Nutritional status of patients with ovarian cancer and associated factors
- Authors:
- Published online on: November 13, 2023 https://doi.org/10.3892/wasj.2023.213
- Article Number: 36
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Copyright : © Nguyen et al. This is an open access article distributed under the terms of Creative Commons Attribution License [CC BY 4.0].
Abstract
Introduction
Ovarian cancer (OC) is caused by the abnormal growth of cells formed in the ovaries. Their rapid development can lead to the destruction of healthy body tissues. In 2020, ~21,750 new cases of OC were identified, accounting for 1.2% of all cancer types (1). OC is the second most common type of malignancy affecting women >40 years of age, particularly in developing countries (2). Of note, only ~15% of OC cases are diagnosed when the disease is localized (1). Moreover, ~60% of OC cases are detected at the metastatic stage (1). This is perhaps the reason that OC is becoming the leading cause of cancer-related mortality among women with gynecological cancer worldwide (1,2). OC has been proven to be in the list of top five common cancers among women in Southeast Asian countries, including Vietnam (3). The majority of patients are diagnosed at a late stage. Therefore, the treatment of OC is a particular concern nowadays.
Malnutrition is the most common nutritional concern of patients with cancer and OC (4). In patients with OC, the metabolic effects of large tumors and intestinal obstruction lead to a poor nutritional status (5). A previous study also demonstrated that >50% of patients with OC are at risk of developing malnutrition (6). This condition negatively affects the treatment efficacy, causing pain to patients, and increasing the mortality and morbidity rates (6). In addition, the nutritional status also significantly affects the occurrence of post-operative complications (7). However, in Vietnam, the nutritional status of patients with OC has not been studied to date, at least to the best of our knowledge.
Currently, a number of methods are used to assess and screen nutrition in patients with OC. In recent years, clinicians have used the albumin-based nutrition assessment method. When the serum albumin level is <35 g/l, the patient is considered to be at risk of malnutrition (8). Serum albumin is considered an indicator for convenient and objective nutrition evaluation for clinicians. However, its specificity in nutrition assessment is controversial worldwide (9). Currently, studies using albumin levels to assess nutritional status are encouraged to verify the reliability of this approach. Moreover, an overview of the nutritional status of patients with OC through albumin levels can help healthcare professionals assess and take measures to improve the nutritional status of patients.
Therefore, the present study aimed to assess the scientific basis of the nutrition assessment method based on serum albumin levels. In addition, the present study determined the nutritional status of patients with OC and related factors based on this method.
Patients and methods
Research subjects
The medical records of patients treated for OC at K Hospital in Tan Trieu, Vietnam, from January, 2018 to December, 2021 were obtained. The present study was approved by the Institute of Genome Research Institutional Review Board, Vietnam Academy of Science and Technology, according to the decision number: 02-2022/NCHG-HĐĐĐ on March 09, 2022.
Study procedure
The present cross-sectional study was carried out between October, 2021 and June, 2022. The study was performed at K Hospital. The convenience sampling method was used for the study. All medical records of patients treated for OC at K Hospital between January, 2018 and December, 2021 were obtained. Retrospective information was collected based on the medical records of patients with OC. All written medical records of the patient were photographed. Medical records with information about the characteristics of patients, indicators of total peripheral blood cell analysis, blood biochemical indicators and electrolyte indexes were selected. The medical records of 129 patients with OC with a median age of 52 years were selected. The nutritional status of the patients with OC was divided into three stages based on serum albumin levels as follows: 36-48 g/l, normal; 21-35.9 g/l, mild and moderate malnutrition; and <21 g/l, severe malnutrition. The subclinical indicators used to identify factors affecting the nutritional status and its classification as normal and abnormal are presented in Table SI.
