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Introduction

Anti-tumour chemotherapy using 5-fluorouracil (5-FU) and other cytostatics is often complicated by various disorders. Cellular damage caused by 5-FU is related to its intracellular transformation into 5-FU deoxynucleotide, which incorporates into RNA and interferes with RNA processing, and also inhibits thymidylate synthase enzyme, thereby affecting DNA synthesis and repair (1). 5-FU is effective against cancer of the digestive system (esophageal, stomach, intestinal, colon, pancreatic and liver cancer) and breast cancer (2). The toxicity of 5-FU is primarily associated with its effect on rapidly renewing tissues (those with high cellular turnover); the major dose-limiting factors are myelosuppression and damage to the gastrointestinal mucosa (3). Generation of reactive oxygen species (ROS) is the leading mechanism of the synergistic effect of polychemotherapeutic schemes incorporating 5-FU, causing disturbance of antioxidant enzymes (4), and is also one of the leading aspects in the development of mucositis (5).

An important aim of adjunct treatment in oncology patients is decreasing chemotherapy toxicity, since side effects lead to increased intervals between chemotherapy cycles or require dose reduction, and these changes have a negative effect on treatment results (6). The options for treating such disorders remain limited (7,8). Ideally, medications used to correct toxic effects should not have side effects themselves, nor should they increase or decrease treatment effectiveness. Natural plant polyphenols are promising in this regard; they protect healthy tissues, in particular decreasing production of intracellular ROS, but do not diminish the effect of chemotherapies (9). Notably, not only low-molecular weight polyphenols exhibit antioxidant efficacy, but polymeric polyphenolic compositions, such as lignin derivatives, exert it too (10).

The present study examined the effect of BP-C3 on the development of haematological and intestinal manifestations of toxicity caused by the administration of high doses of 5-FU to mice. BP-C3 is a product, which comprises lignin-derived polyphenolic composition of benzenepolycarboxylic acids (BP-Cx-1) with iron complex, selenium, ascorbic acid and retinol. BP-Cx-1, produced through high-temperature alkaline hydrolysis of lignin conducted in the presence of air oxygen with subsequent isolation and purification (11), is used for preparation of medicinal products. Antineoplastic platinum-containing investigational medicinal product, BP-C1, is used in clinical trials in patients with metastatic breast cancer (12). Investigational medicinal product, BP-C2, a composition of BP-Cx-1 with ammonium molybdate, inhibits radiation-induced skin damage in mice (13) and improves quality of life of patients with cancer treated with 5-FU-containing regimens (14). BP-C3, used in the present study, was previously demonstrated to exhibit geroprotective activity (15).

Materials and methods

Animals

A total of 105 outbred 2-month-old male Swiss-H-derived Rappolovo albino (SHR) mice were purchased from the Rappolovo Animal Facility (Rappolovo, Russia). The weight of animals at the commencement of the study was 31.0±2.2 g. Animals were maintained in a 12-h light/dark cycle at 21±2°C with 20–50% average humidity and with ad libitum access to laboratory feed (Laborotorkorm Ltd., Moscow, Russia) and tap water. Study protocols were approved by the Local Ethics Committee of the N.N. Petrov National Medical Research Center of Oncology, previously known as N.N. Petrov Research Institute of Oncology (protocol no. 1 dated 13/02/2014; Saint-Petersburg, Russia). At the end of the study, the experimental animals were euthanized by trained personnel using CO2 inhalation.

Preparations

BP-C3 is a composition developed jointly by the N.N. Petrov Research Institute of Oncology and Nobel Ltd. (Saint-Petersburg, Russia) (16). BP-C3 is comprised of polyphenolic composition BP-Cx-1 (RD Innovation ApS, Copenhagen, Denmark), iron complex, selenium, ascorbic acid and retinol. BP-C3 composition was supplied by Nobel Ltd., as a 0.5% aqueous solution. 5-FU Ebewe (Sandoz International GmbH, Holzkirchen, Germany) concentrate for solution for infusions (50 mg/ml; batch no. EW4102) was used.

