Ethological Constraints and Welfare-Related Bias in Laboratory Mice: Implications of Housing, Lighting, and Social Environment

Early evolutionary perspectives already emphasized that domestication primarily affects traits under direct or indirect human selection, such as docility, reproductive output, or morphology, while leaving much of the species-typical behavioral repertoire intact [18,19]. More recent syntheses reinforce this view, describing domestication as a syndrome involving correlated changes in stress physiology, neuroendocrine regulation, and morphology, without implying the loss of behavioral complexity or motivational systems [20,21].

In laboratory mice, selective breeding has reduced overt fear responses toward humans and altered hypothalamic–pituitary–adrenal axis reactivity in many strains. Nevertheless, core motivations related to exploration, nesting, social interaction, and environmental control remain robustly expressed across strains and experimental contexts [8,22,23,24]. Consequently, laboratory mice remain biologically prepared to respond to environmental and social cues that are often absent, distorted, or uncontrollable under standard housing conditions.

Importantly, domestication effects are strongly strain dependent. Inbred strains differ markedly in anxiety-like behavior, aggression, stress responsiveness, and coping strategies, reflecting both their mixed subspecies origins and divergent selection histories [25,26,27]. Treating laboratory mice as a behaviorally uniform population therefore obscures biologically meaningful variation and may contribute to inconsistent experimental outcomes across laboratories.

Comparative studies of wild, feral, and free-living M. musculus populations provide essential insight into which behavioral traits persist despite domestication. Field observations consistently document complex spatial organization, territoriality, dominance hierarchies, and extensive use of shelters and nests [22,28,29,30]. These features reflect core regulatory mechanisms governing stress, reproduction, and social stability rather than optional ecological embellishments.

Even under commensal conditions, wild house mice actively construct nests, regulate microclimates, and manage social stress through spatial avoidance or dispersal [24,31]. Laboratory housing, by contrast, restricts these regulatory options through spatial confinement and enforced proximity, forcing animals to cope with social and environmental challenges in fundamentally altered ways.

Comparisons with closely related species further underscore the persistence of ancestral ethological constraints. The mound-building mouse (Mus spicilegus), for example, exhibits highly specialized communal and architectural behaviors adapted to seasonal environmental stressors [32,33]. Despite ecological divergence, both M. spicilegus and M. musculus share fundamental needs for shelter, social regulation, and nocturnal activity patterns [34,35], highlighting the deep evolutionary roots of these traits.

Field studies further demonstrate substantial individual and population-level variation in aggressiveness and social tolerance, emphasizing that social behavior in mice is flexible and context dependent rather than uniform [36].

The discrepancy between conserved behavioral motivations and restricted laboratory environments can be conceptualized as an ethological mismatch. Rather than producing acute distress, such mismatch often manifests as chronic, low-level stress that alters baseline physiology and behavior over extended periods [8,37]. These effects may remain undetected by routine health monitoring yet exert profound influence on experimental outcomes.

Crucially, welfare-related bias arising from ethological mismatch is not random. Housing-induced alterations in metabolism, immune function, and emotional reactivity may systematically shift baseline phenotypes, thereby confounding experimental manipulations [5,6,7]. From this perspective, biologically impoverished environments do not simply increase variability but may actively generate structured bias that undermines reproducibility.

Recent methodological critiques have emphasized that behavioral assays conducted under ethologically inappropriate conditions may fail to measure the constructs they are intended to assess [9,13]. If baseline motivational and emotional states are altered by housing constraints, then experimental outcomes may reflect these underlying distortions rather than the effects of experimental variables of interest.

Recognizing the persistence of ethological constraints after domestication has direct implications for both animal welfare and scientific rigor. Behaviors such as nest building, social interaction, and environmental manipulation should be regarded as biologically grounded needs rather than optional enrichments [38,39]. When these needs are chronically frustrated, animals may exhibit compensatory behaviors or altered physiological states that compromise the interpretability of experimental data.

