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CONUT score as a predictor for anamorelin efficacy in patients with cancer cachexia receiving chemotherapy
Journal of Pharmaceutical Health Care and Sciences volume 10, Article number: 36 (2024)
Abstract
Background
Anamorelin is expected to improve cancer cachexia by increasing lean body mass (LBM) due to increased appetite and protein synthesis. However, the effect of anamorelin on cancer cachexia in real-world practice is unclear. The purpose of this study was to evaluate the efficacy and safety of anamorelin and to identify predictors of efficacy on treatment with anamorelin.
Methods
We retrospectively analyzed data from patients with cancer cachexia treated with chemotherapy between May 2021 and August 2022. Efficacy of anamorelin was evaluated using LBM, with “12-week sustained effective response” to anamorelin treatment defined as maintenance or an increase in LBM for 12 weeks. We examined factors associated with “12-week sustained effective response” to anamorelin treatment using a multivariable logistic model that included controlling nutritional status (CONUT) score, an objective assessment of nutritional disorders, and the modified Glasgow prognostic score (mGPS), which scores the cachexia status of cancer patients. To assess patient subjective quality of life (QOL) changes related to eating after starting anamorelin treatment, we used a questionnaire (QOL-ACD appetite-related items: Q8, 9, 11). Adverse events were evaluated in accordance with the Common Terminology Criteria for Adverse Events (CTCAE) Version 5.0.
Results
On analysis of data from 40 patients, 23 patients showed a 12-week sustained effective response to anamorelin (57.5%). At 12 weeks, LBM significantly increased by 1.63 ± 3.73 kg (mean ± SD). Multivariable logistic analysis revealed that a low CONUT score was significantly associated with “12-week sustained effective response” to anamorelin treatment (adjusted odds ratio: 13.5, 95% confidence intervals: 2.2–84.2, P = 0.004). QOL assessment showed a trend toward increased appetite and enjoyment of meals after anamorelin initiation. Five patients (12.5%) had an increase in HbA1c of more than 1.0% during the 12 weeks after the start of anamorelin. No patient had QT interval prolongation or grade 3 or higher hepatic transaminase elevation.
Conclusion
Anamorelin may maintain or increase LBM with tolerable safety in patients with cancer cachexia undergoing chemotherapy. A low CONUT score, despite meeting criteria for cancer cachexia, is suggested as a predictor for the efficacy of anamorelin, indicating that patients with a low CONUT score may benefit from early introduction of anamorelin.
Background
Cancer cachexia is defined as “a multifactorial syndrome characterized by a persistent loss of skeletal muscle mass (with or without fat loss) that cannot be completely reversed by conventional nutritional therapy and progresses to functional impairment” [1]. The European Palliative Care Research Collaborative (EPCRC) diagnoses cachexia in patients who meet any of the following three criteria: (1) Weight loss > 5% over the past 6 months, (2) BMI < 20 and any degree of weight loss > 2%, (3) Sarcopenia and any degree of weight loss > 2% [1]. The development of cachexia involves inflammatory cytokines produced as a biological response and various factors produced by tumor cells, which together lead to abnormal energy metabolism and the degradation of skeletal muscle [2]. The main symptoms are weight loss, loss of skeletal muscle mass, and anorexia, and it is this last factor – anorexia - which reduces quality of life (QOL).
Cancer cachexia is classified into three stages: precachexia, cachexia, and refractory cachexia [1]. Kimura et al. reported that the prognosis of patients with advanced non-small cell lung cancer complicated with cachexia is worse than that of patients without cachexia, no matter what stage of cachexia develops during the course of the disease [3]. In cancer patients, weight loss is associated with a variety of risks, including increased side effects during chemotherapy, fewer cycles of chemotherapy, less effective chemotherapy and radiation therapy, increased risk of surgery, and ultimately, decreased survival [4,5,6,7,8]. Furthermore, the efficacy of these combined therapies, including immune checkpoint inhibitors and cytotoxic anticancer drugs, is reportedly decreased in patients with cancer cachexia [9,10,11,12]. Thus, cancer cachexia is closely related to the efficacy of treatment, and an improvement of cancer cachexia is considered essential.
