)
1.6 (1.4)
0.064
0.343c
Trouble maintaining weight due swallow (q4)
3.1 (2.6)
2.0 (2.3)
1.3 (0.9)
0.108
0.219c
Losing weight (q1)
3.0 (2.9)
2.4 (2.1)
1.5 (1.1)
0.149
0.113c
Percentages may not total 100 due to rounding mths months, SD standard deviation, PAS penetration-aspiration scale, FOIS functional oral intake scale, MASA-C mann assessment of swallowing ability—cancer, VHNSS vanderbilt head and neck symptom survey, VHNSS scoring 1–3 mild, 4–6 moderate, 7–10 severe, p = p-value
aWilcoxon signed-rank test
bPaired t-test
Associations Between External and Internal Head and Neck Lymphoedema and Swallowing Outcomes
The relationships between the external and internal HNL variables and swallowing outcomes are presented in Table 1. Backwards stepwise procedures did not identify any other variables of significance, and there was no loss of normality in model residuals. Regression modelling revealed significant (p < 0.05) relationships between dysfunctional PAS scores (i.e. scores 3–8), FOIS scores and MASA-C scores and external HNL. Significant relationships (p < 0.05) were also found between dysfunctional PAS scores, FOIS scores and MASA-C scores and all three of the internal HNL summary variables. These results indicate that participants were more likely to experience dysphagia, have laryngeal penetration and/or aspiration and require increased diet modification if they had a higher severity of external and/or internal HNL, and if they had more diffuse internal HNL. Of interest, internal HNL that occurred at the aryepiglottic folds, pyriform sinus and cricopharyngeal prominence were also amongst some of the strongest predictors of dysfunctional PAS scores, worse FOIS scores and worse MASA-C scores.
The VHNSS swallow general and swallow solids subscales were highly significantly correlated (r = 95%). Therefore, only the VHNSS swallow solids, swallow liquids and nutrition subscales were examined in the regression modelling. In these models, there was less association between the VHNSS subscales and the HNL variables, as compared to the PAS, FOIS and MASA-C scores. But of note, significant relationships were found between the swallow solids subscale and external HNL, the sum severity score for internal HNL and the total number of internal sites affected by HNL (all p < 0.05). These results signify that participants with a higher severity of external HNL and more diffuse internal HNL had higher (or worse) levels of patient-reported symptom burden in relation to swallowing and eating solid foods. Like the PAS, FOIS and MASA-C scores, the aryepiglottic folds, pyriform sinus and cricopharyngeal prominence were again amongst some of the strongest predictors for symptom burden with solid foods.
Discussion
This study describes the trajectory of external and internal HNL and its association with dysphagia in a homogeneous cohort of HNC patients treated with CRT. The results indicate that external and internal HNL are both prevalent following CRT and that two separate trajectory patterns exist in the 12 months post-treatment. External HNL was most prevalent at 3 months, began to improve at 6 months and had largely resolved by 12 months. In contrast, internal HNL persisted throughout the whole 12 months and whilst there was some reduction in its severity and diffuseness, it never fully resolved during the study period. It can therefore be expected that patients with HNC who are 12 months post-CRT may present with internal HNL in the absence of external HNL. Patients who also have a higher severity of external and/or internal HNL during the first 12 months post-treatment, and those with more diffuse internal HNL may also experience more severe dysphagia.
The current study is consistent with previous research that has demonstrated the high prevalence of external and internal HNL in HNC patients post-treatment [6, 9, 10, 12, 19]. However, prior studies have examined both surgical and non-surgical treatment modalities which contrasts with the current study’s homogeneous cohort. However, the use of a homogeneous cohort comprising only of HNC patients treated with CRT can also be seen as a strength, in that it has provided evidence that these non-surgical patients are just as likely to develop external and internal HNL in the first 12 months post-treatment as their surgical counterparts. One difference though is that the peak severity of HNL in the current study occurred around 3 months, whereas it occurred around 9 months in Ridner’s et al. [6] longitudinal study. It is unknown whether this difference can be attributed their heterogeneous population, but it is a disparity that warrants further investigation.
The current study has also shown that whilst the presence of internal HNL remains constant across the 12 months following CRT, its presentation constantly changes. HNL that occurred at five of the 13 internal sites, including the aryepiglottic folds, valleculae and pyriform sinus, consistently improved from 3 to 12 months, whereas other internal sites, such as the epiglottis, showed early improvement between 3 and 6 months, and then plateaued from 6 to 12 months. In contrast, the arytenoids had limited improvement from 3 to 6 months and then significantly improved from 6 to 12 months. No other studies are currently available for comparison, but these results suggest that changes in HNL at individual internal sites are not uniform and that differences may exist in the lymphatic drainage of individual sites. Future studies that examine the trajectory of HNL at the individual internal sites, whilst also examining their lymphatic drainage patterns would be valuable.
