Artificial Neural Network as a Tool to Predict Severe Toxicity of Anticancer Drug Therapy in Patients with Gastric Cancer: A Retrospective Study

Ugljesa Stanojevic; Dmitry Petrochenko; Irina Stanoevich; Ekaterina Pismennaya

doi:10.20944/preprints202511.1609.v1

Submitted:

19 November 2025

Posted:

20 November 2025

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Abstract

Background. The aim of the study was to develop a predictive model of anticancer drug therapy toxicity in patients with gastric cancer. Methods. The retrospective study included 100 patients with stage II-IV gastric cancer who underwent 4 chemotherapy cycles. Initial significant toxicity factors included age, gender, height, body mass, body mass index, disease stage, skeletal muscle index (SMI), as well as plasma levels of trace elements (copper, zinc, selenium, manganese) and thyroid-stimulating hormone, cancer histology type and treatment regimen. The CTCAE v5.0 scale was employed to assess the severity of adverse events. Statistical analysis and building of mathematical neural network models were carried out in SPSS Statistics (v19.0). Results. Lower SMI values were associated with higher rates of toxicity-related complications of anticancer drug therapy (р< 0.05): leukopenia, hypoproteinemia, nausea, vomiting, cardiovascular events. Anemia, thrombocytopenia, hepatic cytolysis syndrome, nausea, diarrhea, constipation and stomatitis showed a weaker correlation with SMI. An increase in TSH was associated with higher rates of thrombocytopenia, nausea and vomiting. A decrease in Cu/Zn in plasma correlated with the severity of leukopenia and diarrhea, whereas Se/Mn showed an inverse correlation with the severity of anemia. Conclusion. Sarcopenia, abnormal thyroid status and imbalances in copper, zinc, selenium and manganese in blood plasma of patients with gastric cancer may be used as predictors of increased toxicity of anticancer drug therapy.

Keywords:

skeletal muscle index

;

gastric cancer

;

anticancer drug therapy

;

neural network

;

toxicity

;

oncology

Subject:

Medicine and Pharmacology - Oncology and Oncogenics

1. Introduction

Gastric cancer (GC) is a clinical entity with one of the highest prevalence and mortality rates in oncology [1,2]. Despite the decreasing prevalence of GC in developed countries, it has the fifth highest incidence among all cancers, and its cancer-specific mortality already ranks third [3,4]. While loss of appetite and weight up to cachexia are characteristic of a multitude of cancers, they are especially common in GC, reaching 57% [5]. Low muscle mass is thought to contribute to higher risks of toxicity during anticancer drug therapy [6]. Moreover, there is a robust body of evidence indicating fluctuations in trace elements during carcinogenesis, disease progression and toxicity-related complications associated with xenobiotic agents (including chemotherapy drugs). Copper, zinc, selenium and manganese are essential components of cellular antioxidation defense mechanisms and detoxification systems [7,8,9,10,11].

Anticancer drug treatment also affects the endocrine system, namely, the thyroid status, and alters the outcomes of treatment modalities associated with hormonal and metabolic shifts [12,13]. At the time of cancer detection, the majority of patients have chronic or newly diagnosed disorders of the thyroid gland, with some being incidental findings on diagnostic tests for cancer. However, thyroid gland disorders may also result from the treatment itself.

Mathematical models based on specific initial clinical signs and symptoms are widely employed to predict the course, relapses and outcomes (including death) of multiple disorders [14,15]. Current medical research often uses neural networks of various structures, such as recurrent neural networks [16,17], Kohonen self-organizing maps [18,19,20] and convolutional neural networks [21,22,23]. However, the classic example is the multilayer perceptron, a feedforward artificial multilayer network consisting of fully connected neurons [24,25]. This type of network features neurons of the previous layer linked by synapses to each neuron of the following layer [15]. Input layer neurons are fed mathematical signals describing prior medications, disease parameters, demographic data, etc. Each neuron in the input layer then forwards the data to each neuron of the hidden layer, where it is processed by a classic mathematical neuron. The process contains the following steps:

1. Each mathematical synapse is attributed a certain weight, which is multiplied by a value passing through the synapse.

2. Multiplied by the corresponding coefficients, the inputs of all the neuron synapses in the hidden layer are summed in the neuron’s adder and are represented by a single value.

3. The value obtained from the adder undergoes transformation via a series of mathematical functions to reduce it to fit a defined range.

4. The transformed and reduced to a range value of the adder is forwarded to all the neurons of the next layer of the neural network (next hidden layer or output layer) [15].

It is important to remember that initially, such a neural network is incapable of correct classification by itself; it has to be trained using a labeled dataset. The initial dataset is split into two unequal parts: the training set, accounting for 70%, and the test set, representing 30%. The former is used for neural network training itself, and the latter is used to evaluate the model’s performance, i.e., the quality of classification [15]. Thus, the information on all the objects of the training set passes through the neural network and undergoes synaptic weight correction to ensure that the number of correctly classified objects is as high as possible. Upon completion of training, the quality of classification is assessed by means of the test set [15].

The aim of this study was to develop a predictive model of anticancer drug therapy toxicity in patients with gastric cancer.

2. Materials and Methods

This retrospective study included treatment outcomes in 100 patients with locally advanced and metastatic gastric cancer who underwent chemotherapy in an inpatient department of Ostroverkhov Clinical and Research Center for Oncology (Kursk, Russia) from October 2021 to March 2023; anticancer drug therapy followed conventional chemotherapy protocols per national guidelines [26]. The decision regarding treatment was made on the basis of disease stage, Eastern Cooperative Oncology Group (ECOG) performance status, pathology report and comorbidities; FLOT was selected as neoadjuvant polychemotherapy (PCT) in resectable GC, and FOLFOX or XELOX were chosen for metastatic cancer. A thorough examination prior to treatment was carried out in an outpatient setting.

The inclusion criteria were age ≥18 years, histologically verified stage II-IV gastric cancer diagnosed for the first time, planned anticancer drug therapy for locally advanced or metastatic gastric cancer (a minimum of four cycles of platinum-based antineoplastics, taxanes and fluoropyrimidines (FLOT, FOLFOX, XELOX regimens) according to national guidelines) and a signed informed consent form.

The exclusion criteria were severe liver failure (Child-Pugh C) or renal failure (creatinine clearance less than 30 ml/min), decompensated somatic disorders, any disorders of consciousness, professional sports, pregnancy and lactation.

