1. Introduction

Environmental enrichment (EE) is an enhanced mental stimulation method that promotes stimuli, developing memory-demanding tasks due to the socio-environmental context where rodents can interact actively with their complex surroundings [1,2]. In this context, EE has been investigated in animal studies and considers several disorders, such as Alzheimer’s disease, Parkinson’s disease, stroke, and anxiety- and depression-like behaviors [3,4,5]. Therefore, EE is known to delay the rate of progression and/or reduce the symptoms and the severity of these diseases. Also, evidence has shown an enhancement in immune function due to EE, mitigating inflammatory disorders—a risk factor that predisposes to the development of chronic diseases, such as cancer [6].

Cancer consists of a complex of 200 diseases. It is known that a dysfunctional immune response and inflammation have a considerable impact on cancer development and its progression [7]. Moreover, studies have shown that adjuvant cancer treatment induces a permanent systemic inflammatory state, associated with high levels of inflammatory cytokines, and weaknesses in physical function [8]. Also, cancer treatment is often associated with psychological distress, chronic pain, cachexia, fatigue, and long-term impaired quality of life, all of which are related to a worse general picture of the disease and, consequently, a worse prognosis [9].

Recent studies have demonstrated the effect of EE protocols on different types of cancer. It has been shown that EE could decrease tumor growth in melanoma, colon, and intestinal cancers [10,11]. Recently, Queen et al. (2021) observed that EE mitigated Lewis lung carcinoma growth and promoted alterations in markers of proliferation and angiogenesis in lung carcinoma [12]. However, the impact of different EE protocols on cancer studies is still not completely clear. In this regard, this systematic review aims to evaluate the influence of EE on tumor factors in experimental models of cancer. We hypothesize that different EE protocols will be able to promote positive changes in parameters related to tumor growth and development.

2. Methods

The review followed the Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA) guidelines. This systematic review was not registered.

2.1. Study Selection and Eligibility Criteria

Eligibility criteria were previously selected to minimize the risk of bias. The inclusion and exclusion criteria followed the PICOS (Population/Intervention/Control/Outcomes/Study) strategy (Table 1). There were no restrictions on language or publication date. Articles that did not meet the following eligibility criteria were excluded: (a) studies that used only mice and rats from different species; (b) animals subjected to intervention with different protocols of environmental enrichment; (c) those without a control group; and (d) studies that did not perform a model of cancer and did not evaluate tumor parameters. Exclusions also applied to review publications, letters, duplicates, and the presence of data used in different studies.

2.2. Information Sources and Search Strategy

The search strategy was carried out during the period from December to January 2023. The databases used were PubMed (Medline), Scopus, and Embase. The search strategies used for PubMed (Medline), Embase, and Scopus were: ((“Environmental Enrichment”) OR (“Enriched Environment”)) AND ((((((Tumor) OR (Tumors)) OR (Cancer)) OR (Cancers)) OR (Neoplasm)) OR (Malignant Neoplasms)). Filters were also used in the databases: [Species, Animals, and Type of publication].

2.3. Selection and Data Collection Process

The screening of studies was performed by reading the title, abstract, and full text. The selection of studies was performed by two independent researchers (MSSF and GCJS), with discrepancies resolved by a third rater. Data were extracted by two independent researchers, and any discrepancies were resolved by a third rater (TOF), Figure 1.

2.4. Items

Data were extracted about the study (Author and year), Animal characteristics (Species, sex, age), information on the number of animals per cage; Environmental Enrichment Protocol, and Housing dimensions (Length, Width, and Depth or Height, in centimeters or meters). In addition, the exposure time of the environmental enrichment in weeks was collected. In the absence of information, data were not considered. Data were collected on cancer and tumor outcomes, including type of cancer; cancer model description; angiogenesis; tumor occurrence; tumor volume (%, cubic millimeters); tumor weight (milligrams, grams); mice with tumor and inhibition (%); and tumor size (square millimeters).