From an experimental design perspective, failure to account for ethological mismatch risks conflating treatment effects with housing-induced artifacts. Addressing these constraints through evidence-based refinement therefore represents not merely an ethical improvement but a methodological necessity for enhancing reproducibility and translational relevance [3,4].

House mice are highly social animals whose interactions are structured through dominance hierarchies, kinship, and territorial boundaries. These systems are dynamic and self-regulating: subordinate individuals can avoid dominant conspecifics through dispersal or spatial segregation, and social instability is often resolved by emigration rather than prolonged conflict [24,36]. Olfactory communication plays a central role in maintaining this balance. Urinary scent marks convey information about individual identity, dominance status, and reproductive condition, allowing mice to anticipate and avoid aggressive encounters [40,41].

Standard laboratory husbandry practices, particularly frequent cage cleaning, repeatedly disrupt these olfactory landscapes. Removal of scent marks destabilizes established social relationships and may increase aggression and anxiety-like behavior, even in otherwise stable groups [42,43]. Such disruptions are rarely acknowledged as experimental variables, despite their clear relevance for welfare and data interpretation. For this reason, it is recommended to always transfer mice to a clean cage using a portion of their used but clean nesting material to preserve olfactory cues [44].

Despite the social nature of mice, individual housing is commonly employed as a preventive measure against aggression, especially in adult males. However, a substantial body of evidence indicates that social isolation constitutes a potent and biologically meaningful stressor. Isolated mice exhibit increased anxiety-like and depressive-like behaviors, altered reward sensitivity, cognitive impairments, and dysregulated hypothalamic–pituitary–adrenal axis activity [11,45,46].

At the neurobiological level, social isolation induces long-lasting alterations in synaptic plasticity, neurotransmitter systems, and gene expression patterns associated with emotional regulation and social behavior [10,47]. Importantly, these changes may persist beyond the isolation period, effectively redefining the baseline phenotype of the animal. From an experimental standpoint, this raises a critical concern: treatment effects observed in isolated mice may reflect interactions with an isolation-induced phenotype rather than responses to the experimental manipulation itself [48].

Group housing is often presented as a welfare-friendly alternative to isolation, yet this assumption requires careful qualification in the context of male mice. Under laboratory conditions, male mice frequently exhibit elevated levels of aggression, leading to injury, wounding, or mortality [23,49]. Unlike in natural settings, subordinate individuals cannot escape or establish alternative territories, resulting in prolonged exposure to social stress.

Chronic social stress has been shown to affect immune function, metabolic regulation, and emotional behavior outcomes that are central to many biomedical research domains [50,51]. Moreover, aggression levels vary substantially across strains, age groups, and housing configurations, introducing additional variability that is rarely controlled or reported [25,52]. Chronic social stress has also been linked to immune dysregulation and altered host–microbiota interactions, suggesting that social housing conditions may indirectly affect disease-related outcomes in experimental models [50].

From a methodological perspective, social environment represents a major but frequently overlooked source of experimental variability. Differences in group composition, dominance stability, isolation history, and husbandry practices can generate divergent baseline states even within nominally identical experimental conditions [9,53]. Such variability directly undermines reproducibility by inflating within-group variance and obscuring true treatment effects.

Importantly, social stress does not merely introduce random noise. Instead, it may systematically bias results by shifting behavioral and physiological baselines in predictable directions, such as heightened anxiety or altered immune responsiveness [5,6]. Failure to account for these effects risks misattributing housing-induced phenotypes to genetic, pharmacological, or environmental manipulations.

A range of refinement strategies has been proposed to mitigate the negative effects of social housing constraints. These include maintaining stable group compositions, minimizing disruptive cage cleaning, preserving olfactory cues, and introducing environmental complexity that allows partial avoidance or retreat [42,44,48,54]. Physical modifications such as perforated partitions may permit visual and olfactory contact without direct physical interaction, reducing the severity of aggression while preserving some degree of social stimulation.