To measure the number of skeletal muscles and their loss rates, computed tomography was used (Discovery CT750 HD with accessories, GE Medical Systems, LLC, USA, slice thickness of 1.25 mm). Visualization tests followed the standard protocol from clinical guidelines on gastric cancer to assess potential tumor invasion and perform staging [26,27]. CT was carried out no earlier than one month prior to hospital admission and 2-3 weeks after 4 cycles of anticancer drug therapy.

The skeletal muscle index (SMI, cm²/m²) was calculated as the muscle area (cm²) in two subsequent axial sections at the level of the third lumbar vertebra (L3) divided by the patient’s height squared (m²). The threshold values for the SMI were 52.4 cm²/m² for males and 38.5 cm²/m² for females; lower SMIs were considered indicative of sarcopenia.

Plasma levels of trace elements (selenium, zinc, copper, manganese) were measured by means of mass spectrometry detection using the Varian 810-MS inductively coupled plasma mass spectrometer prior to anticancer drug therapy and after 4 chemotherapy cycles. The spectrometer provides data on signal strength at a certain level of m/z [28].

Plasma levels of thyroid-stimulating hormone (TSH) were measured with an Immulite 2000 Siemens automatic immunoassay system before radiological tests with iodine-based contrast agents or anticancer drug therapy.

The ECOG scale was used to assess patients’ overall condition, and the severity of adverse events was classified according to the National Cancer Institute Common Toxicity Criteria for Adverse Events (CTCAE v5.0) framework during anticancer drug therapy (after 4 cycles). The endpoint was any chemotherapy-induced hematological and nonhematological toxicity. Hematological toxicity included anemia (hemoglobin <130 g/l in males and <120 g/l in females), leukocytopenia (<4.0*109/l) and thrombocytopenia (<180*109/l). Nonhematological toxicity included hypoproteinemia (serum total protein less than 60 g/l), hepatic toxicity (liver enzymes (AST, ALT) 3.0 above the upper value of the normal range), nausea, vomiting, diarrhea, constipation, alopecia, hand-foot syndrome (HFS) and stomatitis (oral mucositis). Cardiovascular toxicity was assessed using the orthostatic test: all patients underwent blood pressure (BP) measurement using the Korotkov sphygmomanometer technique 5 minutes after lying still on their backs, as well as when standing 1 and 3 minutes after standing up independently. Blood pressure was measured prior to and after 4 cycles of anticancer drug therapy. Orthostatic hypotension was defined as a decrease in systolic blood pressure by 20 mm Hg (or by 30 mm Hg in patients with arterial hypertension) and/or diastolic blood pressure by at least 10 mm Hg or blood pressure below 90 mm Hg for 3 minutes after standing up. Other conditions interpreted as cardiovascular toxicity were the manifestation and/or progression of arterial hypertension, coronary heart disease, superficial and/or deep vein thrombosis in the lower extremities and venous thromboembolic events.

The mathematical models of neural networks were built and tested on the basis of data from 100 patients with GC. A total of 13 mathematical models of neural networks were built to predict blood plasma levels of hemoglobin, white blood cells, platelets and serum total protein, as well as the severity of hepatic cytolysis syndrome, nausea, vomiting, diarrhea, constipation, stomatitis, alopecia, hand-foot syndrome and dysregulation of blood pressure after 4 cycles of anticancer drug therapy. The selection of a particular neural network was made on the basis of the best potential performance in regard to predicting adverse events of anticancer drug therapy in patients with GC.

Statistical analysis of the results was carried out using the SPSS Statistics (v19.0) software package. The Shapiro–Wilk test and Kolmogorov-Smirnov test were used to check for a normal distribution of quantitative variables. To describe quantitative variables with an abnormal distribution, the median, first quartile and third quartile (Me [Q1; Q3]) were employed. The normally distributed values are represented by the mean and mean-square deviation (М±σ). Qualitative data is described as absolute values and percentages (n, %). Correlations between quantitative and ranked values were assessed using Spearman’s correlation coefficient. Quantitative variables were compared between two groups via Student's t-test. A p-value of <0.05 was chosen as the threshold for statistical significance.

3. Results

Patient data is given in Table 1. Among the 100 patients included, 76 (76.0%) were male and 24 (24.0%) were female. SMI values before treatment were indicative of sarcopenia in 92 (92.0%) patients (75 (98.7%) males and 17 (70.8%) females).

No signs of deficiency or excess of copper, zinc, selenium or manganese were detected: the trace element levels remained within normal ranges before and after 4 courses of polychemotherapy. When absolute values were analyzed, while no deviation from the normal ranges was detected, a statistically significant (p<0.05) decrease in copper and zinc levels, as well as an increase in selenium and manganese were noted by the fifth chemotherapy cycle. Statistically significant changes in the ratios of trace elements (copper/zinc, selenium/manganese, copper/manganese and selenium/zinc) were also observed after four cycles of anticancer drug therapy.

Histological examination revealed high-grade adenocarcinoma in 56 (56.0%) patients (42 (75.0%) males and 14 (25.0%) females) and low-grade adenocarcinoma in 44 (44.0%) patients (34 (77.3%) males and 10 (22.7%) females), p>0.05.

Toxicity-related complications after 4 cycles of anticancer drug therapy are outlined in Table 2. Clinically relevant peripheral polyneuropathy was not observed after 4 cycles of anticancer drug therapy because it usually manifests later, and its cumulative effects take more time to become apparent.

In 91 (91.0%) patients, toxicity during anticancer drug therapy did not warrant cessation of/pause in treatment or initial anticancer agent dose reduction; these patients were successfully managed with conventional symptomatic therapy. A pause in therapy and dose reduction were required in two patients due to thromboembolic events, grade III anemia and leukopenia, as well as in patients with grade III hand-foot syndrome. Grade IV-V toxicity was not observed during anticancer drug therapy.

Cardiovascular toxicity started developing during the first cycle of anticancer drug therapy. Arterial hypertension as a comorbidity was noted in 68 (68.0%) patients, of whom 28 patients (41%) had stopped antihypertensive treatment several months before the start of chemotherapy owing to a shift toward hypotension. Six (6.0%) patients had stable coronary artery disease. Apart from the dysregulation of blood pressure found in 38 (38.0%) patients, one patient developed coronary heart disease in the form of acute anteroseptal ST-elevation myocardial infarction after 4 cycles of chemotherapy, and one patient progressed to FC III stable angina, which necessitated more intensive treatment with antianginal agents. Moreover, there were 4 cases of acute deep vein thrombosis, one of which resulted in segmental pulmonary thromboembolism (in the left pulmonary artery).