2.5. Methodological Quality Assessment

The SYRCLE’s strategy was used to assess the methodological quality of the animal studies. The tool consisted of ten questions that evaluated methodological criteria: Q1. Was the allocation sequence adequately generated and applied? Q2. Were the groups similar at baseline, or were they adjusted for confounders in the analysis? Q3. Was the allocation to the different groups adequately concealed? Q4. Were the animals randomly housed during the experiment? Q5. Were the caregivers and/or investigators blinded by the knowledge of which intervention each animal received during the experiment? Q6. Were animals selected at random for outcome assessment? Q7. Was the outcome assessor-blinded? Q8. Were incomplete outcome data adequately addressed? Q9. Are reports of the study free of selective outcome reporting? Q10. Was the study free of other problems that could result in a high risk of bias? Questions were answered with options of ‘Yes’, ‘No’, or ‘Not clear’. When the answer was ‘yes’, a score was given; when the answer was ‘no’ or ‘not clear’, no score was given. The overall scores for each article were calculated as a score of 0–10 points, with the quality of each study being classified as high (8–10), moderate (5–7), or low (<5). The two reviewers independently reviewed all the included studies. Discrepancies between evaluators were resolved by consensus. The quality outcomes are described in Table 2.

3. Results

3.1. Search Results

In an initial search, 770 articles were found, of which 346 duplicates were excluded. This was performed with the help of the EndNote software X20 version. Then, 424 articles were screened and subjected to the eligibility criteria, leading to the exclusion of 409 articles based on title and abstract reading. Fifteen studies remained for full-text reading, and of these, three studies were excluded. Finally, 12 studies were included in this systematic review (Figure 1).

3.2. Methodological Quality Assessment

The quality analysis of the studies is shown in Table 2. All studies showed adequate and randomized allocation with randomly selected animals. Furthermore, incomplete results were handled appropriately, free from selective results and bias. Because these studies involve intervention with a cancer model, it is not possible to consider the investigation and analysis of the results blindly. In general, all studies presented good quality criteria.

3.3. Study Characteristics

The included studies were published between 2010 and 2021. Regarding the characteristics of the animals, we observed that all included studies used mice of different species. Ten studies were performed exclusively with C57BL6 mice [10,12,13,14,15,16,17,20,21,22]. One study used C57BL6 and BALB/c mice [18], and another used B6C3F1 [19]. Of the included studies, eight used male mice, with ages ranging from 2 to 56 weeks. All included studies used physical and social enrichment protocols, according to the classification by Hosey and collaborators [23]. Within the characteristics of the different protocols, we observed that the number of animals per cage ranged from 4 to 25. In the objects used to establish EE, great diversity was observed (Huts; Igloos; Running Wheels; and Wood Toys, among others). The dimensions of the cages in terms of Length, Width, and Depth or Height are expressed in centimeters or meters in these variables. Finally, the duration in weeks of exposure to the EE ranged from 3 to 16 weeks (Table 3).

3.4. Types and Cancer Models

Different types of cancer were used within the included studies: breast cancer [14,16], lung cancer [12,20], pancreatic cancer model [17,22], melanoma [10,21], glioma [15], liver cancer [18], and ovarian cancer [19]. In the cancer models used in the included studies, we identified the mimicry of cancer models by injection/inoculation of cancer cells subcutaneously in nine included studies.

3.5. Tumor Volume, Weight, Size, and Angiogenesis after Environmental Enrichment

Eight included studies evaluated tumor volume, which is usually measured using the equation (Volume = length × width² × π/6) and expressed in mm³ and percentage [10,12,13,14,15,16,17,18]. The results showed that EE was able to significantly reduce tumor volume in mice with colon, melanoma, breast, glioma, pancreatic, liver, and lung cancer. Additionally, eight included studies evaluated tumor weight, expressed in milligrams, grams, and percentages. [10,12,13,16,17,18,20,22]. Seven studies demonstrated a decrease in tumor weight after EE in mice with melanoma, breast, glioma, pancreatic, liver, and lung cancer [10,12,16,17,18,20,22], while only one study did not show significant differences [13]. One study only analyzed tumor size [21] and did not observe significant differences after EE. One study only analyzed angiogenesis, showing a significant reduction after EE [13] (Table 4). Therefore, it is observed that EE was able to act positively on the oncological variables analyzed in the included studies (Figure 2).