Although the European Palliative Care Research Collaborative (EPCRC) recommends intervention from the pre-cachexia stage [1], no standard treatment strategy to improve metabolic abnormalities in cancer cachexia has yet been established. Rather, a combination of pharmacotherapy and exercise therapy is currently considered effective in addressing the treatable factors of cachexia [13].
Anamorelin is an oral drug with ghrelin-like effects. In preclinical studies (in vitro and in vivo studies), anamorelin was shown to be a potent and highly specific ghrelin receptor (growth hormone secretagogue receptor type 1a) agonist with significant effects in stimulating appetite, increasing food intake and weight, and stimulating GH secretion [14]. GH promotes the secretion of insulin-like growth factor-1 (IGF-1) from the liver, and IGF-1 increases muscle mass. Anamorelin has high affinity (0.70 nM) for ghrelin receptors, a level which is slightly lower than that of natural ghrelin, and has no antagonist properties [14]. An in vitro report including anamorelin revealed that access of ghrelin ligands to the brain, particularly to the reward areas, is important for eliciting more potent appetite stimulant effects [15].
Currently, however, clinical evidence for the efficacy of treatment with anamorelin is insufficient. In particular, it is unclear which type of patient would most benefit from this agent.
We have focused on controlling nutritional status (CONUT) score and the modified Glasgow prognostic score (mGPS). The CONUT score is an index calculated from serum albumin concentration, total peripheral lymphocyte count, and total cholesterol concentration. CONUT scores are associated with sarcopenia and physical function in elderly patients with colorectal cancer [16]. Patients with cancer cachexia have been reported to have significantly lower total cholesterol compared to patients without cancer cachexia or non-cancer patients [17]. Accordingly, total cholesterol levels might indicate the stage of cachexia. Nevertheless, no study to date has described the use of CONUT score to predict the effectiveness of cancer cachexia treatment.
The mGPS, consisting of C-reactive protein (CRP) and albumin, is one of the most extensively validated prognostic factors in some cancer types [18,19,20,21].
Here, we evaluated the efficacy of anamorelin in clinical practice and identified patients who would benefit from anamorelin by using the CONUT score and mGPS.
Methods
Patients
This study was conducted under a retrospective observational design using data obtained from patient electronic medical records at our hospital. The study population consisted of patients with cancer cachexia who were started on anamorelin at Gifu University Hospital between May 2021 and August 2022. We excluded patients whose LBM was not evaluated before starting anamorelin.
Criteria for administration of anamorelin
In our institution, anamorelin is prescribed in the outpatient chemotherapy unit if the physician confirms that the patient has had weight loss of 5% or more and anorexia within 6 months, and two or more of the following: (1) fatigue or malaise; (2) generalized muscle weakness; and (3) CRP > 0.5 mg/dL, hemoglobin < 12 g/dL, or albumin < 3.2 g/dL. If a pharmacist confirms the above criteria, they propose the prescription of anamorelin to the physician, who then prescribes anamorelin.
Efficacy and safety of anamorelin
Patients included in the study received nutritional guidance and body composition assessment by dietitians before anamorelin was started. The body composition assessment was performed by dietitians using the direct segmental multi-frequency bioelectrical impedance analysis method (DSM-BIA) with InBody [22]. Electrocardiogram, blood glucose, and liver function marker measurements were also used to assess side effects. The evaluations included assessment of body composition, QOL, and side effects of anamorelin. They were performed every 3–4 weeks, following which the physician decided whether to continue anamorelin. The primary study outcome was “12-week sustained effective response” to anamorelin treatment, defined as maintenance or an increase in LBM for 12 weeks.
To evaluate the safety of anamorelin, we investigated the elevation of hepatic transaminases above grade 3, QT prolongation, and onset or exacerbation of diabetes mellitus. These adverse events were evaluated in accordance with the Common Terminology Criteria for Adverse Events (CTCAE) Version 5.0. The exacerbation of diabetes was defined as an increase in HbA1c of 1% or more from baseline. Every 3–4 weeks after starting anamorelin, the physician decided whether to continue anamorelin or not based on the evaluation of changes in LBM, improvement in anorexia and adverse events.