Experimental design

A total of 105 male SHR mice were randomly subdivided into five groups (n=21/group). The mice in group 1, the control group, were given tap water by gavage as a placebo. The mice in groups 2, 3 and 4 were given a single intravenous injection of 5-FU (150 mg/kg), while the mice in groups 1 and 5 were injected with 0.9% saline solution on day 0). In addition, the mice in groups 3, 4, and 5 were gavaged with BP-C3 (80 mg/kg) daily except for day 0 (a total of 18 times). BP-C3 was administered on the preventative/therapeutic schedule in group 3, starting 7 days before the administration of 5-FU (day-7) and continuing through to day 11, whereas in group 4 BP-C3 was given on the therapeutic schedule, starting on day 1 and continuing through to day 18 of the experiment.

The 5-FU dose level selected for the study is known to induce anemia in mice (17) and corresponds to dose levels that patients with cancer are exposed to; for example 500 mg/m2 in CAF regimen [cyclophosphamide, doxorubicin hydrochloride (Adriamycin) and 5-FU], which corresponds to 165 mg/kg dose in mice. The selected dose level was <200 mg/kg, which is the maximum tolerated single dose used in tumour-bearing mice (18). Animals were observed once daily, including weekends.

Blood count and bone marrow nucleated cell (BMNC) assay

Blood counts were examined in samples collected on day 0 before 5-FU administration and on days 4, 7, 11, 17 and 20. Blood samples (20–40 µl) were taken from the tip of the tail and collected in test tubes (MiniCollect®; Greiner Bio-One International GmbH, Kremsmünster, Austria) containing K3EDTA. Clinical blood analysis was performed on a Mindray BC-2800Vet Hematology Analyzer (Shenzhen Mindray Bio-Medical Electronics Co., Ltd, Shenzhen, China). On days 4, 11, and 20, 5 mice from each group were euthanized, and the cellular composition of the bone marrow was quantitatively analysed in a bone marrow cell suspension prepared by mixing of 0.02 ml bone marrow aspirate with 0.4 ml of a 3% acetic acid solution. BMNCs were counted using a haemocytometer (19).

Pathomorphology studies

In mice euthanized on day 4, the morphology of crypts in the small intestine was evaluated. At autopsy, the jejunum was taken and fixed in 10% buffered formalin at room temperature for 48 h. Following fixation, 10 rings of 4–5 mm in height were dissected from each lymphoid-free intestinal sample. After routine histological processing, histological sections 4-µm thick were prepared and stained with Mayer's haematoxylin (8 min at room temperature) with subsequent differentiation and bluing and with eosin (30 sec at room temperature), dehydrated and mounted with xylene-based mounting medium. The survival of intestinal crypts was evaluated as described by Withers and Elkind (20), by counting the number of crypts (no fewer than 10 cells with basophilic nuclei lying next to each other) in at least six transverse cuts using a light microscope (Nikon Eclipse Ni-U, Nikon Corporation, Tokyo, Japan) at a magnification of ×400 with NIS-Elements Br software (version 4.30.00; Nikon Corporation).

To evaluate the organ-specific toxic effect of 5-FU, the organ/body weight ratios of the spleen, thymus, heart, liver and kidneys were determined in animals euthanized on days 4, 11 and 20. At the autopsy the organs were dissected free of adhering tissue and weighed using Sartorius Research R 160 P (Sartorius AG, Gottingen, Germany). Organ/body weight (mg) ratio was multiplied by 10 and the mean absolute organ: Body weight ratios were calculated and compared.

Statistical analysis

Data were presented as the mean ± standard error of the mean. SPSS (version 16.0; SPSS Inc., Chicago, IL, USA) was used to evaluate the data. Results were assessed by a two-way analysis of variance and Tukey's multiple comparisons test for 3–4 repeated measurements. P<0.05 was considered to indicate a statistically significant difference.

