Submitted:
01 July 2026
Posted:
01 July 2026
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Abstract

Keywords:
1. Introduction: From Compensation to Inflammatory Resilience
2. Narrative Review Approach and Literature Selection
3. Dietary Inflammatory Potential as a Lifestyle Exposure
4. Biological Translation from Dietary Inflammatory Exposure to Disease Vulnerability
5. Physical Activity as an Anti-Inflammatory and Metabolic Resilience Factor
6. Joint and Interactive Evidence: Pro-Inflammatory Diets, Physical Activity, and Health Outcomes
7. Why Compensation Is an Incomplete Model
8.8. The Inflammatory Resilience Framework
9. Applications, Research Gaps, and Future Directions
10. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
| CRP | C-reactive protein |
| DII | Dietary Inflammatory Index |
| E-DII | Energy-adjusted Dietary Inflammatory Index |
| IL-6 | Interleukin-6 |
| METs | Metabolic equivalents |
| NHANES | National Health and Nutrition Examination Survey |
| TNF-α | Tumor necrosis factor-alpha |
| VO₂max | Maximal oxygen uptake |
| VO₂peak | Peak oxygen uptake |
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| Health 7. | Representative outcomes | Main inflammatory relevance | Evidence type emphasized in this review | Key supporting references |
| Cardiovascular and vascular outcomes | Cardiovascular disease risk, cardiovascular mortality, vascular morbidity | Chronic low-grade inflammation, oxidative stress, endothelial dysfunction, vascular impairment, and cardiometabolic risk clustering | Meta-analysis and umbrella-level evidence linking higher dietary inflammatory potential with cardiovascular risk and mortality | [7,28,32] |
| Metabolic disease and glucose regulation | Type 2 diabetes, impaired glucose regulation, insulin resistance-related risk | Diet-related inflammation may contribute to insulin resistance, metabolic dysfunction, adipose tissue inflammation, and impaired glucose handling | Systematic review and meta-analysis evidence linking higher DII scores with diabetes risk | [29,32] |
| Metabolic syndrome and cardiometabolic clustering | Metabolic syndrome and its components, including central adiposity, dyslipidemia, hypertension, and glucose abnormalities | Pro-inflammatory dietary patterns may interact with adiposity, metabolic inflammation, and vascular risk factors | Systematic review and meta-analysis of observational studies on DII and metabolic syndrome | [8,30,32] |
| Obesity and adiposity-related vulnerability | General obesity, central adiposity, visceral adipose tissue-related risk | Excess adiposity can amplify inflammatory responses through adipokine imbalance, macrophage infiltration, and low-grade systemic inflammation | Narrative and umbrella-level evidence linking DII with non-communicable disease risk and adiposity-related pathways | [6,28,32] |
| Cancer-related outcomes | Site-specific cancer risk and broader cancer-related vulnerability | Chronic inflammation, oxidative stress, immune dysregulation, and altered metabolic signaling may contribute to carcinogenic environments | Systematic review and dose-response meta-analysis of DII and site-specific cancer risk | [28,31,32] |
| Mortality and long-term non-communicable disease burden | All-cause mortality, non-communicable chronic disease risk, long-term health vulnerability | Persistent inflammatory exposure may contribute to cumulative disease burden across cardiometabolic, vascular, cancer-related, and aging-related pathways | Umbrella reviews and meta-analyses of observational evidence | [6,28,32] |
| Aging-related vulnerability | Functional decline, biological aging-related risk, multimorbidity vulnerability | Low-grade inflammation and diet-related inflammatory exposure may contribute to inflammaging, metabolic dysfunction, vascular impairment, and reduced physiological reserve | Narrative and umbrella-level synthesis; interpreted cautiously because aging-specific evidence varies by outcome and design | [1,2,6,28,32] |
| Physical activity-related factor | Anti-inflammatory or metabolic mechanism | Relevant biomarkers/pathways | Potential buffering role against pro-inflammatory diet | Key supporting references |
| Regular moderate-to-vigorous physical activity | Supports immune regulation and may reduce chronic inflammatory tone over time | CRP, IL-6, TNF-α, innate and adaptive immune regulation | May reduce baseline inflammatory tone, thereby limiting downstream expression of dietary inflammatory exposure | [43,44] |
| Exercise training adaptation | Repeated training may shift inflammatory responses from transient stress signals toward longer-term adaptation | Cytokine balance, recovery, training dose, anti-inflammatory signaling | Provides biological plausibility for partial buffering rather than full compensation | [10,12,43,44] |