Statistical analysis
The data were checked, cleaned, encrypted and entered using Excel software, then processed statistically using SPSS volume 20 software (IBM Corp.). Descriptive and inferential statistical tests (Chi-squared and Fisher's exact tests) were used for data analysis. A value of P<0.05 was considered to indicate a statistically significant difference. The following principles were applied when analyzing data: i) For a description of the general nutritional status of the study subject, the nutritional status by age, self-history, family history and the stage of OC was considered. The test results of serum albumin levels at the first test after admission were used to avoid the effects of treatment interventions. ii) For the description of nutritional status at the time of pre-and post-operative testing, and the association between nutritional status and this factor, the test results of serum albumin levels were used immediately before and after surgery. iii) For determining the association between nutritional status and subclinical indicators, the serum albumin levels from all tests were used where that subclinical index was present.
Results
From the 129 patients with OC, 22 patients had mild and moderate malnutrition (17.1%). Patients <60 years of accounted for 68.2% of the study population, with a median age of 52 years. Of note, >75% of the study subjects had no comorbidities (78.3%), and the proportion of study subjects with one and two comorbidities was 19.4 and 2.3%, respectively. Only 8.5% of the total study subjects had a family history of OC. More than half of the patients had a history that could lead to a risk of developing OC and could affect their OC condition (54.3%). Subjects with allergies accounted for only 3.1% (Table I).
Of the 129 patients with OC included in the present study, information regarding the stage of OC was available for only 77 subjects. Patients with stage I and III OC accounted for the same proportion (40%) of the study population, followed by patients with stage IV OC; this subpopulation accounted for 11% of the total study population, whereas patients with stage II OC accounted for 9% of the total study population (Fig. 1).
The stage of OC and testing time were factors that were found to affect the nutritional status of patients, as determined by the serum albumin levels (P<0.01; P=0.005 and 0.003, respectively). For patients with stage III and IV OC, the rate of malnutrition was 35.9%, almost 5-fold higher than that of patients with stage I and II OC (7.9%). As regards the time of testing, post-operative malnutrition accounted for 56.2%, >2-fold higher than the pre-operative malnutrition rate (Table II).
Indicators, including red blood cell count, hemoglobin levels, hematocrit, white blood cell count, neutrophil and lymphocyte percentage, neutrophil, lymphocyte, monocyte and platelet count were found to significantly affect the nutritional status of patients (P<0.05). In particular, the malnutrition rate was higher when the levels of these indicators were abnormal (Table III).
 | Table IIIAssociation between indicators of total peripheral blood cell analysis and the nutritional status of patients with ovarian cancer. |
The creatinine and glucose levels were also found to significantly affect the nutritional status of patients (P<0.01). The malnutrition rate was higher when the levels of these indicators were abnormal (48.1 and 59.3% compared with 22.6 and 15.3%) (Table IV).
| Table IVAssociation between blood biochemical indicators and the nutritional status of patients with ovarian cancer. |
It was also found that electrolyte indices, including Na+, K+, Cl- and total calcium levels, were significantly associated with the malnutrition status (P<0.05). In particular, the malnutrition rate was higher when the levels of these indicators were abnormal (Table V).
Discussion
The present cross-sectional study of 129 patients with OC found that 17.1% were malnourished using an albumin-based nutrition assessment method. This ratio appears to be low when compared to the study of Le NTA et al (70.3%) (10). The different research subjects used may be the cause for this disparity. The present study was conducted only on patients with OC and small sample sizes. By contrast, the study of Le NTA et al (70.3%) was conducted on a larger sample size with a variety of cancer types. In particular, weight loss and malnutrition rates were obtained for patients with liver, stomach, mouth, pharyngeal and tonsil cancer. Therefore, the rate of malnutrition was higher than the one obtained in the present study.
In the present study, the malnutrition rate of the patients aged ≥60 years was >2-fold higher than that patients <60 years of age, although this difference was not statistically significant (P>0.05). Older patients often experience physiological aging associated with changes that render them more susceptible to nutritional risks (11). They often suffer from a number of diseases, such as high blood pressure, diabetes, dental deterioration, issues related to memory loss, etc., along with the weakening of the digestive system, which makes the ability to tolerate nutrients. Furthermore, the presence of OC cells leads to the metabolic effects of tumor enlargement and intestinal obstruction, which aggravate malnutrition (5).