Results

Survival of animals exposed to 5-FU

Evaluating survival was not within the scope of the study; however, there was some mortality observed among the mice, indicating that 5-FU had a toxic effect (Table I). On day 7, 6 experimental animals succumbed in group 2 (the group receiving 5-FU alone). The mortality in group 2 was significantly greater than that observed in the control group (29% in group 2 vs. 0% in the control group; P<0.05; Table I). The maximum weight loss of the 6 animals that succumbed in group 2 was 3–16%. Due to this, on the same day the remaining mice were weighed and a daily weighing of animals with body weight loss >15% (6 animals in total) was introduced in the protocol. In group 3, 2 mice with 20% and 1 with 12% body weight loss found recumbent were euthanized. Additionally, 3 mice with a body weight loss of 17–20% and absent of clinical manifestations at the previous observation succumbed. In the group with preventative/therapeutic use of BP-C3 (group 3), the total dropout rate was also 29%; dropouts in group 3 occurred 1–11 days later than those in group 2. The mortality in the group with therapeutic BP-C3 regimen (commenced 24 h after 5-FU administration; group 4) was decreased to 5% (1 mouse with 17% weight loss died at day 8; P=0.093 vs. group 2; Table I). Enteritis was identified as the primary macroscopic change in all dropout animals. Adverse events may develop rapidly in mice; therefore, more frequent inspection (i.e., twice-daily) of animals receiving 5-FU at doses starting at 150 mg/kg will be introduced in future protocols.

Table I. Animal dropout rate during the experiment.

Table I.

Animal dropout rate during the experiment.

	Experiment day
Group	4	11	20	Dropout, %
1. Control	0 (5)	0 (5)	0 (11)	0
2. 5-FU	0 (5)	6a (5)	0 (5)	29c
3. ВР-С3 + 5-FU + ВР-С3	0 (5)	1a (5)	5b (5)	29c
4. 5-FU + ВР-С3	0 (5)	1a (5)	0 (10)	5d
5. ВР-С3	0 (5)	0 (5)	0 (11)	0

{ label (or @symbol) needed for fn[@id='tfn1-etm-0-0-5782'] } Data are presented as number of dropouts (number euthanized according to protocol; n=21).

a Mortality occurred despite no clinical endpoints being observed at prior inspection

b 2 mice experienced mortality and 3 animals in a recumbent state were euthanized.

c P<0.05 vs. control group (Fisher's exact test).

d P=0.093 vs. 5-FU group (Fisher's exact test). 5-FU, 5-fluorouracil; BP-C3, lignin-derived polyphenolic composition of benzenepolycarboxylic acids, iron complex, selenium, ascorbic acid and retinol.

Dynamics of body weight of the animals

The toxic effect of 5-FU was manifested by the decreased body weight of the animals (average loss of 7% as of day 4). There was no significant difference in mean body weight of animals treated with 5-FU alone, and animals treated with a combination of 5-FU and BP-C3 (Table II). Body weight loss is a general sign of toxicity and is commonly ~10% in animal studies evaluating cytostatic agents such as 5-FU (21). The maximum body weight loss registered in individual mice on day 4 was −16, −11 and −10% of the initial body weight in the 5-FU (group 2), BP-C3 + 5-FU + BP-C3 (group 3) and 5-FU + BP-C3 (group 4) groups, respectively. The average body weight loss was transient and by day 11 no statistically significant differences between the experimental groups were present.

Table II. Body weight of mice exposed to 5-FU with or without BP-C3.

Table II.

Body weight of mice exposed to 5-FU with or without BP-C3.

	Body weight in each group, g
Experiment day	1. Control	2. 5-FU	3. ВР-С3 + 5-FU + ВР-С3	4. 5-FU + ВР-С3	5. ВР-С3
0	31.66±0.49	32.45±0.38	32.01±0.48	31.89±0.34	32.27±0.46
4	32.34±0.65	30.14±0.63a,b	30.39±0.47b	30.13±0.43a,b	32.60±0.54
11	32.07±0.56	32.62±0.50	31.15±0.63	32.11±0.61	32.55±0.53
20	32.62±0.55	33.76±0.61	32.61±0.68	33.26±0.2	32.83±0.45

a P<0.05 vs. control group on the same day

b P<0.05 vs. BP-C3 group on the same day. Values are presented as the mean ± standard error of the mean. Data were analysed by a two-way analysis of variance. 5-FU, 5-fluorouracil; BP-C3, lignin-derived polyphenolic composition of benzenepolycarboxylic acids, iron complex, selenium, ascorbic acid and retinol.

