This study provides a novel insight into how MEE contributes to cognitive improvement in the early-onset AD model, the APP/PS1 mice [19, 55]. Our findings indicate that an MEE reduces astrocyte activity and ApoE biosynthesis, which may lower the brain's low-density lipoprotein (LDL) cholesterol levels. Also, consistent with a previously reported inverse correlation between ApoE and LRP1 expression [56], we observed increased LRP1 protein levels in the brains of ethanol-exposed presymptomatic APP/PS1 mice.
It is worth noting that our initial hypothesis was that a short (binge-like) and naturalistic ethanol exposure might exacerbate AD pathology. However, our findings contradict our initial hypothesis. Although excessive drinking often refers to more than 4 drinks per day for women and more than 5 drinks per day for men [57], moderate alcohol consumption has been reported to provide some health benefits, especially cardiovascular health [58]. Keeping these in mind (4–6), it is still an open question how to define "moderate" or "non-hazardous" drinking. In our study, contrasting to our previous [35] or other studies [59], we chose to expose mice to vaporized alcohol for 4 h per day without using pyrazole, an inhibitor of alcohol dehydrogenase (ADH), which naturally and slowly increases BAC to approximately 170 mg/dl. Although 170 mg/dl is not typically a moderate dose of alcohol, we consider this as a moderate dose because of relatively short alcohol exposure and ten times faster heart rate in mice compared to humans [60]. As we reported [35], longer (16 h per day, 4 days per week, 4 weeks) daily ethanol exposures in the vapor chamber may worsen the AD-like pathology in APP/PS1 mice.
In the presymptomatic group, MEE reduced Aβ plaque count and levels, with a corresponding improvement in cognitive function. This suggests that moderate alcohol consumption could mitigate neuronal loss and improve cognitive function in early disease stages. Importantly, we found that MEE has no effect on presymptomatic NTG mice nor symptomatic APP/PS1 mice (Fig. S13 and Fig. S14), suggesting that MEE normalizes AD-like cognitive function in only presymptomatic APP/PS1 mice. Our results imply that possible neuroprotective effects of moderate alcohol consumption may not extend to the symptomatic group, who already have an established Aβ plaque burden and more advanced neurodegeneration [61].
In addition to the addictive nature of alcohol [62], alcohol is known to damage multiple organs and cause many diseases, including cancers [63]. In particular, prolonged alcohol misuse causes alcohol liver disease [64] and hepatitis [65]. The AST and ALT levels are hallmarks of liver function [66]. We found increased AST levels without altered ALT levels in presymptomatic APP/PS1 mice liver compared to aged-matched air-exposed APP/PS1 mice without differences in the cortex and hippocampus (Fig. S16A-C). The AST/ALT ratio of over 1.5 is considered severe liver damage [67, 68]. In this regard, a relatively high AST/ALT ratio (~ 2.3) in the liver of APP/PS1 mice indicates that the ethanol exposure paradigm has a detrimental effect on liver function (Fig. S16A-C). Thus, despite some beneficial effects of alcohol in presymptomatic APP/PS1 mice, because only about 10% are early-onset AD patients and a few of them have APP/PS1 mutations [69–71], our findings do not support alcohol drinking to prevent cognitive decline or AD pathology. Instead, we want to emphasize that even moderate drinking could be harmful for those especially sensitive to the intoxication effects of alcohol.
Despite the unclear mechanistic causality of altered LRP1 expression, our study establishes a compelling correlation between MEE and changes in ApoE, LDL cholesterol, and LRP1 levels. Additionally, our study revealed that ethanol exposure significantly mitigates the levels of proinflammatory cytokines, IL-1β and TNF-α, in the cortex and hippocampus of ethanol-exposed APP/PS1 mice compared to air-exposed counterparts, which is causally linked to the inhibition of the LRP1-IKK-α/β-NF-κB p65 pathway. This finding is particularly significant as both LRP1 and Toll-like receptor 4 (TLR4) play influential roles in neuroinflammation and AD pathogenesis [72, 73]. LRP1 suppresses microglial and astrocytic cell activation, critical contributors to neuroinflammation, by regulating the TLR4/NF-κB p65/MAPK signaling pathway [72]. This interaction regulates the release of proinflammatory cytokines and phagocytosis, contributing to maintaining brain homeostasis [74]. However, IκB-α levels responded to ethanol within 30 minutes in mixed hippocampal cell samples from wild-type mice but not in cells from TLR4- or MyD88-deficient mice [75]. Besides, insufficient LRP1 activation is associated with inflammation-induced tumor progression [76, 77], demonstrating the role of LRP1 in inflammation. Our findings illustrate alterations in sub-signals IKK-α/β and IKβ-α, notwithstanding the absence of an overall alteration in TLR4. Interestingly, a peptide ligand SP16 is known to activate LRP1, which decreases inflammation and increases cell survival in acute myocardial infarction [78, 79]. A recent phase 1 clinical trial as a first-in-class anti-inflammatory LRP1 agonist shows a promising outcome in healthy volunteers [80]. Moreover, a new peptide agonist, COG1410, shows a similar anti-inflammatory effect in rats [61]. Thus, a future study will reveal a possible therapeutic effect of LRP1 agonist in neuroinflammation-related AD.