Assessment of quality of life
QOL was assessed using a QOL questionnaire for cancer patients treated with anticancer drugs (QOL-ACD) [23], and performed by pharmacists or nurses. Patient quality of life was assessed using QOL-ACD Q8, Q9, and Q11, namely “Did you have a good appetite?” for Q8, “Did you enjoy your meals?” for Q9, and “Did you lose any weight?” for Q11. Patients answered using a 5-point scale for each of these 3 questions. Q8 and Q9 defined responses of “1” and “5” as “not at all” and “very much”, respectively, while Q11 defined responses of “1” as “no, I have instead gained weight” and “5” as “Yes”.
Statistical analyses
Statistical analyses were conducted using IBM SPSS version 22 (IBM Japan Ltd., Tokyo, Japan), R software version 3.5.1 (www.r-project.org) and GraphPad Prism version 6.0 (GraphPad Software, San Diego, CA, USA). P-values less than 0.05 were considered significant. Patient characteristics were described as medians with 25th and 75th percentiles for continuous variables, and by frequency and percentage for categorical variables.
The percentage of patients who obtained a response was compared for PS (0, 1, 2), CONUT score (0–1: normal, 2–4: mild, 5–8: moderate, 8<: severe), and mGPS (0,1,2), respectively.
We showed mean changes from baseline values (± SD) in LBM, body weight, and skeletal muscle mass at each of weeks 3–4, weeks 8–9, and week 12. Comparisons of means between two or more corresponding groups were performed using repeated measures ANOVA. Results for the three QOL-ACD questions (Q8, 9, and 11) are shown as the percentage of patients with each response for each timing, i.e., at baseline, weeks 3–4, weeks 8–9, and week 12, respectively. We performed a Cochran Q-test statistical analysis with each QOL question as a categorical variable divided into level ≤ 3 and level > 3, respectively.
We performed multivariable logistic regression analyses to evaluate the associations between response to anamorelin and mGPS, as well as between response to anamorelin and CONUT scores [16,17,18,19,20,21]. First, both mGPS and CONUT scores were incorporated into the regression model by the forced entry method. Second, either mGPS or CONUT score was incorporated into the regression model along with one potential confounder at a time (PS, age, gender, BMI, gastric cancer) that may impact the 12-week sustained effective response to anamorelin. The reliability of the regression model was internally validated via a bootstrap method by measuring overfitting quantified by optimism parameter in a calibration plot. Bootstrap validation was performed with one hundred fifty resamples. Variance Inflation Factor (VIF) was calculated to check the multicollinearity between CONUT score and mGPS. To adjust for confounding, we performed logistic analyses by including one factor (PS, age, gender, BMI, gastric cancer) at a time in the CONUT score and mGPS models that may have an impact on 12-week sustained effective response to anamorelin.
Results
Patient demographics
Of the 55 patients who started anamorelin, 15 patients met the exclusion criterion of no LBM measurement before the initiation of anamorelin, leaving 40 patients for inclusion in the analysis. Patient background is shown in Table 1. Of the 40 patients, 30 (75%) were male and 10 (25%) were female. By cancer type, gastric, pancreatic, colorectal, and lung cancers accounted for 23, 9, 6, and 2 patients, respectively. Median LBM was 42.2 kg (interquartile range [IQR]: 36.1–47.1), and performance status (PS; 0, 1, 2) was 6, 29, and 5, respectively. All patients were cStage IV. In this study, none of the patients took drugs that stimulate ghrelin release, such as olanzapine or rikkunshito, during the period of anamorelin administration. Nutritional therapy included the introduction of high-protein diets and nutritional supplements at the discretion of the dietitian. Data on adherence to nutritional therapy was difficult to obtain because the patients in this study were undergoing outpatient chemotherapy, and it is difficult in real-world practice to collect strict data on adherence to nutritional therapies during an interview every few weeks. Further, exercise therapy was not provided to patients.
Efficacy and safety of anamorelin
Twenty-three patients showed a response to anamorelin (57.5%). Changes in LBM, body weight, and skeletal muscle mass after anamorelin initiation over the 12-week course are shown in Fig. 1. The mean change (± SD) in LBM at weeks 3–4, 8–9, and 12 after anamorelin was 1.29 ± 2.16 kg, 1.06 ± 2.90 kg, and 1.63 ± 3.73 kg, respectively, a significant increase (P < 0.05). Changes in body weight and skeletal muscle mass were also significantly elevated at all points. Five patients (12.5%) had an increase in HbA1c of more than 1.0% during the 12 weeks after the start of anamorelin. No patient had QT interval prolongation or Grade 3 or higher hepatic transaminases elevation.