The strength and direction of the relationship between two variables represented by Spearman’s correlation coefficient (r) are given in Table 3, Table 4, Table 5 and Table 6. TSH levels had a statistically significant moderate correlation with the severity of thrombocytopenia, nausea and vomiting after 4 cycles of anticancer drug therapy, and the SMI showed a moderate correlation with the toxic effects of chemotherapy (leukopenia, hypoproteinemia, nausea and vomiting) and an average statistically significant correlation with cardiovascular events.

A moderate inverse statistically significant correlation was revealed between the copper/zinc ratio before treatment and the severity of leukopenia after 4 chemotherapy cycles (r=-0.331; p<0.05). A weak inverse statistically significant correlation (p<0.05) was observed between the selenium/manganese ratio before treatment and anemia severity after 4 chemotherapy cycles (r=-0.211). A moderate inverse (r= -0.331) statistically significant (p<0.05) correlation was noted between the copper/zinc ratio before treatment and the severity of diarrhea after 4 chemotherapy cycles. A weak inverse statistically significant correlation (p<0.05) was detected between the copper/manganese ratio before treatment, the zinc/selenium ratio before treatment, the copper/zinc ratio after 4 cycles and the severity of diarrhea after 4 chemotherapy cycles (r= -0.206; r= -0.199; r= -0.241, respectively).

The properties of neural networks used to predict toxic complications of anticancer drug therapy in patients with gastric cancer are given in Table 7, Table 8 and Table 9.

In each model, hidden layer neurons were activated with the hyperbolic tangent activation function (for analog activation of all neurons and mapping a set of all real numbers into range sets). The output layer neurons were activated with Softmax (to normalize the network output to a probability distribution over the predicted output classes). Categorization of the training set was performed via machine learning algorithms. The percentage of correct classifications reflects the accuracy of the predictive model.

Table 10, Table 11 and Table 12 list the predictors included in the models that were selected by the neural networks during training. The predictive value of the models only reached clinically significant ranges if all the selected predictors were included.

The highest prognostic values in neural network models that predict toxic complications of anticancer drug therapy in patients with GC were shown by sex, age, height, body mass, body mass index (BMI), body surface area (BSA), functional status according to the Karnovsky scale, SMI, TSH and levels of trace elements in blood plasma (copper, zinc, selenium, manganese). Conversely, the least reliable predictors were disease stage, treatment regimen, tumor histology and type 2 diabetes mellitus.

4. Discussion

The loss of skeletal muscles is an age-related physiological process that can be exacerbated by systemic disorders, especially those that result in limited physical activity. A lower SMI is associated with higher rates of toxic complications of anticancer drug therapy, with no difference between sexes (p>0.05): leukopenia, hypoproteinemia, nausea, vomiting and cardiovascular events. While anemia, thrombocytopenia, hepatic cytolysis syndrome, nausea, diarrhea, constipation and stomatitis (oral mucositis) are notable side effects of chemotherapy, they are relatively weakly correlated with SMI, which likely stems from the small sample of patients. No differences in the histological types of GC between sexes were noted. The data obtained in the current study (including sex, age and toxicity type) corresponds to the outcomes of other trials exploring the link between sarcopenia and anticancer drug therapy toxicity [29,30,31,32,33].

TSH levels turned out to be strong predictors of adverse events associated with anticancer drug therapy. Higher TSH levels were linked to higher rates of toxicity-related complications of drug therapy, such as thrombocytopenia, nausea and vomiting. Although adequate assessment of the thyroid gland and status prior to the initiation of anticancer drug therapy is an important step toward satisfactory outcomes in patients with cancers, guidelines still fail to recommend it, with the exception of immune checkpoint inhibitors. The toxic effects of anticancer drug therapy may manifest as symptoms characteristic of hypo- or hyperthyroidism. Higher or lower basal metabolic rates, in turn, obviously impact drug metabolism. Taken together, altered thyroid status parameters may result in erroneous dosing, i.e., lowering the dose or even halting therapy altogether [12,13]. For example, signs and symptoms of hypothyroidism, such as fatigue, weakness, depression, memory loss, cold intolerance and changes in the cardiovascular system, may be falsely attributed to cancer itself or drug therapy. O.P Hamnvik et al. recommended routine checks of the functional activity of the thyroid gland in patients who receive cytotoxic agents [13]. Notably, several conventional cytostatic drugs (such as lomustine, vincristine and cisplatin) have been proven to affect the thyroid gland in vitro with no obvious clinical signs [34,35,36]. 5-Fluorouracil, a widely used anticancer agent, increases thyroxin and triiodothyronine levels, while neither changes in TSH nor clinical signs of hyperthyroidism are observed [37].

For several decades, altered levels of trace elements have been known to cause DNA/cell damage and oxidative stress, with both processes triggering malignant transformation [38,39,40,41]. Monitoring the plasma levels of copper, zinc, manganese and selenium in patients with GC who receive anticancer drug therapy has potential clinical applications. The copper and zinc levels decreased after 4 cycles of polychemotherapy, which may stem from increased demand or loss as a direct side effect of anticancer agents. Higher selenium and manganese levels after 4 cycles of chemotherapy warrant further research. This may be linked to the decreased bioavailability of these trace elements in tissues in response to polychemotherapy or changes in their metabolic rates. The obtained data revealed statistically significant correlations with hematological and gastrointestinal complications. Low ratios of trace elements (copper and zinc) were associated with severe leukopenia and diarrhea after 4 chemotherapy cycles, and lower selenium/manganese ratios showed a statistically significant correlation with increased severity of anemia. While a vast body of research has been dedicated to measuring the levels of trace elements in patients with GC in various biological samples, papers exploring the impact of imbalances in trace elements on adverse events linked to anticancer drug therapy, to the best of our knowledge, are nonexistent.

The study has several limitations which may impact the interpretation of the results. The small sample decreases the statistical significance and limits generalizability, which may lead to lower accuracy and increased sensitivity to individual differences between the participants. Moreover, the limited scale of the study does not allow for the proper evaluation of confounding factors. Further research featuring larger and more representative samples is warranted to confirm and improve the accuracy of the results.