One intriguing finding is the reduced levels of proinflammatory cytokine IL-1β in male mice following MEE. IL-1β plays a significant role in inducing neuroinflammation, and its reduction suggests a decrease in the inflammatory response [81]. This reduction could potentially lead to alleviating the symptoms associated with neuroinflammation, such as cognitive dysfunction. Conversely, in female mice, MEE has been linked to the upregulation of IL-10, an anti-inflammatory cytokine. An increase in IL-10 suggests an enhanced anti-inflammatory response, potentially protecting the brain from the damaging effects of inflammation [81, 82]. This upregulation might contribute to preserving cognitive function and neuronal health in female mice. Interestingly, we found no sex-specific changes in AD-like behaviors but only sex-specific changes in cytokine levels (Table 1). Although the exact mechanisms of these sex-specific effects of ethanol are unclear, several plausible explanations underlie our findings. Hormonal differences between males and females, such as the influence of estrogen and testosterone, could potentially differentially respond to ethanol exposure [83]. Several recent studies revealed the sex-specific differences in the regulation of cytokines by astrocytes and microglia. In males, astrocytes primarily regulate proinflammatory cytokines [84]. Conversely, in females, microglia play a central role in regulating anti-inflammatory cytokines [85]. Furthermore, astrocytes are more active in anti-inflammatory phenotype in females [86]. These differences underscore the complex interplay of astrocytes, microglia, and cytokines and their roles in the brain. Similarly, recent studies have shown that astrocytes and microglia, essential central nervous system (CNS) components, respond differently to alcohol exposure. Astrocytes primarily activate proinflammatory cytokines, proteins that heighten inflammation in response to alcohol consumption. This is part of their role in maintaining CNS homeostasis and their varying response to inflammatory stimuli [82, 87]. On the other hand, microglia mainly activate anti-inflammatory cytokines, undermining the inflammation. Focusing on the role of TLR4 in alcohol-induced neuroinflammation and brain damage, alcohol consumption activates microglia through TLR4 to produce anti-inflammatory cytokines in the brain [88]. Thus, our findings imply that MEE preferentially reduces astrocyte-induced proinflammatory cytokines in males while increasing microglia-induced anti-proinflammatory cytokines; both yield similar MEE-induced behavior outcomes. Further research may reveal mechanisms underlying the sex difference in cytokine-mediated signaling and AD pathology.
Table 1
Summary of statistical analysis
Figure | Statistical Tests | Comparison | Value | P value |
Figure 1 | B | Mann-Whitney test | Air vs EtOH | U = 0 | P < 0.0001 |
C | Mann-Whitney test | Air vs EtOH | U = 9 | P = 0.0011 |
D | Mann-Whitney test | Air vs EtOH | U = 1 | P < 0.0001 |
E | Mann-Whitney test | Air vs EtOH | U = 4 | P = 0.0001 |
F | Mann-Whitney test | Air vs EtOH | U = 1.5 | P < 0.0001 |
G | Mann-Whitney test | Air vs EtOH | U = 4 | P = 0.0001 |
H | Mann-Whitney test | Air vs EtOH | U = 37 | P = 0.3423 |
I | Correlation | ApolipoproteinE vs LDL-C | R = 0.6897 | P = 0.0008 |
J | Mann-Whitney test | Air vs EtOH | U = 13 | P = 0.0039 |
K | Mann-Whitney test | Air vs EtOH | U = 18 | P = 0.0138 |
L | Mann-Whitney test | Air vs EtOH | U = 47 | P = 0.8534 |
M | Correlation | ApolipoproteinE vs LDL-C | R = 0.5964 | P = 0.0021 |
Figure 2 | C (LRP1) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
C (p-IKK-α/β) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
C (t-IKK-α/β) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