Organ/body weight ratios of the animals

To evaluate the organ-specific toxic effect of 5-FU, the organ/body weight ratios of the spleen, thymus, heart, liver and kidneys were determined (Table III). The spleen and thymus were the main organs that exhibited a toxic effect in response to 5-FU. The toxic effect was demonstrated by the significant decrease of the organ/body weight ratios of these organs on day 4 post 5-FU administration compared with those observed in the control group (P<0.05). The use of BP-C3 in the therapeutic (group 4) and preventative/therapeutic (group 3) schedules was protective against the toxic effect that 5-FU exerted on the lymphopoietic organs.

Table III. The effect of BP-C3 on 5-FU-induced changes in organ/body weight ratios.

Table III.

The effect of BP-C3 on 5-FU-induced changes in organ/body weight ratios.

A, Spleen
	Organ/body weight ratio on each experiment day, mg/10 g
Group	4	11	20
1. Control	36.39±3.01	38.43±2.83	37.11±5.41
2. 5-FU	16.57±1.55a	45.10±6.66b	88.96±5.02a,c
3. ВР-С3 + 5-FU + ВР-С3	23.89±2.67	54.95±10.31b,c	95.02±2.77a,c
4. 5-FU + ВР-С3	36.31±2.00	92.92±9.81a,c	80.80±5.21a,c
5. ВР-С3	35.86±5.10	30.75±0.65	35.38±1.78
B, Thymus
	Organ/body weight ratio on each experiment day, mg/10 g
Group	4	11	20
1. Control	22.26±2.79	22.21±1.45	20.60±0.65
2. 5-FU	14.01±1.10a	18.44±2.39	20.39±1.61
3. ВР-С3 + 5-FU + ВР-С3	18.90±3.76	21.02±1.47	21.16±2.25
4. 5-FU + ВР-С3	16.21±1.06	15.88±1.23	17.16±1.21
5. ВР-С3	19.51±2.63	22.62±1.53	20.98±1.03
C, Heart
	Organ/body weight ratio on each experiment day, mg/10 g
Group	4	11	20
1. Control	66.23±8.99	66.13±6.66	64.64±3.85
2. 5-FU	63.10±4.28	52.64±2.57	56.23±1.37
3. ВР-С3 + 5-FU + ВР-С3	56.90±3.59	64.93±9.11	57.87±2.17
4. 5-FU + ВР-С3	55.12±2.57	64.24±5.31	55.82±2.73
5. ВР-С3	66.88±6.60	60.73±4.05	60.58±2.61
D, Liver
	Organ/body weight ratio on each experiment day, mg/10 g
Group	4	11	20
1. Control	594.38±54.71	605.24±46.98	541.53±19.14
2. 5-FU	475.70±13.77	472.04±26.63	509.56±26.22
3. ВР-С3 + 5-FU + ВР-С3	595.79±24.40	545.28±40.06	576.07±30.38
4. 5-FU + ВР-С3	540.68±39.11	590.89±48.13	511.19±33.71
5. ВР-С3	600.78±69.93	541.90±31.40	552.30±35.96
E, Kidney (left)
	Organ/body weight ratio on each experiment day, mg/10 g
Group	4	11	20
1. Control	83.14±7.72	89.56±8.51	77.76±3.74
2. 5-FU	88.18±8.92	80.58±6.00	69.26±6.07
3. ВР-С3 + 5-FU + ВР-С3	79.40±3.36	86.12±2.71	71.84±3.79
4. 5-FU + ВР-С3	75.43±5.35	70.95±3.74	67.10±2.97
5. ВР-С3	79.40±3.36	86.12±2.71	71.84±3.79

a P<0.05 vs. control group on the same day

b P<0.05 vs. 5-FU + BP-C3 group on the same day

c P<0.05 vs. BP-C3 group on the same day. Values are presented as the mean ± standard error of the mean. Data were analysed by a two-way analysis of variance. 5-FU, 5-fluorouracil; BP-C3, lignin-derived polyphenolic composition of benzenepolycarboxylic acids, iron complex, selenium, ascorbic acid and retinol.