Change in QOL-ACD (Q8, 9, 11) after the start of anamorelin
We evaluated changes in the proportion of patients scoring in each of the five scores of the QOL-ACD questionnaire after starting anamorelin treatment (Fig. 2). The proportion of patients scoring at level 3 or lower gradually declined for Q8 (baseline: 77.5%, week 3–4: 46.2%, week 8–9: 38.2%, week 12: 36.7%) and Q9 (baseline: 82.5%, week 3–4: 66.7%, week 8–9: 52.9%, and week 12: 53.3%). In addition, for Q11, the proportion of patients scoring at level 3 or higher also gradually declined after the start of anamorelin (baseline: 97.5%, week 3–4: 87.2%, week 8–9: 76.5%, week 12: 73.3%). Cochran Q test results showed a significant increase in the percentage of scores > 3 for questions 8 (P = 0.036) and 9 (P = 0.009), and a significant decrease in the percentage of scores > 3 for question 11(P < 0.001).
Determinants of a 12-week sustained effective response to anamorelin treatment
Figure 3 shows the percentage of patients who responded to anamorelin treatment in each group by CONUT score (0–1, 2–4, 5–8, > 8) and mGPS (0, 1, 2) factors. The results show that significantly more patients had a 12-week sustained effective response to anamorelin treatment in the CONUT 0–1 and CONUT 2–4 groups than in the CONUT 5–8 and CONUT > 8 groups. The mGPS0 group had a higher response rate to anamorelin than the mGPS1 and mGPS2 groups. As shown in Table 2, a low CONUT score (< 5) was a significant independent predictor for patients with a 12-week sustained effective response to anamorelin treatment (OR: 13.5, 95% CI: 2.2–84.2, P = 0.004). As shown in Table 3, CONUT scores significantly affected 12-week sustained effective response to anamorelin in all factors, while mGPS did not affect it in any factor.
Discussion
We evaluated the efficacy and safety of anamorelin in real-world clinical practice and identified predictors of efficacy of treatment with anamorelin. After starting anamorelin, LBM increased significantly, and QOL assessment showed improved appetite. Further, a low CONUT score (< 5) was identified as a predictor of efficacy of the treatment with anamorelin. On the other hand, a few patients developed new onset or exacerbation of diabetes after starting anamorelin. These results suggest that active anamorelin administration may be recommended for patients with anamorelin indications and low CONUT scores.
Previous studies included two international and one Japanese randomized, double-blind, placebo-controlled trials in patients with inoperable stage III or IV non-small cell lung cancer with cachexia. The two international phase III trials (ROMANA1, ROMANA2) compared anamorelin 100 mg with placebo at 93 centers in 19 countries and reported increases in LBM of 0.99 kg and 0.65 kg, respectively, after 12 weeks of anamorelin treatment, with both increases being significantly higher than placebo [24]. In the Japanese phase III study (ONO-7643-04), LBM increased by 1.38 kg after 12 weeks of anamorelin treatment, which was also significantly higher than placebo [25]. In our study, the mean increased LBM change at 12 weeks after anamorelin initiation was 1.63 kg, similar to the results of these studies [24, 25].
Further, in the current study all 5 patients with CONUT 0–1 and 11 of the 13 patients with CONUT 2–4 had anamorelin responses, while only 7 of the 22 patients with CONUT ≥ 5 had anamorelin responses. In other words, the anamorelin response rates for CONUT < 5 and CONUT ≥ 5 were 88.9% (16/18) and 31.8% (7/22), respectively, clearly higher for CONUT < 5. Unfortunately, we could only include the CONUT score and mGPS in our multivariable logistic model as predictors of anamorelin efficacy to avoid overfitting due to small sample sizes. However, the results of our multivariable logistic model and the difference in the proportion of anamorelin responders also suggest that the CONUT score may be a useful predictor of response when considering starting anamorelin.