The developed neural network models that predict the toxic effects of anticancer drug therapy in patients with GC may find their place in clinical practice. Notably, in the neural network models, the key predictors of toxicity-related complications of drug therapy were age, SMI before treatment and plasma levels of trace elements and TSH.

One of the key benefits of the developed neural network models is their ability to take objective laboratory findings and other investigations into account, which highlights the current models’ efficacy and ability to predict the toxicity of anticancer treatment. This underscores the critical value of laboratory and investigation data for model functioning, as they offer a boost in prognostic accuracy. The high accuracy of the predictions on the basis of objective parameters indicates that the developed neural network algorithms are reliable.

Neural-network-based analysis and suggested parameters yielded high-accuracy predictions of hematological toxicity and hypoproteinemia as complications of anticancer drug therapy for GC.

5. Conclusions

Sarcopenia, abnormal thyroid status and imbalances in plasma levels of trace elements in patients with gastric cancer may act as predictors of a greater severity of toxicity-related complications of anticancer drug therapy.

The results of the current work offer clear applications in clinical practice. The developed multilayer-perceptron-based mathematical models capable of predicting severe toxic effects associated with anticancer drug therapy for gastric cancer completely follow the principles of translational medicine, which strives to translate basic science and fundamental research into actual medical practice [42]. The developed mathematical models for predicting hematological toxicity and hypoproteinemia can be readily incorporated into the daily clinical practice of oncologists and chemotherapists; the models predict toxicity-related complications of anticancer drug therapy in patients with gastric cancer on the basis of clinical data, laboratory findings and investigations prior to the commencement of anticancer drug therapy.

Supplementary Materials

The following supporting information can be downloaded at the website of this paper posted on Preprints.org.

Author Contributions

Conceptualization, I.S.; methodology, D.P. and I.S.; software, D.P.; validation, U.S., D.P., I.S. and E.P.; formal analysis, D.P. and I.S.; investigation, D.P. and I.S.; resources, D.P.; data curation, D.P.; writing—original draft preparation, I.S.; writing—review and editing, U.S., D.P., I.S. and E.P.; visualization, D.P.; supervision, U.S. and E.P.; project administration, U.S. and E.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

The study was conducted in accordance with the Declaration of Helsinki, and approved by the Ethics Committee of Kursk State Medical University (protocol code 11, 26 November 2021).

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

Data is contained within the article or supplementary material.

Conflicts of Interest

The authors declare no conflicts of interest.

Abbreviations

The following abbreviations are used in this manuscript:

BMI	Body mass index
BP	Blood pressure
BSA	Body surface area
COPD	Chronic obstructive pulmonary disease
CTCAE	Common toxicity criteria for adverse events
ECOG	Eastern Cooperative Oncology Group
FC	Functional class
GC	Gastric cancer
HFS	Hand-foot syndrome
PCT	Polychemotherapy
SMI	Skeletal muscle index
TSH	Thyroid-stimulating hormone