Notably, by day 20 there was a significant increase in spleen weight in all groups that received 5-FU compared with that observed in the control group (P<0.05; Table IIIA). Administration of BP-C3 affected this process. By day 11 the spleen/body weight ratio in animals treated with BP-C3 on the therapeutic schedule (24 h after exposure to 5-FU) was greater than that in the animals that received BP-C3 on the preventative/therapeutic schedule. On day 20, the spleen/body weight ratio was reached the values observed in all groups where 5-FU was administered.

BP-C3 effects on 5-FU-induced hematological toxicity

The modification of the myelotoxic effect of 5-FU by co-administration of BP-C3 was evaluated (Fig. 1). The use of BP-C3 did not improve the 5-FU-induced suppression of bone marrow haematopoiesis that was observed on day 4. However, during the time that the BMNC count was recovering, there were differences in the effects of ВР-С3 used on the therapeutic and preventative/therapeutic schedules. On day 11, significantly fewer bone marrow nucleated cells were observed in group 4 compared with group 2 (P<0.05) and group 3 (P<0.01). However, on day 20 the BMNC count in group 4 was significantly greater compared with group 2 (P<0.05) and group 3 (P<0.01).

Figure 1. Changes in the bone marrow nucleated cell count in Swiss-H-derived Rappolovo albino mice exposed to 150 mg/kg 5-FU. Values are presented as the mean ± standard error of the mean. *P<0.05 and ***P<0.001 vs. the control group; ##P<0.01 vs. the BP-C3 + 5-FU + BP-C3 group; •P<0.05 and •••P<0.001 vs. the 5-FU group. 5-FU, 5-fluorouracil; BP-C3, lignin-derived polyphenolic composition of benzenepolycarboxylic acids, iron complex, selenium, ascorbic acid and retinol.

When blood counts were analysed, the following changes were noted (Table IV): Mice in groups 2, 3 and 4, which all received 5-FU, exhibited pronounced leukopenia on days 4 and 7, which changed to leukocytosis in groups 2 and 3 by days 14–17; however, this phenomenon was not reproduced in group 4. The changes in the populations of lymphocytes, granulocytes and monocytes were similar.

Table IV. The effect of BP-C3 on 5-FU-induced changes in white and red blood cell counts.

Table IV.

The effect of BP-C3 on 5-FU-induced changes in white and red blood cell counts.