Iwai et al. compared baseline factors at initiation in patients with gastrointestinal cancer who did and did not respond to anamorelin [26]. They found that total protein, albumin, transferrin, and prognostic nutritional index were significantly higher in responders, whereas neutrophil/lymphocyte ratio and C-reactive protein/albumin ratio were significantly lower. This finding by Iwai et al. that the proportion of patients with a low nutritional status prior to initiation is higher in patients who do not respond to anamorelin supports our results. Takeda et al. compared changes in body weight and appetite after anamorelin treatment in two groups of pancreatic cancer patients with cachexia who were divided into moderate (5–10%) and severe (> 10%) weight loss groups [27]. Results showed that the moderate weight loss group (N = 8) gained significantly more weight than the severe weight loss group (N = 16). Although the number of patients in this study was small, it is possible that patients with a smaller amount of weight loss prior to anamorelin initiation may be more responsive to anamorelin.
Our results and the results of the two previous studies [26, 27] suggest that anamorelin may not be effective if the patient is extremely underweight or has low nutritional markers at initiation of the drug. In other words, cancer cachexia should be diagnosed in a timely manner in patients undergoing cancer chemotherapy, and anamorelin should be started early. Therefore, collaborative efforts by physicians, pharmacists, nurses, and dietitians to monitor anorexia and weight loss in patients may be vital to improving cancer cachexia and increasing LBM.
Several limitations of our study should be mentioned. First, it was conducted under a retrospective design and analysed data from a single center. Second, because the sample size was small and the number of factors included in the multivariable analysis was limited to avoid overfitting, consideration of confounding factors may have been insufficient. Third, improvement in patients’ physical abilities, such as grip strength and 6-minute walking distance, could not be assessed. Fourth, it was not possible to determine changes in dietary caloric intake.
Conclusion
For patients with cancer cachexia, anamorelin was found to be highly effective and well tolerated. In addition, patients with cachexia but a low CONUT score may benefit from anamorelin. We consider that administration of anamorelin to patients with early-stage cancer cachexia, such as those with low CONUT scores, is appropriate.
Data availability
Not applicable.
References
Fearon K, Strasser F, Anker SD, Bosaeus I, Bruera E, Fainsinger RL, et al. Definition and classification of cancer cachexia: an international consensus. Lancet Oncol. 2011;12:489–95.
Aoyagi T, Terracina KP, Raza A, Matsubara H, Takabe K. Cancer cachexia, mechanism and treatment. World J Gastrointest Oncol. 2015;7:17–29.
Kimura M, Naito T, Kenmotsu H, Taira T, Wakuda K, Oyakawa T, et al. Prognostic impact of cancer cachexia in patients with advanced non-small cell lung cancer. Support Care Cancer. 2015;23:1699–708.
Andreyev HJ, Norman AR, Oates J, Cunningham D. Why do patients with weight loss have a worse outcome when undergoing chemotherapy for gastrointestinal malignancies? Eur J Cancer. 1998;34:503–9.
Fearon K, Arends J, Baracos V. Understanding the mechanisms and treatment options in cancer cachexia. Nat Rev Clin Oncol. 2013;10:90–9.
Ross PJ, Ashley S, Norton A, Priest K, Waters JS, Eisen T, et al. Do patients with weight loss have a worse outcome when undergoing chemotherapy for lung cancers? Br J Cancer. 2004;90:1905–11.
Suzuki H, Asakawa A, Amitani H, Nakamura N, Inui A. Cancer cachexia-pathophysiology and management. J Gastroenterol. 2013;48:574–94.
Vaughan VC, Martin P, Lewandowski PA. Cancer cachexia: impact, mechanisms and emerging treatments. J Cachexia Sarcopenia Muscle. 2013;4:95–109.
Roch B, Coffy A, Jean-Baptiste S, Palaysi E, Daures JP, Pujol JL, et al. Cachexia - sarcopenia as a determinant of disease control rate and survival in non-small lung cancer patients receiving immune-checkpoint inhibitors. Lung Cancer. 2020;143:19–26.