References

Sung, H.; Ferlay, J.; Siegel, R.L.; Laversanne, M.; Soerjomataram, I.; Jemal, A.; Bray, F. Global Cancer Statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin 2021, 71, 209–249. [Google Scholar] [CrossRef]
Kaprin A.D.; Starinsky V.V.; Shakhzadova A.O. Malignancies in Russia in 2021: incidence and mortality. Moskva: Moscow, Russia, 2022.
Bollschweiler, E.; Berlth, F.; Baltin, C.; Mönig, S.; Hölscher, A.H. Treatment of early gastric cancer in the Western World. World J Gastroenterol 2014, 20, 5672–5678. [Google Scholar] [CrossRef] [PubMed]
Ang, T.L.; Fock, K.M. Clinical epidemiology of gastric cancer. Singapore Med J 2014, 55, 621–628. [Google Scholar] [CrossRef] [PubMed]
Khubutiya, M.Sh.; Popova, T.S.; Saltanov, A.I. Chapter 34. Nutritional support in patients with systemic blood diseases. In Parenteral and enteral nutrition: national guidelines; Khubutiya, M.Sh., Popova, T.S., Saltanov, A.I., Eds.; Geotar-Media: Moscow, Russia, 2014; p800. [Google Scholar]
Prado, C.M.; Baracos, V.E.; McCargar, L.J.; Mourtzakis, M.; Mulder, K.E.; Reiman, T.; Butts, C.A.; Scarfe, A.G.; Sawyer, M.B. Body composition as an independent determinant of 5-fluorouracil-based chemotherapy toxicity. Clin Cancer Res 2007, 13, 3264–3268. [Google Scholar] [CrossRef] [PubMed]
Janowska, M.; Potocka, N.; Paszek, S.; Skrzypa, M.; Wróbel, A.; Kluz, M.; Baszuk, P.; Marciniak, W.; Gronwald, J.; Lubiński, J.; Zawlik, I.; Kluz, T. An assessment of serum selenium concentration in women with endometrial cancer. Nutrients 2022, 14, 958. [Google Scholar] [CrossRef]
Song, M.; Kumaran, M.N.; Gounder, M.; Gibbon, D.G.; Nieves-Neira, W.; Vaidya, A.; Hellmann, M.; Kane, M.P.; Buckley, B.; Shih, W.; Caffrey, P.B.; Frenkel, G.D.; Rodriguez-Rodriguez, L. Phase I trial of selenium plus chemotherapy in gynecologic cancers. Gynecol Oncol 2018, 150, 478–486. [Google Scholar] [CrossRef]
Tanini, D.; Carradori, S.; Capperucci, A.; Lupori, L.; Zara, S.; Ferraroni, M.; Ghelardini, C.; Mannelli, L.; Micheli, L.; Lucarini, E.; Carta, F.; Angeli, A.; Supuran, C.T. Chalcogenides-incorporating carbonic anhydrase inhibitors concomitantly reverted oxaliplatin-induced neuropathy and enhanced antiproliferative action. Eur J Med Chem 2021, 225, 113793. [Google Scholar] [CrossRef]
To, P.K.; Do, M.H.; Cho, J.H.; Jung, C. Growth modulatory role of zinc in prostate cancer and application to cancer therapeutics. Int J Mol Sci 2020, 21, 2991. [Google Scholar] [CrossRef]
Lin, S.; Yang, H. Ovarian cancer risk according to circulating zinc and copper concentrations: A meta-analysis and Mendelian randomization study. Clin Nutr 2021, 40, 2464–2468. [Google Scholar] [CrossRef]
Hartmann, K. Thyroid disorders in the oncology patient. J. Adv. Pract. Oncol 2015, 6, 99–106. [Google Scholar] [CrossRef]
Hamnvik, O.P.; Larsen, P.R.; Marqusee, E. Thyroid dysfunction from antineoplastic agents. J Natl Cancer Inst 2011, 103, 1572–1587. [Google Scholar] [CrossRef]
Sharashova, E.E.; Kholmatova, K.K.; Gorbatova, M.A.; Grzhybovsky, A.M. Multiple logistic regression analysis in healthcare using the SPSS software package. Nauka i Zdravookhranenie 2017, 4, 5–26. [Google Scholar] [CrossRef]
Narkevich, A.N.; Vinogradov, K.A.; Paraskevopulo, K.M.; Mamedov, T.K. Intellectual techniques of data analysis in biomedical research: neural networks. Ekologiya Cheloveka 2021, 4, 55–64. [Google Scholar] [CrossRef]
Banerjee, I.; Ling, Y.; Chen, M.C.; Hasan, S.A.; Langlotz, C.P.; Moradzadeh, N.; Chapman, B.; Amrhein, T.; Mong, D.; Rubin, D.L.; Farri, O.; Lungren, M.P. Comparative effectiveness of convolutional neural network (CNN) and recurrent neural network (RNN) architectures for radiology text report classification. Artificial Intelligence in Medicine 2019, 97, 79–88. [Google Scholar] [CrossRef] [PubMed]
Rajeev, R.; Samath, J.A.; Karthikeyan, N.K. An intelligent recurrent neural network with long short-term memory (LSTM) BASED batch normalization for medical image denoising. Journal of Medical Systems 2019, 43, 234. [Google Scholar] [CrossRef] [PubMed]
Cao, C.; Wang, W.; Jiang, P. Clustering of self-organizing map identifies five distinct medulloblastoma subgroups. Cancer biomarker 2016, 16, 327–332. [Google Scholar] [CrossRef]
Kvist, T.; Voutilainen, A.; Eneh, V.; Mäntynen, R.; Vehviläinen-Julkunen, K. The self-organizing map clustered registered nurses’ evaluations of their nurse leaders. Journal of Nursing Management 2019, 27, 981–991. [Google Scholar] [CrossRef]
Van Gassen, S.; Callebaut, B.; Van Helden, M.J.; Lambrecht, B.N.; Demeester, P.; Dhaene, T.; Saeys, Y. FlowSOM: Using self-organizing maps for visualization and interpretation of cytometry data. Cytometry A 2015, 87, 636–645. [Google Scholar] [CrossRef]
Yasaka, K.; Akai, H.; Kunimatsu, A.; Kiryu, S.; Abe, O. Deep learning with convolutional neural network in radiology. Japanese Journal of Radiology 2018, 36, 257–272. [Google Scholar] [CrossRef]
Sarıgül, M.; Ozyildirim, B.M.; Avci, M. Differential convolutional neural network. Neural Networks 2019, 116, 279–287. [Google Scholar] [CrossRef]
Lee, J.G.; Jun, S.; Cho, Y.W.; Lee, H.; Kim, G.B.; Seo, J.B.; Kim, N. Deep learning in medical imaging: general overview. Korean Journal of Radiology 2017, 18, 570–584. [Google Scholar] [CrossRef] [PubMed]
Lorencin, I.; Anđelić, N.; Španjol, J.; Car, Z. Using multi-layer perceptron with Laplacian edge detector for bladder cancer diagnosis. Artificial Intelligence in Medicine 2020, 2, e101746. [Google Scholar] [CrossRef] [PubMed]
Savalia, S.; Emamian, V. Cardiac arrhythmia classification by multi-layer perceptron and convolution neural networks. Bioengineering (Basel) 2018, 5, 35. [Google Scholar] [CrossRef] [PubMed]
Clinical guidelines on gastric cancer. Available online: https://cr.minzdrav.gov.ru/view-cr/574_1 (accessed on 26 Aug 2025).
Tyurin, I.E. The gastrointestinal tract. In Computed tomography: thorax, abdomen, pelvis and musculoskeletal system; Tyurin I.E. Ed.; Geotar-Media: Moscow, Russia, 2023; p488. [Google Scholar]
Nelms, S.M. Mass spectrometers. In Inductively coupled plasma mass spectrometry handbook; Nelms S.M. Ed.; Blackwell: Hoboken, United States, 2005; p485. [Google Scholar]
Prado, C.M.; Lima, I.S.; Baracos, V.E.; Bies, R.R.; McCargar, L.J.; Reiman, T.; Mackey, J.R.; Kuzma, M.; Damaraju, V.L.; Sawyer, M.B. An exploratory study of body composition as a determinant of epirubicin pharmacokinetics and toxicity. Cancer Chemother Pharmacol 2011, 67, 93–101. [Google Scholar] [CrossRef]
Shachar, S.S.; Deal, A.M.; Weinberg, M.; Williams, G.R.; Nyrop, K.A.; Popuri, K.; Choi, S.K.; Muss, H.B. Body composition as a predictor of toxicity in patients receiving anthracycline and taxanebased chemotherapy for early-stage breast cancer. Clin Cancer Res 2017, 23, 3537–3543. [Google Scholar] [CrossRef]
Shachar, S.S.; Deal, A.M.; Weinberg, M.; Nyrop, K.A.; Williams, G.R.; Nishijima, T.F.; Benbow, J.M.; Muss, H.B. Skeletal muscle measures as predictors of toxicity, hospitalization, and survival in patients with metastatic breast cancer receiving taxane-based chemotherapy. Clin Cancer Res 2017, 23, 658–665. [Google Scholar] [CrossRef]
Barret, M.; Antoun, S.; Dalban, C.; Malka, D.; Mansourbakht, T.; Zaanan, A.; Latko, E.; Taieb, J. Sarcopenia is linked to treatment toxicity in patients with metastatic colorectal cancer. Nutr Cancer 2014, 66, 583–589. [Google Scholar] [CrossRef]
Cespedes Feliciano, E.M.; Lee, V.S.; Prado, C.M.; Meyerhardt, J.A.; Alexeeff, S.; Kroenke, C.H.; Xiao, J.; Castillo, A.L.; Caan, B.J. Muscle mass at the time of diagnosis of nonmetastatic colon cancer and early discontinuation of chemotherapy, delays, and dose reductions on adjuvant FOLFOX: the C-SCANS study. Cancer 2017, 123, 4868–4877. [Google Scholar] [CrossRef]
Sutcliffe, S.B.; Chapman, R.; Wrigley, P.F. Cyclical combination chemotherapy and thyroid function in patients with advanced Hodgkin’s disease. Med Pediatr Oncol 1981, 9, 439–448. [Google Scholar] [CrossRef]
Paulino, A.C. Hypothyroidism in children with medulloblastoma: a comparison of 3600 and 2340 cGy craniospinal radiotherapy. Int J Radiat Oncol Biol Phys 2002, 53, 543–547. [Google Scholar] [CrossRef]
Massart, C.; Le Tellier, C.; Lucas, C.; Gibassier, J.; Leclech, G.; Nicol, M. Effects of cisplatin on human thyrocytes in monolayer or follicle culture. J Mol Endocrinol 1992, 8, 243–248. [Google Scholar] [CrossRef]
Beex, L.; Ross, A.; Smals, A.; Kloppenborg, P. 5-fluorouracil-induced increase of total serum thyroxine and triiodothyronine. Cancer Treat Rep 1977, 61, 1291–1295. [Google Scholar] [PubMed]
Sohrabi, M.; Gholami, A.; Azar, M.H.; Yaghoobi, M.; Shahi, M.M.; Shirmardi, S.; Nikkhah, M.; Kohi, Z.; Salehpour, D.; Khoonsari, M.R.; Hemmasi, G.; Zamani, F.; Sohrabi, M.; Ajdarkosh, H. Trace element and heavy metal levels in colorectal cancer: comparison between cancerous and non-cancerous tissues. Biol. Trace Elem. Res 2018, 183, 1–8. [Google Scholar] [CrossRef] [PubMed]
Pasha, Q.; Malik, S.A.; Shah, M.H. Statistical analysis of trace metals in the plasma of cancer patients versus controls. J. Hazard. Mater 2008, 153, 1215–2121. [Google Scholar] [CrossRef] [PubMed]
Nordberg, M.; Nordberg, G.F. Trace element research-historical and future aspects. J. Trace Elem. Med. Biol 2016, 38, 46–52. [Google Scholar] [CrossRef]
Rainis, T.; Maor, I.; Lanir, A.; Shnizer, S.; Lavy, A. Enhanced oxidative stress and leukocyte activation in neoplastic tissues of the colon. Dig. Dis. Sci. 2007, 52, 526–530. [Google Scholar] [CrossRef]
Shlyakhto, E.V.; Konradi, S.A.; Galagudza, M.M. Translational medicine: yesterday, today, tomorrow. Vestnik Roszdravnadzora 2016, 1, 47–51. [Google Scholar]