A, Lymphocytes, 109/l
	Experiment day
Group	0	4	7	11	14	17	20
1. Control	5.99±0.94	6.18±0.55	8.08±0.76	6.40±0.99	6.71±0.55	6.77±1.07	5.44±0.65
2. 5-FU	5.61±0.65	2.79±0.37a,b	5.02±1.17	10.60±1.24	22.02±5.94a,b	13.54±3.50b	7.72±3.24
3. ВР-С3 + 5-FU + ВР-С3	5.96±0.69	2.90±0.48a,b	2.45±0.49a,b	7.51±1.31	16.63±3.15a–c	18.18±3.95a,b	10.06±0.97
4. 5-FU + ВР-С3	6.07±0.52	2.48±0.15a	2.52±0.38a,b	6.87±1.98	8.68±1.30	11.64±1.41	5.94±2.27
5. ВР-С3	5.61±1.03	5.82±0.75	6.50±0.59	5.70±0.81	5.43±1.47	4.10±0.65	4.03±1.19
B, Granulocytes, 109/l
	Experiment day
Group	0	4	7	11	14	17	20
1. Control	4.88±0.37	4.44±0.29	4.71±0.84	3.97±0.41	4.54±0.60	4.39±0.96	4.20±0.64
2. 5-FU	4.29±0.35	1.95±0.27a,b	0.58±0.13a,b	3.65±0.63	12.04±2.75	16.98±7.93a,b	8.74±2.09
3. ВР-С3 + 5-FU + ВР-С3	4.14±0.30	1.46±0.15a,b	0.41±0.09a,b	3.84±0.61	21.00±6.93a–c	19.54±8.25a–c	9.34±1.83
4. 5-FU + ВР-С3	4.22±0.59	1.08±0.28a,b	0.40±0.06a,b	3.68±1.17	7.58±0.85	8.44±1.00	5.44±0.87
5. ВР-С3	3.80±0.42	3.32±0.24	3.82±0.65	3.57±0.34	3.73±0.38	2.88±0.51	2.45±0.34
C, Monocytes, 109/l
	Experiment day
Group	0	4	7	11	14	17	20
1. Control	0.58±0.04	0.63±0.08	0.64±0.13	0.52±0.06	0.51±0.09	0.54±0.12	0.60±0.12
2. 5-FU	0.47±0.04	0.19±0.03a,b	0.15±0.03a,b	0.60±0.21	2.26±0.22a–c	1.58±0.36a,b	0.94±0.22
3. ВР-С3 + 5-FU + ВР-С3	0.44±0.04	0.16±0.03a,b	0.11±0.03a,b	0.79±0.11	2.37±0.39a–c	2.07±0.30a–c	1.46±0.15a–c
4. 5-FU + ВР-С3	0.38±0.07	0.12±0.04a,b	0.1±0.03a,b	0.74±0.23	1.38±0.17a,b	0.98±0.26	0.48±0.09
5. ВР-С3	0.43±0.06	0.44±0.04	0.52±0.10	0.43±0.04	0.40±0.04	0.50±0.20	0.25±0.06
D, Red blood cells, 1012/l
	Experiment day
Group	0	4	7	11	14	17	20
1. Control	10.7±0.3	10.4±0.2	10.6±0.3	10.5±0.2	9.9±0.4	10.0±0.3	9.9±0.2
2. 5-FU	11.0±0.3	10.7±0.3	8.9±0.5a–c	8.5±0.5a,b	9.5±0.3	10.2±0.4	10.5±0.4
3. ВР-С3 + 5-FU + ВР-С3	11.1±0.2	10.7±0.4	9.5±0.4	8.1±0.2a,b	8.4±0.2a,b	9.4±0.1	9.8±0.4
4. 5-FU + ВР-С3	11.4±0.3	11.4±0.3	10.5±0.4	9.4±0.8	8.8±0.3	9.5±0.2	9.2±0.3
5. ВР-С3	10.7±0.2	10.3±0.2	10.7±0.3	10.7±0.3	10.5±0.3	10.7±0.3	10.7±0.1

a P<0.05 vs. control group on the same day

b P<0.05 vs. BP-C3 group on the same day

c P<0.05 vs. 5-FU + BP-C3 group on the same day. Values are presented as the mean ± standard error of the mean. Data were analysed by a two-way analysis of variance. 5-FU, 5-fluorouracil; BP-C3, lignin-derived polyphenolic composition of benzenepolycarboxylic acids, iron complex, selenium, ascorbic acid and retinol.

The lymphocyte count on day 4 in group 2 was 55% lower than that of the control group (P<0.05; Table IVA). By day 7, the lymphocyte count in group 2 returned to a normal level. Although the lymphocyte count in group 2 was 38% lower compared with the control group on day 7, no significant difference was identified. On day 14, the lymphocyte count in group 2 was significantly increased by 228% (P<0.05) compared with the control group, followed by a decrease to the normal level by day 20. The lymphocyte count in group 3 was reduced by 53% on day 4 and by 70% on day 7 compared with the control group at the respective time points (both P<0.05), and thus this reduction lasted longer than that of group 2. On day 14 and 17 the lymphocyte count in group 3 increased significantly by 148 and 167%, respectively (P<0.05 vs. the control group). In group 4, the lymphocyte count decreased by 60% on day 4 and by 69% on day 7 (both P<0.05 vs. control group).