C (p-/t-IKK-α/β) | Mann-Whitney test | Air vs EtOH | U = 2 | P = 0.0317 |
C (IκB-α) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
C (NF-κB) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
D (LRP1) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
D (p-IKK-α/β) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
D (t-IKK-α/β) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
D (p-/t-IKK-α/β) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
D (IκB-α) | Mann-Whitney test | Air vs EtOH | U = 2 | P = 0.0317 |
D (NF-κB) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
Figure 3 | A (Total, IL-1β, Cortex) | Mann-Whitney test | Air vs EtOH | U = 10 | P = 0.0014 |
A (Total, IL-1β, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 9.5 | P = 0.0011 |
A (Total, TNF- α, Cortex) | Mann-Whitney test | Air vs EtOH | U = 18 | P = 0.0147 |
A (Total, TNF- α, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 12 | P = 0.0018 |
B (Male, IL-1β, Cortex) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
B (Male, IL-1β, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
B (Male, TNF- α, Cortex) | Mann-Whitney test | Air vs EtOH | U = 2 | P = 0.317 |
B (Male, TNF- α, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
C (Female, IL-1β, Cortex) | Mann-Whitney test | Air vs EtOH | U = 7 | P = 0.3905 |
C (Female, IL-1β, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 9 | P = 0.5476 |
C (Female, TNF- α, Cortex) | Mann-Whitney test | Air vs EtOH | U = 6 | P = 0.2222 |
C (Female, TNF- α, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 5 | P = 0.1508 |
Figure 4 | B | Mann-Whitney test | Air vs EtOH | U = 13 | P = 0.0038 |
C | Mann-Whitney test | Air vs EtOH | U = 3.5 | P < 0.0001 |
Figure 5 | A | Mann-Whitney test | Air vs EtOH | U = 56 | P = 0.3698 |
B | Mann-Whitney test | Air vs EtOH | U = 0 | P < 0.0001 |
C | Mann-Whitney test | Air vs EtOH | U = 23 | P = 0.0036 |
D | Mann-Whitney test | Air vs EtOH | U = 50 | P = 0.2133 |
E | Mann-Whitney test | Air vs EtOH | U = 10 | P = 0.0001 |
F | Mann-Whitney test | Air vs EtOH | U = 29 | P = 0.0121 |
Figure 6 | B | Mann-Whitney test | Air vs EtOH | U = 7 | P = 0.0005 |
C | Mann-Whitney test | Air vs EtOH | U = 0 | P < 0.0001 |
Figure 7 | B | Mann-Whitney test | Air vs EtOH | U = 116.5 | P < 0.0001 |
C | Mann-Whitney test | Air vs EtOH | U = 359.5 | P = 0.9623 |
E (Air) | Mann-Whitney test | Air vs EtOH | U = 256 | P = 0.8618 |
FD (EtOH) | Mann-Whitney test | Air vs EtOH | U = 108 | P < 0.0001 |
H | Two-way ANOVA | Air vs EtOH | F (3, 88) = 5.433 | P = 0.0018 |
I | Two-way ANOVA | (PF) Air vs (PF) EtOH | F (3, 88) = 6.786 | P = 0.0138 |
J | Two-way ANOVA | Air vs EtOH | F (3, 88) = 9.313 | P < 0.0001 |
Sup Fig.1 | C (Male, Presymptomatic, Body weight) | Two-way ANOVA | Air vs EtOH | F (4, 62) = 0.3201 | P = 0.8635 |
C (Female, Symptomatic, Body weight) | Two-way ANOVA | Air vs EtOH | F (4, 100) = 0.8585 | P = 0.4917 |
D (Male, Presymptomatic, Body weight) | Two-way ANOVA | Air vs EtOH | F (3, 32) = 0.3373 | P = 0.7984 |
D (Female, Symptomatic, Body weight) | Two-way ANOVA | Air vs EtOH | F (3, 31) = 0.6150 | P = 0.6105 |
Sup Fig.3 | A (ApoE, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
A (ApoE, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 1 | P = 0.0159 |
A (ApoE, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
A (ApoE, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 2 | P = 0.0317 |
B (GFAP, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 1 | P = 0.0159 |
B (GFAP, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
B (GFAP, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
B (GFAP, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
C (ApoE, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 1.5 | P = 0.0238 |