| Skeletal muscle contraction and myokines | Contracting muscle releases myokines involved in interorgan communication | Myokine signaling, muscle–adipose–liver–vascular crosstalk | May influence immune–metabolic pathways affected by pro-inflammatory dietary patterns | [11,45,46] |
| Skeletal muscle metabolic plasticity | Exercise promotes metabolic adaptation and functional plasticity of skeletal muscle | Mitochondrial remodeling, substrate use, glucose disposal, metabolic flexibility | May improve host capacity to handle dietary metabolic stress | [46,49] |
| Visceral adiposity reduction | Exercise can reduce visceral adipose tissue, an important inflammatory tissue depot | Visceral adiposity, adipokines, adipose inflammation | May reduce adipose-driven amplification of dietary inflammatory exposure | [37,38,47] |
| Insulin sensitivity and glucose regulation | Exercise improves skeletal muscle glucose uptake and insulin sensitivity | Insulin signaling, glucose handling, substrate delivery | May buffer diet-related metabolic dysfunction and glycemic stress | [48,49] |
| Redox adaptation | Exercise-induced redox signals may stimulate adaptive antioxidant and repair responses | Reactive oxygen species, redox signaling, antioxidant enzymes, hormesis | May improve redox regulation rather than simply suppress oxidative stress | [35,36,50,51] |
| Endothelial function and vascular adaptation | Aerobic training can improve endothelial function and vascular reactivity | Flow-mediated dilation, nitric oxide bioavailability, vascular inflammation | May reduce vascular vulnerability related to inflammatory and oxidative dietary stress | [39,40,52,53] |
| Cardiorespiratory fitness | Represents accumulated physiological reserve from habitual activity and training | VO₂max/VO₂peak, METs, CRP, mortality risk | May indicate higher resilience capacity and lower vulnerability under inflammatory exposure | [54,55] |
| Integrated inflammatory resilience | Physical activity effects across immune, adipose, metabolic, redox, vascular, and fitness pathways are interconnected | Multi-system regulation rather than single biomarker change | Supports partial buffering of dietary inflammatory risk, not complete cancellation | [43,44,45,46,47,48,49,50,51,52,53,54,55] |
| Research priority | Current limitation | Recommended design or measurement | Framework component tested | Key supporting references |
| Dietary inflammatory exposure assessment | Single baseline dietary assessment and variable DII component availability | Repeated dietary assessment, E-DII, validation, and sensitivity analysis by dietary components | Exposure layer | [4,5,22,68,74] |
| Objective physical activity and sedentary behavior | Reliance on self-reported physical activity and incomplete sedentary behavior characterization | Accelerometry, device-based PA, sedentary behavior assessment, and 24-hour movement composition | Resilience modifier layer | [66,69,70] |
| Cardiorespiratory and muscular fitness | Physical activity behavior measured without physiological reserve indicators | CRF, grip strength, muscle function, gait speed, and resistance training assessment | Physiological reserve | [54,55,67,71,72] |
| Inflammatory and metabolic biomarkers | Outcomes measured without biological translation markers | CRP, IL-6, TNF-α, adipokines, glycemic markers, endothelial markers, and redox markers | Biological translation layer | [24,27,33,37,39,73] |
| Interaction and mediation modeling | Diet and PA often treated only as covariates | Additive and multiplicative interaction, mediation, moderated mediation, and causal inference | Risk translation | [60,63,75,76] |
| Longitudinal risk trajectories | Cross-sectional or single-time-point designs | Repeated measures of diet, PA, biomarkers, fitness, and outcomes | Time-dependent resilience | [56,57,77] |
| Combined lifestyle intervention trials | Observational evidence cannot prove buffering or compensation | Diet–exercise trials, factorial designs, pragmatic interventions, and mechanistic endpoints | Intervention testing | [78,79] |
| Population heterogeneity and responder profiling | Limited stratification by baseline phenotype | Stratification by age, sex, adiposity, CRF, muscle function, baseline inflammation, and disease status | Phenotype-specific resilience | [64,65,80,81] |
| Public health and clinical translation | Oversimplified “exercise offsets diet” messaging | Communication of partial buffering, residual risk, and combined lifestyle benefit | Translational application | [14,56,58,60,80] |
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