3.6. Tumor Number, Occurrence, Inhibition, and Mice with Tumor after Different Protocols of Environmental Enrichment

One study analyzed tumor numbers and did not identify significant differences after environmental enrichment [13]. Four studies evaluated the occurrence of tumors in mice, and a significant reduction was observed after EE in melanoma, breast, liver, and lung cancer models [10,14,18,20]. On the other hand, two studies only evaluated the percentage inhibition of tumors [17,22]. In this regard, an increase in the percentage of tumor inhibition was observed after the intervention with EE. Three included studies analyzed the percentage of mice affected by tumors [10,15]. Two studies did not observe significant differences in the prevalence of tumors [13,15]. However, one study only observed a reduction in the number of tumors in mice after environmental enrichment in an ovarian cancer model [19]. Thus, it is evident that exposure to EE was able to significantly reduce the number of tumors and their occurrence, as well as increase tumor inhibition in mice (Figure 2).

4. Discussion

The findings of this systematic review qualitatively demonstrate that the implementation of EE protocols has a significant impact on multiple parameters associated with tumor growth and development. Notably, EE was found to reduce tumor volume, weight, angiogenesis, tumor cell number, occurrence, and the presence of tumors in mice. These observations have important implications for understanding the possible antitumor potential of EE. Tumor volume and weight are widely recognized as reliable indicators of tumor progression and treatment efficacy in different tumor types, including colon, breast, glioma, pancreatic, liver, and lung cancers [24]. The qualitative synthesis carried out in this systematic review suggests that EE may exert its antitumor effects through hormonal mechanisms, including a decrease in cortisol levels and the modulation of sympathetic activity. It is known that the cancer initiation process is intrinsically linked to different genetic, environmental, and psychophysiological mechanisms, including chronic stress. This is responsible for the activation of inflammatory signaling, as well as heightened activity of the neuroendocrine axis, resulting in excessive production of cortisol, which can act as a trigger for tumor growth and development [25].

Studies by Kamiya et al. (2021) [24] have highlighted the significant role of sympathetic nerves in cancer progression, particularly under conditions of stress. Evidence has shown that sympathetic nerves must innervate the tumor microenvironment, promoting cancer cell alterations and angiogenesis, while also altering immune cells’ response to the cancer environment. In this regard, experimental studies have observed that chemical and surgical sympathectomy might suppress carcinogenesis from tumor initiation and its progression [26]. Moreover, Magnon et al. (2013) found that genetic deletion of stromal β2- and β3-adrenergic receptors can prevent prostate cancer development in early phases [26]. This underscores the importance of stress management and the regulation of sympathetic pathways as potential strategies to exert antitumor effects [24]. Furthermore, the ability of EE to influence tumor volume makes it a potential tool for monitoring the effectiveness of radiotherapy, as suggested by Dubben et al. (1998) [27]. No significant differences were observed in tumor size after EE.

Angiogenesis, the formation of new blood vessels, is critical for tumor establishment and maintenance. Vascular endothelial growth factor (VEGF) has emerged as a key mediator of tumor angiogenesis, promoting tumor growth, invasion, and metastasis [28,29]. Targeting VEGF and other biological agents involved in angiogenesis has been explored as a therapeutic strategy to limit oxygen and nutrient supply to tumors [30]. In this regard, EE has been shown to reduce tumor angiogenesis, suggesting its potential as a non-pharmacological approach to inhibit this process [13]. The depletion of vessels, vessel normalization, and immune activation are potential pathways through which EE may exert its anti-angiogenic effects [31]. Queen et al. (2021) noticed that EE promoted the inhibition of mRNA expression in a variety of markers of angiogenesis, such as COX2 and VEGF genes [12]. Furthermore, EE has been found to regulate natural killer cells, demonstrating its immunoprotective role against cancer [32]. Encouraging the adoption of lifestyle factors such as EE, physical activity, and nutritional adjustments may further modulate tumor angiogenesis [33,34]. Besides the relevance that tumors exhibited alterations in angiogenesis due to EE, the mechanism by which EE promotes the inhibition of angiogenesis is unknown.