C (ApoE, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
C (ApoE, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 3 | P = 0.0478 |
C (ApoE, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 3 | P = 0.0456 |
Sup Fig.4 | A | Mann-Whitney test | Air vs EtOH | U = 40.5 | P = 0.4926 |
B | Mann-Whitney test | Air vs EtOH | U = 37 | P = 0.3423 |
C | Mann-Whitney test | Air vs EtOH | U = 26 | P = 0.0753 |
D | Mann-Whitney test | Air vs EtOH | U = 9 | P = 0.0011 |
E | Mann-Whitney test | Air vs EtOH | U = 31 | P = 0.1649 |
F | Mann-Whitney test | Air vs EtOH | U = 47 | P = 0.8534 |
G | Mann-Whitney test | Air vs EtOH | U = 38 | P = 0.3930 |
H | Mann-Whitney test | Air vs EtOH | U = 10 | P = 0.0278 |
Sup Fig.5 | A (HDL-C, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 7 | P = 0.3095 |
A (HDL-C, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 8.5 | P = 0.4603 |
A (HDL-C, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 12.5 | P > 0.9999 |
A (HDL-C, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 7 | P = 0.3095 |
B (LDL-C, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 1 | P = 0.0159 |
B (LDL-C, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 1 | P = 0.0159 |
B (LDL-C, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 2.5 | P = 0.0397 |
B (LDL-C, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 2 | P = 0.0317 |
C (Total-C, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 7 | P = 0.3095 |
C (Total-C, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 12 | P > 0.9999 |
C (Total-C, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 11 | P = 0.8413 |
C (Total-C, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 9 | P = 0.5476 |
Sup Fig.6 | A | One-way ANOVA | Air vs EtOH (Male) | F (3, 9) = 1.031 | P = 0.9636 |
Air vs EtOH (Female) | P = 0.5892 |
B | One-way ANOVA | Air vs EtOH (Male) | F (3, 9) = 0.9527 | P = 0.7369 |
Air vs EtOH (Female) | P = 0.5858 |
C | One-way ANOVA | Air vs EtOH (Male) | F (3, 11) = 8.388 | P = 0.0209 |
Air vs EtOH (Female) | P = 0.4809 |
D | One-way ANOVA | Air vs EtOH (Male) | F (3, 10) = 0.6277 | P = 0.8978 |
Air vs EtOH (Female) | P = 0.9988 |
E | One-way ANOVA | Air vs EtOH (Male) | F (3, 11) = 12.16 | P = 0.9998 |
Air vs EtOH (Female) | P = 0.0015 |
F | One-way ANOVA | Air vs EtOH (Male) | F (3, 10) = 1.222 | P = 0.9984 |
Air vs EtOH (Female) | P = 0.7469 |
G | One-way ANOVA | Air vs EtOH (Male) | F (3, 12) = 0.7291 | P = 0.9994 |
Air vs EtOH (Female) | P = 0.0454 |
H | One-way ANOVA | Air vs EtOH (Male) | F (3, 9) = 1.290 | P = 0.9815 |
Air vs EtOH (Female) | P = 0.4227 |
I | One-way ANOVA | Air vs EtOH (Male) | F (3, 12) = 1.549 | P = 0.2216 |
Air vs EtOH (Female) | P = 0.9233 |
J | One-way ANOVA | Air vs EtOH (Male) | F (3, 10) = 5.033 | P = 0.0097 |
Air vs EtOH (Female) | P = 0.9996 |
Sup Fig.7 | A | Mann-Whitney test | Air vs EtOH | U = 12 | P > 0.9999 |
B | Mann-Whitney test | Air vs EtOH | U = 10 | P = 0.6905 |
C | Mann-Whitney test | Air vs EtOH | U = 7 | P = 0.3095 |
D | Mann-Whitney test | Air vs EtOH | U = 1 | P = 0.0159 |
Sup Fig.8 | A (Aβ, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 2 | P = 0.0317 |
A (Aβ, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 2 | P = 0.0269 |
A (Aβ, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 0.5 | P = 0.0159 |
A (Aβ, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0079 |
B (Aβ40, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 10 | P = 0.2251 |
B (Aβ40, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 16 | P = 0.7835 |
B (Aβ40, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 15.5 | P = 0.7338 |
B (Aβ40, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 7.5 | P = 0.1039 |
C (Aβ42, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0022 |