In the present study, patients with stage III and IV OC were found to have a 5-fold higher malnutrition rate than patients with stage I and II OC (P=0.005). This is true of the current understanding of OC. The majority of research often focuses on studying the nutritional status and improvement measures in patients with late-stage OC than those with early-stage OC (12,13). In the early stages of the disease, symptoms and physical changes are often unclear. However, changes in the body's condition are strongly manifested when the disease progresses to the late stages. The rapid growth and spread of tumors lead to metabolic disturbances in the body due to a greater anabolism than catabolism (14). Furthermore, patients in the terminal stage are prone to malignant bowel obstruction and gastrointestinal metastases accompanied by tumor expansion, leading to mechanical obstruction of the gastrointestinal tract, placing the patient at high risk of falling into a state of exhaustion (14). It was demonstrated that using serum albumin levels for nutritional assessment can also yield results similar to current knowledge. Assessing the nutritional status through serum albumin levels is thus reliable.
In the present study, albumin levels were used to measure the nutritional status. However, other factors, such as inflammation, liver function and hydration status have been considered to influence albumin levels. On the other hand, these factors can exhibit major variations before and after surgery. Therefore, the present study demonstrated the albumin levels before or after surgery to partially shed light on this matter. The results revealed that the rate of post-operative malnutrition accounted for 56.2%, which was >2-fold higher than the pre-operative malnutrition rate. This indicates that the albumin level was significantly decreased following surgery. The leading causes of a sharp decrease in albumin levels following surgery include hypoalbuminemia immediately before surgery, blood loss or blood dilution, and a systemic inflammatory response. This result is similar to that of the study of Motamed et al (15); following surgery for breast cancer, the serum albumin levels were shown to be reduced by 40% compared to those prior to surgery. Post-operative low serum albumin levels have been found to be significantly associated with mortality within the first 6 months post-operatively, as well as with poor peri-operative outcomes (hospital length of stay is longer; other complications after surgery), particularly for patients with late-stage OC (16).
In the present study, indicators related to erythrocytes, including red blood cell count, hemoglobin, and hematocrit levels, were found to significantly influence malnutrition, as determined using serum albumin levels (P=0.001, 0.003 and 0.001, respectively). When the levels of these indicators are abnormal, the rate of malnutrition increases. These are specific indicators which can be used to determine anemia or the hemoconcentration in patients. An increased red blood cell count indicates hemoconcentration or polycythemia, while a decreased red blood cell count is associated with hemodilution. The amount of hemoglobin is the most characteristic indicator of anemia; it is a relatively reliable and accurate baseline indicator. Red blood cell volume or hematocrit levels are valuable in assessing and monitoring anemia. Decreased serum albumin levels may result from hemoconcentration, hemodilution, or anemia. Therefore, any abnormality in the red blood cell count, hemoglobin and hematocrit levels can cause a decrease in serum albumin levels. This suggests that the prevalence of malnutrition is determined by serum albumin levels, which influence red blood cell count, hemoglobin and hematocrit indices. Furthermore, iron- or zinc-deficiency anemia cases are considered to be related to the body's undernutrition. Therefore, diets and interventions to improve these indicators are essential to avoid the depletion of patients with OC and harmful post-operative complications.