It was also noted that whilst the general trend was for external and internal HNL to improve, some participants’ HNL worsened over the 12-month study period. It was noted that the most severe cases of external and internal HNL worsening occurred in participants with severe dysphagia who were either nil by mouth and tube dependent or restricted to a single food consistency. It is known that muscle contraction aides lymph transportation through the lymphatic vessels [34]; therefore, it may be postulated that the low frequency and force of swallows observed in those participants with severe dysphagia and particularly those who are tube dependent may further limit the effectiveness of the lymphatic system to drain stagnant lymph. This postulation warrants further longitudinal investigation in a larger sample size, but speech pathologists may need to consider the risk of none or limited oral intake for not only disuse atrophy and fibrosis, but also for worsening HNL.
Less than half of the participants in the current study who had external HNL at 3 months accessed treatment, despite being referred onto a free hospital service. These results suggest that some degree of spontaneous recovery has occurred as most participants’ external HNL resolved by 12 months. However, significant improvements were not seen until after 6 months which may indicate that many participants lived with the burden of their external HNL for some time. Therefore, even though there may be some expectation of spontaneous recovery in HNC patients treated with CRT, timely access to external HNL treatment is still required.
The results of the current study also support the association between external and internal HNL and the presence of more severe dysphagia [7, 13, 16, 18, 19], and this association has now been demonstrated across acute, sub-acute and long-term periods post-HNC treatment. However, a limitation of the current evidence base is that none of the authors have described how external and internal HNL impact the physiological events that lead to penetration–aspiration risk and issues with bolus flow and clearance. It is logical to expect that patients with more severe and diffuse internal HNL would experience changes to their swallowing safety and efficiency [16], and the results of the current study would support this hypothesis. However, future studies that incorporate a more comprehensive assessment of swallowing function are required. In the meantime, speech pathologists and other oncologic clinicians need to be aware of the negative impact that external and internal HNL may have on swallowing function in HNC patients post-CRT. Laryngoscopy needs to be utilised to identify and measure internal HNL and monitor its progression and/or resolution over time.
The current study also raises questions about how internal and external HNL are measured. Patterson’s Radiotherapy Oedema Rating Scale does not utilise a composite score and this has led many authors [6, 9, 16, 18] to adopt the maximum severity score for internal HNL. However, this score may not reflect the change that occurs in internal HNL over time and may inflate its overall severity. For example, 64% of participants in this study were classified as having moderate or severe internal HNL at 12 months, but on average, only 2.2 of the 13 internal sites had moderate or severe HNL. The use of a sum severity score or the tallying of the number of internal sites affected, as undertaken in this study, may provide a more comprehensive overview of how internal HNL changes over time. The Patterson’s Radiotherapy Oedema Rating Scale was recently revised, now titled the Revised Patterson Oedema Scale [24], but there continues to be no guidance surrounding composite scoring.
The use of the MDACC Scale as an assessment for external HNL also has limitations. It is a clinical assessment only and hence lacks the sensitivity and psychometric testing of quantitative assessment tools, such as the ALOHA. The MDACC Scale was used as the primary assessment tool in the current study as at the time the study was designed, the ALOHA was not previously used in a diagnostic capacity and was only used to quantify the reduction of external HNL over time [20, 21]. However, normative TDC values for the head and neck region have recently been published in 2021 [22] and were incorporated in the analysis of the current study. The existence of normative reference data now improves the ALOHA’s capacity to be used as an isolated assessment tool.
Limitations
It is acknowledged that the current study has several limitations. Firstly, a baseline or pre-treatment time point was sought, but participation was worse than expected and there was insufficient data to include in this study. This has been attributed to the high levels of anxiety and distress surrounding diagnosis and treatment. Similarly, participation in the 3-month time point was also low, with participants often declining this study appointment due to the recency of treatment and some anxiety surrounding their post-treatment PET-CT scan results. These factors, along with general attrition, may affect this study’s generalisability.
Secondly, the reliability of the current studies internal HNL ratings using Patterson’s Radiotherapy Oedema Rating Scale were also variable. The current study used an education package to support rating determinations which saw improved reliability compared to the authors’ previous work [10, 16], but further work in the area of clinician training is required. The reliability of the external HNL ratings was also not tested in this study.
Finally, there were several weaknesses in the FEES procedure, including no form of volumetric control with fluid trials, no food trials, no measure of pharyngeal residue and no description of physiological events. Other side effects that are known to influence swallowing and oral intake following HNC treatment, such as xerostomia, secretions and dysgeusia, were also not measured. The incorporation of these elements into future studies would be valuable to ensure that there is a more comprehensive assessment of swallowing function and diet status.
Conclusion
External and internal HNL are both prevalent following CRT and two separate trajectory patterns exist in the 12 months post-treatment. External HNL was most prevalent at 3 months, began to improve at 6 months and had largely resolved by 12 months, whereas internal HNL persisted throughout the whole 12 months, but with some changes to its severity and diffuseness. Patients who experienced higher severities of external and/or internal HNL and those who had more diffuse internal HNL also experienced more severe dysphagia. This study supports early screening, diagnosis and treatment of HNL post-treatment, but further consideration needs to be given to how internal HNL is treated and what role speech pathologists play in this management.
Acknowledgements
The authors would like to thank Laurie-Anne Minslow from the Radiation Oncology Department at the Calvary Mater Newcastle for her assistance with the inter-rater reliability testing.
Declarations
Conflict of interest
The authors report no conflict of interest. The authors alone are responsible for the content and writing of the paper.
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