C (Aβ42, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0022 |
C (Aβ42, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0022 |
C (Aβ42, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0022 |
Sup Fig.9 | C | Mann-Whitney test | Air vs EtOH | U = 38.5 | P = 0.9136 |
D | Mann-Whitney test | Air vs EtOH | U = 32 | P = 0.4992 |
Sup Fig.10 | A (FDG, Cortex, Male) | Mann-Whitney test | Air vs EtOH | U = 1.5 | P = 0.0203 |
A (FDG, Cortex, Female) | Mann-Whitney test | Air vs EtOH | U = 3 | P = 0.0303 |
A (FDG, Hippocampus, Male) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0001 |
A (FDG, Hippocampus, Female) | Mann-Whitney test | Air vs EtOH | U = 3 | P = 0.0401 |
Sup Fig.11 | B | Mann-Whitney test | Air vs EtOH | U = 8 | P > 0.9999 |
C | Mann-Whitney test | Air vs EtOH | U = 7 | P = 0.8857 |
Sup Fig.12 | A | Mann-Whitney test | Air vs EtOH | U = 101.5 | P = 0.1414 |
B | Mann-Whitney test | Air vs EtOH | U = 171.5 | P = 0.8003 |
C | Mann-Whitney test | Air vs EtOH | U = 110 | P = 0.1626 |
D | Mann-Whitney test | Air vs EtOH | U = 109 | P = 0.1528 |
E | Mann-Whitney test | Air vs EtOH | U = 299 | P = 0.5061 |
F | Mann-Whitney test | Air vs EtOH | U = 326 | P = 0.7032 |
G | Mann-Whitney test | Air vs EtOH | U = 62 | P = 0.5899 |
H | Mann-Whitney test | Air vs EtOH | U = 70 | P = 0.9323 |
Sup Fig.13 | A | Mann-Whitney test | Air vs EtOH | U = 122 | P = 0.2112 |
B | Mann-Whitney test | Air vs EtOH | U = 132 | P = 0.3503 |
C | Mann-Whitney test | Air vs EtOH | U = 23 | P < 0.0001 |
D | Mann-Whitney test | Air vs EtOH | U = 22 | P < 0.0001 |
Sup Fig.14 | A | Mann-Whitney test | Air vs EtOH | U = 26.5 | P = 0.2457 |
B | Mann-Whitney test | Air vs EtOH | U = 19.5 | P = 0.0706 |
C | Mann-Whitney test | Air vs EtOH | U = 20 | P = 0.0831 |
D | Mann-Whitney test | Air vs EtOH | U = 40 | P > 0.9999 |
E | Mann-Whitney test | Air vs EtOH | U = 28 | P = 0.3154 |
F | Mann-Whitney test | Air vs EtOH | U = 38 | P = 0.8968 |
G | Mann-Whitney test | Air vs EtOH | U = 26 | P = 0.9546 |
H | Mann-Whitney test | Air vs EtOH | U = 17 | P = 0.1806 |
I | Two-way ANOVA | Air vs EtOH | F (3, 40) = 1.476 | P = 0.2356 |
J | Two-way ANOVA | Air vs EtOH | F (3, 88) = 1.716 | P = 0.1694 |
K | Two-way ANOVA | Air vs EtOH | F (3, 40) = 1.204 | P = 0.9961 |
Sup Fig.15 | A | Mann-Whitney test | Air vs EtOH (Male) | U = 10.5 | P = 0.0004 |
Air vs EtOH (Female) | U = 56 | P = 0.0113 |
B | Mann-Whitney test | Air vs EtOH (Male) | U = 65.5 | P = 0.9878 |
Air vs EtOH (Female) | U = 118 | P = 0.9766 |
C | Mann-Whitney test | Old vs New object (Air male) | U = 45 | P = 0.3653 |
Old vs New object (Air female) | U = 47 | P = 0.1600 |
D | Mann-Whitney test | Old vs New object (EtOH male) | U = 15 | P = 0.0019 |
Air vs Old vs New object (EtOH female) | U = 42 | P = 0.0027 |
E (Male) | Two-way ANOVA | Air vs EtOH | F (3, 32) = 5.215 | P = 0.0048 |
F (Male) | Two-way ANOVA | Air vs EtOH | F (3, 48) = 2.693 | P = 0.0465 |
G (Female) | Two-way ANOVA | Air vs EtOH | F (3, 32) = 6.761 | P = 0.0012 |
H (Female) | Two-way ANOVA | Air vs EtOH | F (3, 88) = 3.638 | P = 0.0191 |
Sup Fig.16 | A (ALT, Cortex) | Mann-Whitney test | Air vs EtOH | U = 8 | P = 0.1320 |
A (ALT, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 14 | P = 0.5887 |
A (ALT, Liver) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0022 |
B (AST, Cortex) | Mann-Whitney test | Air vs EtOH | U = 16 | P = 0.8182 |
B (AST, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 8.5 | P = 0.1450 |
B (AST, Liver) | Mann-Whitney test | Air vs EtOH | U = 15 | P = 0.6623 |
C (ALT/AST, Cortex) | Mann-Whitney test | Air vs EtOH | U = 12 | P = 0.3939 |
C (ALT/AST, Hippocampus) | Mann-Whitney test | Air vs EtOH | U = 11 | P = 0.3095 |
C (ALT/AST, Liver) | Mann-Whitney test | Air vs EtOH | U = 0 | P = 0.0022 |