In the present study, the white blood cell counts, neutrophil percentage, lymphocyte percentage, neutrophils count, lymphocyte count and monocyte count also yielded similar results (all, P<0.001; monocyte count, P=0.008). The increased white blood cell count can be caused by inflammation; the decreased white blood cell count is related to a lack of nutrients, such as vitamin B12. Neutrophils are also elevated in cancer infections. Monocytes are increased in infections, anemia due to bone marrow failure, cancer, etc. Therefore, it is reasonable that these indicators are related to the nutritional status, as determined by serum albumin levels. Inflammatory reactions that occur will cause the potent inhibition of organ protein synthesis, leading to malnutrition (9). Anemia for a number of days is also the cause of exhaustion and reduced nutrition in the body. Abnormal lymphocyte counts are associated with cancer and infections. The lymphocyte percentage and lymphocyte count are also used to assess and predict the nutritional status of patients. Low lymphocyte counts are used to assess and predict the risk of malnutrition (17). Moreover, herein, anomalies in creatinine and glucose levels also led to a significant increase in malnutrition rates (P<0.001). Creatinine is also considered a sign of malnutrition due to creatinine levels being an indicator of musculoskeletal rotation (9). Typically, creatinine levels decrease in cases of low muscle mass (18). The cause of low muscle mass in the body is malnutrition (19). Therefore, malnutrition can lead to a low muscle mass status and low creatinine levels. In addition, glucose is the body's leading energy supplier. Poor metabolism and glucose absorption cause abnormalities in blood glucose levels that lead to a lack of energy and malnutrition. Excessive blood glucose levels can lead to organ damage, such as the liver, kidneys, etc (20). Albumin production in the liver is also then disrupted, leading to a decrease in levels (21). In the present study, electrolyte indices including Na+, K+, Cl- and total calcium were all significantly associated with malnutrition, as determined using the serum albumin levels. Disorders in the indicators of electrolytes are often related to damage to the liver and kidneys. In particular, dyskalemia may be caused by malabsorption. As is known, the liver is the site of albumin synthesis; thus, when the liver and kidney function is damaged, this leads to a decrease in albumin synthesis, resulting in low serum albumin levels (22). It is responsible for the higher prevalence of malnutrition as determined by higher serum albumin levels. In addition, poor absorption also directly affects the patient's nutritional status (23). Patients with late-stage OC also suffer from intestinal obstruction and tumors compressing the digestive tract, lead to an even more severe condition (24). These results suggest that a nutritional assessment based on serum albumin levels may still be reliable. However, it can be combined with other methods to determine the accuracy.
The present study had certain limitations which should be mentioned. Firstly, data availability was one of the limitations. The data collected was from written medical records; thus, only information on the characteristics of patients, indicators of total peripheral blood cell analysis, blood biochemical indicators and electrolyte indices was only collected. In addition, some old medical records from 2018 to 2019 had been torn and information was lost; thus, some medical records were incomplete. Therefore, during the analysis, the research object was divided into a number of subgroups. In addition, the collection of patient medical records in the period from 2018-2021 was a volatile period due to the impact of COVID-19. Therefore, the present study had a small sample size. Finally, studies in Vietnam on the nutritional status of cancer patients mainly focus on stomach and esophageal cancers; studies on OC often focus on understanding the influence of genes on patients; thus, it is difficult to compare the study results.
In conclusion, in the present study, of the 129 study subjects, malnutrition or the risk of malnutrition accounted for a low rate (17.1%). In particular, the malnutrition rate in the group aged ≥60 years, in patients with stage III and IV OC, and the post-operative malnutrition rate was markedly higher compared the other groups (2.1-, 4.5- and 2.2-fold higher than the other groups, respectively). Patients with stage III and IV OC and the post-operative time point, were significantly associated with an increased prevalence of malnutrition (P=0.005 and 0.003, respectively). Some subclinical indicators were also significantly related to the nutritional status of patients with OC. The lymphocyte counts and hematocrit levels were prominent indicators significantly related to the increased rate of malnutrition of the study subjects when levels were abnormal (61.7 vs. 6 vs. 19.5%). This evidence may help healthcare professionals improve the nutritional status of patients with OC, as well as provide evidence for the use of serum albumin to assess the nutritional status. The findings presented herein may provide the basis for future studies on the nutritional status of patients with OC and the reliability testing of nutritional assessment methods by serum blood albumin.