Table 1. Clinical and demographic data of the patients (n=100) included in the study.

Parameter	Males and Females	Males	Females
Gender, absolute value (%)	-	76 (76.0%)	24 (24.0%)
Age, years М±σ, Me [Q1; Q3]	64.50±8.85	64.17±8.19	66 [63.0; 69.75]
Anthropometric data, М±σ - height, m - mass, kg - BMI, kg/m²	1.68±0.09 64.63±14.64 22.98±4.92	1.71±0.069 66.12±14.22 22.65±4.23	1.58±0.063 66.17±11.09 26.35±3.96
SMI, prior to treatment (М±σ), cm²/m² SMI, after 4 treatment cycles (М±σ), cm²/m² ΔSMI, (Me [Q1; Q3]), cm²/m²	36.21±6.86 32.31±6.34 2.39 [1.38;5.64]	38.78±6.73 34.55±6.49 3.20 [1.42;6.76]	34.69±6.59 31.79±6.64 2.28 [1.75;4.03]
Plasma levels of trace elements prior to treatment, М±σ; Me [Q1; Q3] - Copper, μg/l - Zinc, μg/l - Selenium, μg/l - Manganese, μg/l	1008.54±245.80 778.74±166.20 130.66 [110.78;152.51] 1.07 [0.90;1.36]	975.59±150.64 807.19±156.55 141.42 [115.71;148.51] 1.17 [0.91;1.28]	1104.70±270.49 773.07±140.02 134.08 [112.19;150.34] 1.13 [0.97;1.19]
Plasma levels of trace elements after 4 treatment cycles, М±σ; Me [Q1; Q3] - Copper, μg/l - Zinc, μg/l - Selenium, μg/l - Manganese, μg/l	970.18±259.11 727.20±152.62 161.78±19.23 1.14 [0.90;1.36]	941.16±264.06 743.72±157.27 162.28±15.86 1.20 [0.92;1.18]	944.29±332.16 718.95±185.09 161.53±20.43 1.37 [0.93;1.31]
TSH, μIU/ml Me [Q1; Q3]; М±σ	1.09 [0.74; 1.93]	1.63±2.70	1.82 [0.87; 2.64]
Functional status, absolute value (%) - ECOG 0 - ECOG 1 - ECOG 2	23 (23.0%) 64 (64.0%) 14 (14.0%)	18 (24.7%) 43 (58.9%) 12 (16.4%)	5 (17.9%) 21 (75.0%) 2 (7.1%)
Disease stage, absolute value (%) - I - II - III - IV	- 18 (18.0%) 43 (43.0%) 39 (39.0%)	- 13 (17.1%) 31 (40.8%) 32 (42.1%)	- 5 (20.8%) 12 (50.0%) 7 (29.2%)
T, absolute value (%) - T1 - T2 - T3 - T4	- 9 (9.0%) 60 (60.0%) 31 (31.0%)	- 5 (6.6%) 43 (56.6%) 28 (36.8%)	- 4 (16.7%) 17 (70.8%) 3 (12.5%)
N, absolute value (%) - N0 - N1 - N2 - N3	4 (4.0%) 58 (58.0%) 35 (35.0%) 3 (3.0%)	2 (2.6%) 45 (59.2%) 27 (35.6%) 2 (2.6%)	2 (8.3%) 13 (54.2%) 8 (33.3%) 1 (4.2%)
M, absolute value (%) - M0 - M1	61 (61.0%) 39 (39.0%)	44 (57.9%) 32 (42.1%)	17 (70.8%) 7 (29.2%)
Treatment regimen, absolute value (%) - FLOT - FOLFOX - XELOX	61 (61.0%) 25 (25.0%) 14 (14.0%)	44 (57.9%) 20 (26.3%) 12 (15.8%)	17 (70.8%) 5 (20.8%) 2 (8.4%)
Comorbidity, absolute value (%) - Coronary heart disease - Arterial hypertension - Type 2 diabetes - COPD, including asthma	6 (6.0%) 68 (68.0%) 6 (6.0%) 18 (18.0%)	4 (5.3%) 45 (59.2%) 4 (5.3%) 16 (21.0%)	2 (8.3%) 23 (95.8%) 2 (8.3%) 2 (8.3%)

Table 2. Toxicity after 4 cycles of anticancer drug therapy.