Morimoto K, Uchino J, Yokoi T, Kijima T, Goto Y, Nakao A, et al. Impact of cancer cachexia on the therapeutic outcome of combined chemoimmunotherapy in patients with non-small cell lung cancer: a retrospective study. Oncoimmunology. 2021;10:1950411.
Fujii H, Araki A, Iihara H, Kaito D, Hirose C, Kinomura M, et al. Cancer cachexia as a determinant of efficacy of first-line pembrolizumab in patients with advanced non-small cell lung cancer. Mol Clin Oncol. 2022;16:91.
Fujii H, Makiyama A, Iihara H, Okumura N, Yamamoto S, Imai T, et al. Cancer Cachexia reduces the efficacy of Nivolumab Treatment in patients with Advanced Gastric Cancer. Anticancer Res. 2020;40:7067–75.
Naito T. Evaluation of the true endpoint of clinical trials for Cancer Cachexia. Asia Pac J Oncol Nurs. 2019;6:227–33.
Pietra C, Takeda Y, Tazawa-Ogata N, Minami M, Yuanfeng X, Duus EM, et al. Anamorelin HCl (ONO-7643), a novel ghrelin receptor agonist, for the treatment of cancer anorexia-cachexia syndrome: preclinical profile. J Cachexia Sarcopenia Muscle. 2014;5:329–37.
Howick K, Chruscicka B, Felice D, Ramirez VT, van Leuven L, Pietra C, et al. Behavioural characterization of ghrelin ligands, anamorelin and HM01: Appetite and reward-motivated effects in rodents. Neuropharmacology. 2020;168:108011.
Güç ZG, Altay C, Özgül HA, Ellidokuz H, Yavuzşen T. GNRI and Conut scores: simple predictors of Sarcopenia in Metastatic Colorectal Cancer patients. Support Care Cancer. 2022;30:7845–52.
Zwickl H, Hackner K, Köfeler H, Krzizek EC, Muqaku B, Pils D, et al. Reduced LDL-Cholesterol and Reduced Total Cholesterol as potential indicators of Early Cancer in Male Treatment-Naïve Cancer patients with pre-cachexia and Cachexia. Front Oncol. 2020;10:1262.
Dolan RD, McSorley ST, Horgan PG, Laird B, McMillan DC. The role of the systemic inflammatory response in predicting outcomes in patients with advanced inoperable cancer: systematic review and meta-analysis. Crit Rev Oncol Hematol. 2017;116:134–46.
Nozoe T, Iguchi T, Egashira A, Adachi E, Matsukuma A, Ezaki T. Significance of modified Glasgow prognostic score as a useful indicator for prognosis of patients with gastric carcinoma. Am J Surg. 2011;201:186–91.
Tsuchihashi K, Ito M, Moriwaki T, Fukuoka S, Taniguchi H, Takashima A, et al. Role of Predictive Value of the modified Glasgow Prognostic score for later-line chemotherapy in patients with metastatic colorectal Cancer. Clin Colorectal Cancer. 2018;17:e687–97.
Ahmad J, Grimes N, Farid S, Morris-Stiff G. Inflammatory response related scoring systems in assessing the prognosis of patients with pancreatic ductal adenocarcinoma: a systematic review. Hepatobiliary Pancreat Dis Int. 2014;13:474–81.
Blue MNM, Hirsch KR, Brewer GJ, Cabre HE, Gould LM, Tinsley GM, et al. The validation of contemporary body composition methods in various races and ethnicities. Br J Nutr. 2022;3:1–11.
Kurihara M, Shimizu H, Tsuboi K, Kobayashi K, Murakami M, Eguchi K, et al. Development of quality of life questionnaire in Japan: quality of life assessment of cancer patients receiving chemotherapy. Psychooncology. 1999;8:355–63.
Temel JS, Abernethy AP, Currow DC, Friend J, Duus EM, Yan Y, et al. Anamorelin in patients with non-small-cell lung cancer and cachexia (ROMANA 1 and ROMANA 2): results from two randomised, double-blind, phase 3 trials. Lancet Oncol. 2016;17:519–31.
Katakami N, Uchino J, Yokoyama T, Naito T, Kondo M, Yamada K, et al. Anamorelin (ONO-7643) for the treatment of patients with non-small cell lung cancer and cachexia: results from a randomized, double-blind, placebo-controlled, multicenter study of Japanese patients (ONO-7643-04). Cancer. 2018;124:606–16.
