ID | 118202 |
Author |
Ohmae, Nao
Tokushima University
Yasui-Yamada, Sonoko
Tokushima University
Tokushima University Educator and Researcher Directory
KAKEN Search Researchers
Furumoto, Taiki
Tokushima University
Wada, Kyoko
Tokushima University
Hayashi, Haruka
Tokushima University
Kitao, Midori
Tokushima University
Yamanaka, Ayaka
Tokushima University
Kubo, Miyu
Tokushima University
Matsuoka, Momoyo
Tokushima University
Shimada, Aki
Tokushima University
Kitamura, Yoshiaki
Tokushima University
Tokushima University Educator and Researcher Directory
KAKEN Search Researchers
Katoh, Shinsuke
Tokushima University
Tokushima University Educator and Researcher Directory
KAKEN Search Researchers
|
Keywords | Cachexia
Muscle function
Physical activity
Resting energy expenditure
Respiratory quotient
Head and neck cancer
|
Content Type |
Journal Article
|
Description | Background & aims: Cancer cachexia is commonly associated with poor prognosis in patients with head and neck cancer (HNC). However, its pathophysiology and treatment are not well established. The current study aimed to assess the muscle mass/quality/strength, physical function and activity, resting energy expenditure (REE), and respiratory quotient (RQ) in cachectic patients with HNC.
Methods: This prospective cross-sectional study analyzed 64 patients with HNC. Body composition was measured via direct segmental multifrequency bioelectrical impedance analysis, and muscle quality was assessed using echo intensity on ultrasonography images. Muscle strength was investigated utilizing handgrip strength and isometric knee extension force (IKEF). Physical function was evaluated using the 10-mwalking speed test and the five times sit-to-stand (5-STS) test. Physical activity was examined using a wearable triaxial accelerometer. REE and RQ were measured via indirect calorimetry. These parameters were compared between the cachectic and noncachectic groups. Results: In total, 23 (36%) patients were diagnosed with cachexia. The cachectic group had a significantly lower muscle mass than the noncachectic group. Nevertheless, there was no significant difference in terms of fat between the two groups. The cachectic group had a higher quadriceps echo intensity and a lower handgrip strength and IKEF than the noncachectic group. Moreover, they had a significantly slower normal and maximum walking speed and 5 STS speed. The number of steps, total activity time, and time of activity (<3 Mets) did not significantly differ between the two groups. The cachectic group had a shorter time of activity (≥3 Mets) than the noncachectic group. Furthermore, the cachectic group had a significantly higher REE/body weight and REE/fat free mass and a significantly lower RQ than the noncachectic group. Conclusions: The cachectic group had a lower muscle mass/quality/strength and physical function and activity and a higher REE than the noncachectic group. Thus, REE and physical activity should be evaluated to determine energy requirements. The RQ was lower in the cachectic group than that in the noncachectic group, indicating changes in energy substrate. Further studies must be conducted to examine effective nutritional and exercise interventions for patients with cancer cachexia. |
Journal Title |
Clinical Nutrition ESPEN
|
ISSN | 24054577
|
Publisher | Elsevier|European Society for Clinical Nutrition and Metabolism
|
Volume | 53
|
Start Page | 113
|
End Page | 119
|
Published Date | 2022-12-09
|
Rights | © 2022 The Authors. Published by Elsevier Ltd on behalf of European Society for Clinical Nutrition and Metabolism. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).
|
EDB ID | |
DOI (Published Version) | |
URL ( Publisher's Version ) | |
FullText File | |
language |
eng
|
TextVersion |
Publisher
|
departments |
Medical Sciences
University Hospital
|