Toxic effect	Toxicity grade, absolute value (%)
Toxic effect	I-II	III	IV
Nausea	69 (69.0%)	6 (6.0%)	-
Vomiting	34 (34.0%)	5 (5.0%)	-
Diarrhea	48 (48.0%)	10 (10.0%)	-
Constipation	8 (8.0%)	1 (1.0%)	-
Stomatitis	13 (13.0%)	-	-
Anemia	48 (48.0%)	2 (2.0%)	-
Leukopenia	29 (29.0%)	2 (2.0%)	-
Thrombocytopenia	8 (8.0%)	-	-
Hepatic cytolysis syndrome	9 (9.0%)	-	-
Hypoproteinemia^*	26 (26.0%)
Alopecia^**	100 (100.0%)	-	-
Hand-foot syndrome	15 (15.0%)	2 (2.0%)	-
Peripheral polyneuropathy^*	-	-	-
Blood pressure dysregulation^*	38 (38.0%)
Myocardial infarction^*	1 (1.0%)
Angina^*	1 (1.0%)
Acute deep vein thrombosis^*	3 (3.0%)
Pulmonary embolism^*	1 (1.0%)

* Classification according to CTCAE is unavailable; ** Only grades I and II available for alopecia in the CTCAE framework.

Table 3. Correlation coefficients between TSH and the severity of anemia, leukopenia, thrombocytopenia, hypoproteinemia, cytolysis, nausea, vomiting, diarrhea, constipation, stomatitis, alopecia, hand-foot syndrome, polyneuropathy and blood pressure dysregulation after 4 cycles of anticancer drug therapy (statistically significant correlations are given in bold). N=100.

	Anemia	Leukopenia	Thrombocytopenia	Hypoproteinemia	Cytolysis	Nausea	Vomiting
TSH	-0.214^* .179^**	-0.104 .496	-0.344 .021	-0.014 .926	-0.018 .907	-0.335 .038	-0.304 .018
	Diarrhea	Constipation	Stomatitis	Alopecia	HFS	Polyneuropathy	BP dysregulation
TSH	-0.192 .205	-0.141 .354	-0.047 .759	-0.025 .871	-0.142 .353	-	-0.166 .275

* correlation coefficient; ** statistical significance (p-value); Interpretation of correlation coefficients: 1. Very strong (0.9<r<1.0); 2. Strong (0.7<r<0.89); 3. Average (0.5<r<0.69); 4. Moderate (0.3<r<0.49); 5. Weak (0.2<r<0.29); 6. Very weak (0.0<r<0.19).

Table 4. Correlation coefficients between SMI, trace elements and the severity of anemia, leukopenia, thrombocytopenia, hypoproteinemia and cytolysis during anticancer drug therapy (statistically significant correlations are given in bold). N=100.

	Anemia after 4 cycles of PCT	Leukopenia after 4 cycles of PCT	Thrombocytopenia after 4 cycles of PCT	Hypoproteinemia after 4 cycles of PCT	Cytolysis after 4 cycles of PCT
SMI before treatment	-.043 .712	-.205 .078	-.157 .178	-.335 .003	-.027 .817
SMI after 4 cycles	-.106 .364	-.307 .030	-.105 .371	-.297 .010	-.012 .915
Copper/ zinc before treatment	.011 .914	-.331 .046	-.088 .389	-.042 .679	-.015 .883
Selenium/ manganese before treatment	-.211 .036	-.024 .813	.046 .653	.009 .933	-.035 .733

Table 5. Correlation coefficients between SMI, trace elements and the severity of nausea, vomiting, diarrhea, constipation, stomatitis, alopecia, hand-foot syndrome and blood pressure dysregulation during anticancer drug therapy (statistically significant correlations are given in bold). N=100.

	Nausea after 4 cycles of PCT	Vomiting after 4 cycles of PCT	Diarrhea after 4 cycles of PCT	Constipation after 4 cycles of PCT	Stomatitis after 4 cycles of PCT	Alopecia after 4 cycles of PCT	HFS after 4 cycles of PCT	BP dysregulation after 4 cycles of PCT
SMI before treatment	-.294 .031	-.304 .036	-.347 .076	.119 .308	-.034 .334	-.045 .634	-.053 .834	.077 .450
Copper/ zinc before treatment	.073 .470	.079 .439	-.331 .001	-.004 .972	.056 .579	.012 .903	.043 .676	.036 .725
Copper/ manganese before treatment	.005 .964	-.049 .632	-.206 .041	-.034 .738	-.002 .981	-.108 .287	.078 .441	.038 .706
Zinc/ selenium before treatment	-.157 .120	-.076 .457	.199 .049	-.018 .862	-.036 .722	-.022 .830	-.005 .958	.034 .735
Copper/ zinc after 4 cycles of PCT	-.094 .355	.082 .417	-.241 .016	.135 .182	.053 .600	.177 .080	-.107 .292	.021 .839

Table 6. Correlation coefficients between SMI, trace elements and cardiovascular toxicity during anticancer drug therapy (statistically significant correlations are given in bold). N=100.

		Systolic blood pressure	Diastolic blood pressure	Systolic blood pressure (orthostatic test, 1 min)	Diastolic blood pressure (orthostatic test, 1 min)
SMI before treatment		0.665 0.001	.686 0.001	0.548 0.001	0.526 0.001
SMI after 4 cycles		0.634 0.001	0.548 0.001	0.664 0.001	0.567 0.001
ΔSMI		0.648 0.001	0.585 0.001	0.594 0.001	0.543 0.001
Trace elements ratios before and after 4 cycles of PCT	No statistically significant correlations were observed (p>0.05)

Table 7. Parameters of prognostic models for hemoglobin, white blood cells, platelets and total protein.