Supplementary Material
Subclinical index variables used in the study.
Acknowledgements
The authors would like to thank all members of the Center for Biomedicine and Community Health for assisting with data collection and for helping to improve the manuscript. The present study also appears as a part of the thesis of TLN to obtain an undergraduate degree at Hanoi Medical University (Hanoi, Vietnam) under the supervision of DTC and NKD.
Funding
Funding: The present study was funded by Vietnam National University, Hanoi (VNU) under the project ‘Researching on some clinical, non-clinical, and epidemiological characteristics, and genetic mutation and expression in Vietnamese patients with ovarian cancer’ no. 776/QĐ-ĐHQGHN on March 26, 2021.
Availability of data and materials
The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.
Authors' contributions
DTC and LTN conceived and designed the study. THNT and BPV provided the medical records of the patients. All authors collected the patient data. LTN and HVT analyzed the data. DTC, LTN and HVT drafted the manuscript. DTC and HVT revised and edited the manuscript. DTC, NKD and BPV supervised the study. THNT, BPV and LTN confirm the authenticity of all the raw data. All authors have read and agreed to the published version of the manuscript.
Ethics approval
The present study was approved by the Institute of Genome Research Institutional Review Board, Vietnam Academy of Science and Technology according to the decision number: 02-2022/NCHG-HĐĐĐ on March 09, 2022.
Patient consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
References
|
Arora T, Mullangi S and Lekkala MR: Ovarian Cancer. In: StatPearls. StatPearls Publishing, Treasure Island, FL, 2021. | |
|
Stewart C, Ralyea C and Lockwood S: Ovarian cancer: An integrated review. Semin Oncol Nurs. 35:151–156. 2019.PubMed/NCBI View Article : Google Scholar | |
|
Ferlay J, Ervik M, Lam F, Colombet M, Mery L, Piñeros M, Znaor A, Soerjomataram I and Bray F: (2020). Global Cancer Observatory: Cancer Today. Lyon, France: International Agency for Research on Cancer. Available from: https://gco.iarc.fr/today. | |
|
Hertlein L, Kirschenhofer A, Fürst S, Beer D, Göß C, Lenhard M, Friese K, Burges A and Rittler P: Malnutrition and clinical outcome in gynecologic patients. Eur J Obstet Gynecol Reprod Biol. 174:137–140. 2014.PubMed/NCBI View Article : Google Scholar | |
|
Gadducci A, Cosio S, Fanucchi A and Genazzani AR: Malnutrition and cachexia in ovarian cancer patients: Pathophysiology and management. Anticancer Res. 21:2941–2947. 2001.PubMed/NCBI | |
|
Balogun N, Forbes A, Widschwendter M and Lanceley A: Noninvasive nutritional management of ovarian cancer patients: Beyond intestinal obstruction. Int J Gynecol Cancer. 22:1089–1095. 2012.PubMed/NCBI View Article : Google Scholar | |
|
Rinninella E, Fagotti A, Cintoni M, Raoul P, Scaletta G, Quagliozzi L, Miggiano GAD, Scambia G, Gasbarrini A and Mele MC: Nutritional interventions to improve clinical outcomes in ovarian cancer: A systematic review of randomized controlled trials. Nutrients. 11(E1404)2019.PubMed/NCBI View Article : Google Scholar | |
|
Bretscher C, Boesiger F, Kaegi-Braun N, Hersberger L, Lobo DN, Evans DC, Tribolet P, Gomes F, Hoess C, Pavlicek V, et al: Admission serum albumin concentrations and response to nutritional therapy in hospitalised patients at malnutrition risk: Secondary analysis of a randomised clinical trial. EClinicalMedicine. 45(101301)2022.PubMed/NCBI View Article : Google Scholar | |