This systematic review also examined the effects of EE on tumor cell number, occurrence, inhibition, and the presence of tumors in mice. Consistent with the present findings, Di Castro et al. (2021) reported a reduction in glioma tumor cell proliferation in mice exposed to EE [35]. This effect may be mediated by a decrease in GABAergic activity in the peritumoral area [36]. The neurotransmitter GABA, derived from B cells, has been shown to promote the differentiation of monocytes into anti-inflammatory macrophages and inhibit the action of CD8+ T cells [36]. Therefore, the inactivation of GABAergic activity appears to enhance antitumor responses. Additionally, increased brain-derived neurotrophic factor (BDNF) production stimulated by EE has been linked to reduced tumor growth in gliomas. BDNF expression has also been associated with the enhanced maturation of natural killer cells in various tissues [37]. The findings of this systematic review highlight the beneficial effects of EE protocols on various parameters related to tumor growth and development. EE demonstrates the potential to reduce tumor volume, weight, angiogenesis, and tumor occurrence.

Strengths and Limitations

The present study stands out as the first systematic review to compile the impacts of EE protocols on different parameters related to tumor growth and development in experimental models of cancer. Furthermore, evidence from animal models demonstrates that non-pharmacological tools, including EE, could be used as adjuvant treatments for various types of cancer. The connection between tumor growth and development and psycho-physiological stress justifies the use of EE, which is increasingly being recognized as a low-cost, viable, reproducible, and reliable tool. It can promote voluntary stimulation of cognitive, motor, and somatosensory domains, culminating in the reduction of stress-linked signaling pathways, including the pituitary-adrenal axis, through the regulation of sympathetic nervous system activation. The synthesis of statistical data is necessary for an effective understanding of the different effects, mechanisms, and responses produced by EE in the effective regulation of tumorigenesis, with the aim of developing new therapeutic strategies. Within the limitations presented by this systematic review, we highlight the possible influence of the sex and age of the animals, as well as the low variability of the rodent species used in the included studies, which mainly used C57BL6. In future studies, we highlight the importance of making comparisons between different sexes and age groups, as well as considering a greater diversity of species, which would help us understand the impacts of EE and cancer within the diversity and individuality of each organism, leading to the observation of divergences and similarities in each regulatory mechanism of tumor development.

5. Conclusions

In conclusion, our findings strongly support the effectiveness of environmental enrichment (EE) protocols in mitigating various parameters associated with tumor growth and development. Through EE interventions, we observed significant reductions in angiogenesis, tumor occurrence, volume, weight, and the number of cells in mice with tumors. Notably, EE also demonstrated the potential to enhance tumor inhibition rates. These findings offer valuable insights into the therapeutic landscape, suggesting that incorporating EE protocols alongside conventional cancer treatments may yield substantial benefits. EE can potentially complement existing therapies by providing a non-pharmacological means to regulate tumor growth and progression. Moving forward, further research is warranted to unravel the underlying molecular mechanisms through which EE exerts its antitumor effects. Exploring these pathways will enable the development of more targeted and personalized EE interventions, enhancing their clinical efficacy and applicability in translational studies, thus better understanding the responses of environmental enrichment in different models and types of studies.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

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Figure 1. PRISMA 2020 flow diagram for new systematic reviews, which included searches of databases and registers only.

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Figure 2. Impacts of environmental variability (standard environment—arrows in red and environmental enrichment—arrows in blue) on parameters related to tumor growth and development in experimental models of cancer. ↓ Significant decrease; ↑ Significant increase.

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