Iwai N, Sakai H, Oka K, Sakagami J, Okuda T, Hattori C, et al. Predictors of response to anamorelin in gastrointestinal cancer patients with cachexia: a retrospective study. Support Care Cancer. 2023;31:115.
Takeda T, Sasaki T, Okamoto T, Ishitsuka T, Yamada M, Nakagawa H, et al. Impact of the extent of weight loss before Administration on the efficacy of Anamorelin in Advanced Pancreatic Cancer patients with Cachexia. Intern Med. 2023;62:1887–93.
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This study did not receive funding from any funding source.
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Conceptualization, H.F., A.M.; methodology, H.F.; formal analysis, H.F., W.D.; investigation, H.F.; data curation, H.F., A.M., K.N., C.H., K.O., and I.Y.; writing—original draft preparation, H.F.; Writing—review and editing, H.F., A.M., H.I., Y.Y., W.D., N.O., Y.T., T.T., R.K., N.M., and A.S.; supervision, A.S. All authors have read and agreed to the published version of the manuscript.
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Ethics approval and consent to participate
This retrospective study involving human participants was in accordance with the ethical standards of the institutional and national research committee and with the 1964 Helsinki Declaration and its later amendments or comparable ethical standards. Ethical approval for the study was obtained from the ethics committees of Gifu University Graduate School of Medicine (Approval number: 2021-B122).
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Competing interests
H Fujii has received honoraria for lectures from Ono Pharm., Chugai Pharm., and Taiho Pharm. H Iihara has received honoraria for lectures from Taiho Pharm., Chugai Pharma., Yakult Honsha., Astellas Pharma., Eli Lilly and Company., Daiichi Sankyo., AstraZeneca plc, Nippon Kayaku, Ono Pharm., and Nippon Boehringer Ingelheim. K Ohata has received honoraria for lectures from Chugai Pharma. and Nippon Boehringer Ingelheim. C Hirose has received honoraria for lectures from Chugai Pharma., Eli Lilly Japan and Nippon Kayaku. A Makiyama has received honoraria for lectures from Eli Lilly and Company, Taiho Pharm., and Takeda Pharma. N Matsuhashi has received honoraria for lectures from Asahi Kasei Pharma, Chugai Pharm., Covidien Japan, Daiichi Sankyo, Eli Lilly Japan, Johnson & Johnson, Kaken Pharm., Sanofi, Taiho Pharm., Takeda Pharm., and Yakult Honsha.; grants or research funds made to institution from Abbott, Asahi Kasei Pharma, Chugai Pharm., Covidien Japan, Daiichi Sankyo, Eisai, Eli Lilly Japan, EP-CRSU, EPS Corporation, FUJIFILM, Johnson & Johnson, Kaken Pharm., Kyowa Kirin, MSD, Nippon Kayaku, Ono Pharm., Otsuka Pharm., Sanofi, ShiftZero K.K., Taiho Pharm., Takeda Pharm., TERUMO, Tsumura, and Yakult Honsha. A Suzuki has received honoraria for lectures from Toa Eiyo, Asahi Kasei Pharma, Daiichi Sankyo, Pfizer Eisai, Nippon Shinyaku, Celltrion Healthcare Japan, Otsuka Pharm., Sandoz, Daiichi Sankyo, Nipro, Taiho Pharm., Asahi Kasei Pharma, Nippon Chemiphar, Japan Blood Products Organization, Takeda Pharm., and Nippon Boehringer Ingelheim.; and grants made to institution from Nippon Kayaku, Asahi Kasei Pharma, Chugai Pharm., Taiho Pharm., Daiichi Sankyo, Japan Blood Products Organization, Mochida Pharm., Sun Pharma. The other authors have no conflicts of interest.
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Fujii, H., Makiyama, A., Nishimura, K. et al. CONUT score as a predictor for anamorelin efficacy in patients with cancer cachexia receiving chemotherapy. J Pharm Health Care Sci 10, 36 (2024). https://doi.org/10.1186/s40780-024-00359-5
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DOI: https://doi.org/10.1186/s40780-024-00359-5