|
Keller U: Nutritional laboratory markers in malnutrition. J Clin Med. 8(775)2019.PubMed/NCBI View Article : Google Scholar | |
|
Le Thi Ngoc A, Duong Thi H, Nguyen Van T and Pham Cong T: Nutritional status of inpatient cancer patients in hospital through somel assessment methods. Vietnam Med J. 504:228–232. . | |
|
Drevet S and Gavazzi G: Undernutrition of the elderly. Rev Med Interne. 40:664–669. 2019.PubMed/NCBI View Article : Google Scholar : (In French). | |
|
Yim GW, Eoh KJ, Kim SW, Nam EJ and Kim YT: Malnutrition identified by the nutritional risk index and poor prognosis in advanced epithelial ovarian carcinoma. Nutr Cancer. 68:772–779. 2016.PubMed/NCBI View Article : Google Scholar | |
|
Yan X, Zhang S, Jia J, Yang J, Song Y and Duan H: Exploring the malnutrition status and impact of total parenteral nutrition on the outcome of patients with advanced stage ovarian cancer. BMC Cancer. 21(799)2021.PubMed/NCBI View Article : Google Scholar | |
|
Mu J, Wu Y, Jiang C, Cai L, Li D and Cao J: Progress in applicability of scoring systems based on nutritional and inflammatory parameters for ovarian cancer. Front Nutr. 9(809091)2022.PubMed/NCBI View Article : Google Scholar | |
|
Motamed C, Mariani L, Suria S and Weil G: Serum albumin kinetics in major ovarian, gastrointestinal, and cervico facial cancer surgery. Int J Environ Res Public Health. 19(3394)2022.PubMed/NCBI View Article : Google Scholar | |
|
Kumar A, Torres ML, Cliby WA, Kalli KR, Bogani G, Aletti G, Nitschmann CC, Multinu F, Weaver AL, Block MS and Mariani A: Inflammatory and nutritional serum markers as predictors of peri-operative morbidity and survival in ovarian cancer. Anticancer Res. 37:3673–3677. 2017.PubMed/NCBI View Article : Google Scholar | |
|
Rocha NP and Fortes RC: Total lymphocyte count and serum albumin as predictors of nutritional risk in surgical patients. Arq Bras Cir Dig. 28:193–196. 2015.PubMed/NCBI View Article : Google Scholar | |
|
Ostermann M, Kashani K and Forni LG: The two sides of creatinine: Both as bad as each other? J Thorac Dis. 8:E628–E630. 2016.PubMed/NCBI View Article : Google Scholar | |
|
Deutz NEP, Ashurst I, Ballesteros MD, Bear DE, Cruz-Jentoft AJ, Genton L, Landi F, Laviano A, Norman K and Prado CM: The underappreciated role of low muscle mass in the management of malnutrition. J Am Med Dir Assoc. 20:22–27. 2019.PubMed/NCBI View Article : Google Scholar | |
|
Mohamed J, Nazratun Nafizah AH, Zariyantey AH and Budin SB: Mechanisms of diabetes-induced liver damage: The role of oxidative stress and inflammation. Sultan Qaboos Univ Med J. 16:e132–e141. 2016.PubMed/NCBI View Article : Google Scholar | |
|
Hantzidiamantis PJ and Lappin SL: Physiology, Glucose. In: StatPearls [Internet]. Treasure Island, FL: StatPearls Publishing, 2023. | |
|
Shrimanker I and Bhattarai S: Electrolytes. In: StatPearls [Internet] Treasure Island, FL: StatPearls Publishing, 2023. | |
|
Saunders J and Smith T: Malnutrition: Causes and consequences. Clin Med (Lond). 10:624–627. 2010.PubMed/NCBI View Article : Google Scholar | |
|
Gonzalez-Ochoa E, Alqaisi HA, Bhat G, Jivraj N and Lheureux S: Inoperable bowel obstruction in ovarian cancer: Prevalence, impact and management challenges. Int J Womens Health. 14:1849–1862. 2022.PubMed/NCBI View Article : Google Scholar |