However, no single housing strategy can fully replicate the regulatory flexibility of natural social systems. Strain differences, developmental history, and experimental context all modulate outcomes, underscoring the need to treat social environment as an explicit experimental variable rather than a fixed background condition [12]. Stable social groups in laboratory settings typically consist of 2 to 5 members [52,55]. To reduce the number of singly housed animals, strategies such as the use of cage dividers or social housing of compatible males should be prioritized [56,57]. Transparent reporting and justification of social housing decisions are therefore essential for both welfare assessment and scientific interpretation.

From an ethological perspective, enrichment should be defined by its functional relevance to the animal rather than by its novelty or complexity per se. In mice, meaningful enrichment includes opportunities to hide, manipulate materials, regulate social exposure, and construct nests [39,59]. Environments lacking these opportunities may act as chronic stressors, even in the absence of overt pathology, leading to altered emotional reactivity and behavioral rigidity [8,37].

Experimental studies demonstrate that environmental complexity enables "active coping" and behavioral regulation, allowing animals to respond to aversive stimuli through behavior rather than sustained physiological stress responses [60,61]. In contrast, barren cages restrict these regulatory strategies, increasing the risk of stereotypic behavior and long-term neurobehavioral changes that directly affect experimental readouts [8]. Importantly, the welfare consequences of barren housing may accumulate over time, influencing affective state and coping capacity even in the absence of overt pathology [14,15]. Recent evidence highlights that enrichment, particularly nesting material, is a biological necessity that directly influences thermal homeostasis and overall welfare [62].

A central but frequently underestimated aspect of mouse housing is ambient temperature. Most animal facilities maintain temperatures between 20 and 24 °C, a range chosen primarily for human comfort rather than for the thermal biology of mice. This temperature range lies well below the thermoneutral zone of laboratory mice, which is estimated to be approximately 28–32 °C depending on strain, age, and activity level [63,64,65].

Housing mice under sub-thermoneutral conditions induces chronic cold stress, forcing animals to allocate metabolic resources toward heat production at the expense of growth, immune function, and disease resistance [51,66,67,68]. Importantly, this energetic burden does not necessarily manifest as overt distress, making cold stress an insidious but powerful source of welfare-related bias that can systematically affect experimental outcomes.

Nest building is a highly conserved behavior in mice, serving critical functions in thermoregulation, reproduction, and psychological security. When provided with suitable nesting material, mice reliably construct nests that create warm, stable microclimates approaching thermoneutral conditions, even in relatively cold environments [54,69,70].

Numerous studies demonstrate that mice strongly prioritize access to nesting material over many other forms of enrichment, underscoring its fundamental biological importance [71,72]. Restricting nesting opportunities should therefore be regarded as a significant welfare deficit rather than a neutral housing condition. From an experimental perspective, lack of nesting material exacerbates strain- and sex-specific responses to cold stress, increasing variability and reducing reproducibility [66,73].

The effects of enrichment cannot be evaluated independently of social housing and cage design. In group-housed mice, access to nesting material and shelters may be unevenly distributed due to dominance hierarchies, resulting in differential exposure to stress within the same cage [53,54]. Similarly, limited cage height and floor space may restrict the functional use of enrichment items, reducing their intended benefits [74,75].

These interactions complicate both welfare assessment and experimental interpretation. Enrichment strategies that improve outcomes in one strain or housing configuration may have neutral or adverse effects in another, contributing to inconsistent findings across laboratories [76]. Such context dependency highlights the importance of transparent reporting and justification of enrichment protocols.

A persistent concern in laboratory research is that environmental enrichment may increase variability and undermine experimental control. However, accumulating evidence challenges this assumption. Biologically impoverished environments may amplify variability by pushing animals into extreme or unstable physiological states, whereas controlled environmental complexity can stabilize baseline phenotypes [6,7,51].