Neural network parameter	Prognostic model for
Neural network parameter	blood plasma hemoglobin	blood plasma white blood cell count	blood plasma platelet count	serum total protein
Training set, %	73	71	64	76
Test set, %	27	29	36	24
Number of neural network layers	3	3	3	3
Number of input layer neurons	23	23	23	23
Number of hidden layer neurons	3	3	3	3
Number of output layer neurons	1	1	1	1
Proportion of all correct classifications in the training set, %	98.5	92.5	91.6	94.9
Proportion of all correct classifications in the testing set, %	97.3	91.2	90.4	91.2
Area under the ROC-curve	0.974	0.910	0.913	0.917

Table 8. Parameters of prognostic models for the severity of cytolysis, nausea, vomiting, diarrhea and constipation.

Neural network parameter	Prognostic model for
Neural network parameter	cytolysis	nausea	vomiting	diarrhea	constipation
Training set, %	70	72	77.0	61.0	59.0
Test set, %	30	28	23.0	39.0	41.0
Number of neural network layers	3	3	3	3	3
Number of input layer neurons	23	23	23	23	23
Number of hidden layer neurons	3	3	3	3	3
Number of output layer neurons	2	2	2	2	2
Proportion of all correct classifications in the training set, %	84.3	59.5	46.5	65.8	66.1
Proportion of all correct classifications in the testing set, %	83.3	52.4	52.8	59.3	80.5
Area under the ROC-curve	0.842	0.675	0.641	0.716	0.675

Table 9. Parameters of prognostic models for the severity of stomatitis, alopecia, hand-foot syndrome and BP dysregulation.

Neural network parameter	Prognostic model for
Neural network parameter	stomatitis	alopecia	HFS	BP dysregulation
Training set, %	68	69	71	62
Test set, %	32	31	29	38
Number of neural network layers	3	3	3	3
Number of input layer neurons	23	23	23	23
Number of hidden layer neurons	3	3	3	3
Number of output layer neurons	2	2	2	2
Proportion of all correct classifications in the training set, %	75	87.0	83.1	66.7
Proportion of all correct classifications in the testing set, %	78.1	84.0	73.8	56.0
Area under the ROC-curve	0.739	0.854	0.821	0.579

Table 10. Contribution of predictors into prognostic models for the plasma levels of hemoglobin, white blood cells, platelets and total protein.

Predictor	Normalized weight (%)
	blood plasma hemoglobin	blood plasma white blood cell count	blood plasma platelet count	serum total protein
Gender	32.1%	11.8%	14.8%	76.3%
Age	100.0%	20.1%	98.1%	94.9%
GC stage	23.2%	20.2%	47.3%	41.1%
Treatment regimen	23.5%	20.5%	38.6%	25.1%
Height	41.2%	33.7%	42.8%	40.4%
Body mass	48.3%	35.9%	44.8%	80.0%
BMI	89.3%	100.0%	87.1%	98.9%
Karnovsky scale	85.1%	38.4%	8.9%	45.1%
BSA	39.7%	87.4%	17.4%	89.5%
Histological tumor type	5.7%	26.3%	30.9%	61.2%
Type 2 diabetes mellitus	12.6%	7.4%	8.2%	10.0%
SMI before treatment	8.1%	33.2%	74.3%	100.0%
Copper before treatment	20.1%	81.1%	85.0%	20.9%
Zinc before treatment	89.2%	48.4%	30.2%	75.5%
Selenium before treatment	81.1%	18.9%	100.0%	38.8%
Manganese before treatment	85.2%	58.9%	60.9%	15.4%
TSH before treatment	91.3%	34.3%	98.9%	41.9%

Table 11. Contribution of predictors into prognostic models for the severity of cytolysis, nausea, vomiting, diarrhea and constipation.

Predictor	Normalized weight (%)
	cytolysis	nausea	vomiting	diarrhea	constipation
Gender	8.5%	20.6%	16.2%	17.4%	13.7%
Age	65.6%	81.4%	100.0%	57.7%	31.8%
GC stage	20.8%	33.4%	21.5%	16.0%	20.7%
Treatment regimen	50.2%	25.2%	20.3%	15.3%	24.0%
Height	35.9%	85.0%	42.0%	61.5%	30.9%
Body mass	79.8%	51.2%	75.1%	100.0%	67.4%
BMI	100.0%	100.0%	38.5%	25.2%	45.7%
Karnovsky scale	70.2%	38.4%	58.9%	18.1%	98.1%
BSA	79.2%	71.8%	17.4%	19.6%	27.8%
Histological tumor type	2.8%	19.1%	18.3%	14.8%	12.3%
Type 2 diabetes mellitus	14.8%	19.9%	16.4%	7.3%	1.5%
SMI before treatment	97.5%	98.7%	24.4%	94.1%	38.6%
Copper before treatment	25.7%	53.6%	26.0%	98.2%	38.3%
Zinc before treatment	57.7%	73.0%	75.4%	57.0%	11.2%
Selenium before treatment	25.1%	79.0%	72.1%	57.4%	68.0%
Manganese before treatment	38.3%	43.2%	59.5%	16.3%	100.0%
TSH before treatment	58.5%	62.0%	58.0%	60.8%	78.5%

Table 12. Contribution of predictors into prognostic models for the severity of stomatitis, alopecia, hand-foot syndrome and blood pressure dysregulation.

Predictor	Normalized weight (%)
Predictor	stomatitis	alopecia	HFS	BP dysregulation
Gender	17.0%	34.9%	18.2%	19.3%
Age	47.5%	31.4%	28.0%	100.0%
GC stage	35.3%	34.0%	16.3%	10.8%
Treatment regimen	40.3%	32.0%	19.4%	34.8%
Height	58.9%	39.0%	7.4%	84.2%
Body mass	35.1%	100.0%	100.0%	30.8%
BMI	16.0%	97.4%	18.4%	17.8%
Karnovsky scale	80.2%	31.4%	36.9%	68.1%
BSA	78.4%	18.4%	17.4%	59.2%
Histological tumor type	16.2%	30.4%	10.6%	30.5%
Type 2 diabetes mellitus	5.7%	24.3%	10.6%	12.1%
SMI before treatment	58.4%	48.4%	7.5%	74.1%
Copper before treatment	80.1%	32.1%	17.9%	32.6%
Zinc before treatment	88.2%	37.4%	48.1%	57.0%
Selenium before treatment	57.2%	57.9%	10.5%	55.8%
Manganese before treatment	100.0%	59.7%	57.3%	7.1%
TSH before treatment	43.8%	33.3%	53.1%	78.1%

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