Contrary to groups 2 and 3, no increase in lymphocyte count was observed in group 4 at later time points (between day 14 and 20). In groups 2, 3 and 4, the granulocyte count (Table IVB) decreased by ~80% on day 4 (P<0.05 vs. the control group). The decrease in the granulocyte count of ~90% was most pronounced in groups 2, 3 and 4 on day 7 (P<0.05 vs. the control group). Differences between the groups 2, 3 and 4 were not statistically significant on day 7. At later time points, the granulocyte count significantly increased in group 2 by day 17 (P<0.05 vs. the control group), and in group 3 by day 14 and 17 (all P<0.05 vs. the control group). In group 4, no increase of the granulocyte count was observed on day 14 and 17 compared with the control group at the same time points.

The monocyte count significantly decreased on day 4 and 11 after 5-FU exposure in groups 2, 3 and 4 (all P<0.05 vs. the control group; Table IVC). At later time points, the monocyte count increased significantly on day 14 and 17 in group 2, and days 14–20 in group 3 (P<0.05 vs. the control group). In group 4, a significant increase in the monocyte count was observed only on day 14 (P<0.05 vs. the control group) and was normalised by day 17. In group 4, the recovery of leukopoiesis without a pronounced stage of enhanced haematological response can be attributed to the anti-inflammatory effect of BP-C3, likely due to a shorter pro-inflammatory response of monocytes. Administration of BP-C3 without 5-FU did not have a significant effect on white blood cell differentiation in the mice.

Mild anaemia developed in the mice in group 2 between day 7 and 11, and in group 3 between day 11 and 14 as the red blood cell count significantly decreased at those time points in the aforementioned groups (all P<0.05 vs. the control group; Table IVD). ВР-C3 was administered 24 h after 5-FU to mice in group 4, which prevented the development of anaemia in the mice. Thus, BP-C3, depending on the administration schedule, has different effects on the haematological parameters of the haematopoietic organs and the peripheral blood.

BP-C3 effects on 5-FU-induced intestinal toxicity

As one of the primary manifestations of the toxic effect of 5-FU is enteritis, the number of surviving intestinal crypts following exposure to 5-FU was evaluated. Histological examination of samples, collected on day 4 from all mice treated with 5-FU, identified the death of crypts, shortening or loss of the villi and a chronic inflammatory response in the intestinal mucosa. The counts of the surviving crypts are demonstrated in Fig. 2. The number of crypts per intestinal cross-section decreased significantly in group 2 (P<0.01 vs. the control group). By contrast, BP-C3 promoted intestinal crypt survival when administered on either the preventative/therapeutic (group 3; P<0.05 vs. group 2) or the therapeutic (group 4; P<0.01 vs. group 2) schedule. BP-C3 treatment alone (group 5) did not affect number of surviving intestinal crypts. In summary, BP-C3 protects the epithelium of the small intestine against damage induced by 5-FU.

Figure 2. Number of SICs in the small intestine of the mice on day 4 post 5-FU administration. Values are presented as mean ± standard error of the mean. **P<0.01 vs. the control; #P<0.05 and ##P<0.01 vs. 5-FU. SIC, surviving intestinal crypts; 5-FU, 5-fluorouracil; BP-C3, lignin-derived polyphenolic composition of benzenepolycarboxylic acids, iron complex, selenium, ascorbic acid and retinol.

Discussion

Substances of plant origin, polyphenols in particular, are promising chemotherapy adjuncts for several reasons. First, they have low toxicity and cause essentially no side effects, as opposed to the synthetic drugs that are currently used in clinical practice to decrease chemotherapy side effects (22). Second, various compounds in this chemical group have been demonstrated to have their own anti-tumour activity. Polyphenol compounds slow the growth of various cancer cell lines and also inhibit carcinogenesis in vivo (23–25). Various plant agents, including genistein, curcumin, epigallocatechin gallate, resveratrol and proanthocyanidin, are able to potentiate the effectiveness of traditional chemotherapeutic drugs (22).