This insight supports a shift away from rigid standardization toward biologically informed standardization, in which key ethological variables are systematically considered and documented [76]. Within this framework, enrichment, particularly nesting material, should be regarded as a tool for reducing welfare-related bias rather than as a confounding factor.

Circadian rhythms orchestrate a wide range of physiological and behavioral processes in mice, including activity patterns, hormone secretion, immune function, metabolism, and cognitive performance [78]. These rhythms are primarily entrained by light–dark cycles, with both light intensity and spectral composition playing critical roles in synchronization [79,80].

Disruption of circadian organization has been shown to induce profound and persistent changes in stress responsiveness, affective behavior, and disease susceptibility [81,82]. Importantly, circadian disruption may alter baseline phenotypes in ways that are not immediately apparent yet systematically influence experimental outcomes, particularly in behavioral and neurobiological studies.

Standard laboratory illumination levels often exceed those encountered by mice during natural nocturnal activity. Such intensities may function as chronic stressors, especially for albino strains that lack retinal pigmentation and are therefore more vulnerable to photic damage [83,84].

Excessive or inappropriate lighting has been linked to retinal degeneration, altered sleep–wake cycles, endocrine disruption, and metabolic dysregulation [81,85]. Regarding light intensity, it is also recommended to maintain levels between 15 and 25 lux at the cage level to prevent retinal damage and minimize stress, particularly for albino strains, while following standardized measurement protocols [86]. This range is sufficient for routine husbandry while preserving circadian stability [87,88]. Despite these effects, lighting conditions are frequently underreported in experimental methods, limiting reproducibility and obscuring potential sources of between-study variability.

A major yet normalized source of bias in mouse research is the routine testing of animals during their inactive (light) phase. Many behavioral and physiological assays are conducted during daytime working hours, when mice would naturally be resting. This practice disregards circadian modulation of motivation, arousal, learning, and stress responses, leading to systematic distortions in experimental readouts [89].

Empirical studies demonstrate that testing during the inactive phase can yield qualitatively different results compared to testing during the active phase, affecting measures of anxiety-like behavior, social interaction, and cognitive performance [89,90]. Such differences raise fundamental questions regarding what is actually being measured under temporally mismatched conditions.

Recent methodological critiques have explicitly questioned whether commonly used behavioral paradigms in mice measure the constructs they are assumed to assess, particularly when experiments are conducted under ethologically inappropriate temporal conditions [9,13]. Circadian mismatch may alter motivational states and coping strategies, thereby changing task engagement rather than the targeted cognitive or emotional processes.

From this perspective, poor reproducibility may arise not only from technical variability but from systematic misalignment between experimental design and the biological characteristics of the model organism [1,4,5]. Addressing circadian validity is therefore central to improving both internal and external validity in mouse-based research.

Reversed light–dark cycles, in which the dark phase is shifted to coincide with human working hours, offer a potential solution to temporal mismatch by enabling testing during the animals' natural active period. When implemented gradually and combined with appropriate control of light intensity and spectrum, reversed cycles have been shown to reduce stress responses and improve the reliability of behavioral assays [89,91].

Nevertheless, reversed light cycles are not a universal remedy. Inadequate acclimation, inappropriate light leakage during the dark phase, or failure to consider interactions with social and environmental factors may exacerbate circadian instability rather than alleviate it [13]. These limitations underscore the need for standardized reporting and evidence-based guidelines rather than ad hoc implementation.

Lighting regimes and circadian timing should be treated as integral components of experimental design rather than as background conditions. Transparent reporting of photoperiod, light intensity, spectral composition, and timing of behavioral testing is essential for reproducibility and cross-study comparison [6,7,9].

Aligning experimental timing with the natural activity patterns of mice represents a biologically grounded refinement that benefits both animal welfare and data quality. More broadly, incorporating circadian considerations reinforces the central argument of this review: that improving biological relevance through ethologically informed housing and experimental design is a prerequisite for reliable and translatable science.