In the cell, polyphenols bind to numerous targets, neutralise free radicals and affect numerous signalling pathways, including the epigenetic regulation of gene expression and mitochondrial function (26). Oxidative stress is one of the mechanisms of action of various anti-tumour substances; therefore, the effectiveness of chemotherapy may be modulated by substances with antioxidant properties. Some of the most common exogenous antioxidants are polyphenolic compounds, which protect us from developing cardiovascular diseases, diabetes, cancer and infectious diseases (27). Antioxidants may protect normal tissue without affecting the effectiveness of anti-tumour chemotherapeutic drugs (28,29). Paradoxically, polyphenols exert an antioxidant effect on healthy cells, while in cancer cells they increase free radicals, causing cellular aging, cell cycle arrest and apoptosis (30). In the presence of copper ions, of which there are more in cancer cells than in normal cells (31), at least some polyphenols (luteolin, apigenin, epigallocatechin-3-gallate and resveratrol) act as pro-oxidants. The anti-tumour effect of these polyphenols decreases significantly in the presence of copper chelators (32).

Polyphenols reduce toxic effects on normal tissues, thus quercetin protects normal renal tubular cells from drug toxicity and attenuates drug-induced nausea and vomiting (22). Traditional Japanese medicines have been demonstrated to protect intestinal epithelium during 5-FU use (33). Besides their direct antioxidant effect, vegetable and fruit flavonoids are able to increase the activity of detoxifying enzymes (34).

Notably, various investigational drugs are traditional medicines, also known as multi-component mixtures, and their various constituents possibly potentiate one another. For example, experiments in mice exposed to γ radiation have demonstrated that the mixtures of polyphenols of green tea were more protective than the tea's individual components (35). Although such traditional medicines are effective, lack of sufficient standardisation is their drawback.

Polyphenol substances exert anti-tumour effects through other mechanisms as well. Curcumin, a polyphenol of plant origin, has numerous molecular effects; in particular, it suppresses the transcription of nuclear factor-κB, and affects the receptors of various growth factors and cell adhesion molecules involved in tumour growth, angiogenesis and metastasis (36). Curcumin has a radioprotective or radiosensitising effect, depending on the dose, and these effects are now being actively studied to support the use of this product as an adjunct therapy for radio and chemotherapy (37). Thus, preparations that contain various polyphenols may be considered as promising adjunct therapies for oncology patients.

The use of such substances in oncology patients may improve quality of life and overall survival, particularly in palliative patients. The results of previous study on BP-C2, administered from week 2–26 in combination with a FOLFIRINOX regimen in a patient with inoperable pancreatic cancer, indicated that during treatment no neutropenia developed for 18 weeks, and blood biochemistry normalised by week 25 (14). In a long-term study performed in female SHR mice, the mean life span increased by ~50 days in animals treated with BP-C3 compared with the untreated control group (15). A greater number of tumour-free mice and delayed age-related switch-off of the oestrus function were observed, possibly due to immunomodulatory effect of BP-C3 (15).

Thus, the findings from the present study, which demonstrate the protective effects of BP-C3 on the immune system and other systems, and intestinal epithelium, are in line with and complement the results of previous studies by our group, though molecular mechanisms underlying these effects remain to be further elucidated. Future studies to assess the potential of BP-C3 in combination with certain chemotherapy agents and regimens will allow the identification of optimal combinations, doses and dosing schedules.

The experimental data of the present study extends current knowledge on the biological activity of lignin-derived polyphenolic compositions, which are a group of natural compounds. The extensive therapeutic potential of lignin-derived polyphenolic compositions is yet to be explored. The present study demonstrated the feasibility of using a lignin-derived polyphenolic composition to diminish the toxic effects of chemotherapy, in particular, to reduce the haematological and gastrointestinal adverse effects.

Acknowledgements

The present study was supported by a grant from the Russian Science Foundation (grant no. 16-15-00142 to VNA).

References