Abstract

Background: Type 2 diabetes mellitus (T2DM) is characterized by significant metabolic heterogeneity, re quiring precise subtyping to optimize personalized management. While etiological classifications are founda tional, they lack the granularity needed to predict diverse clinical trajectories.

Objective: This review elucidates the role of body composition phenotypesspecifically regional adiposity and skeletal muscle massas a framework for T2DM stratification.

Synthesis: We synthesized evidence regarding the pathophysiological cross-talk between adipose and skeletal muscle tissues. Adipose tissue modulates metabolism via lipotoxicity and systemic inflammation, while skel etal muscle governs glucose homeostasis through insulin-mediated uptake and myokine secretion. Crucially, the transition from regional fat distribution (visceral vs. gluteofemoral) to ectopic deposition (liver, pancreas) differentially impacts insulin resistance and beta-cell function. Dual-energy X-ray absorptiometry (DXA) is highlighted as a robust modality for precise phenotyping.

Key Findings: T2DM can be stratified into four distinct phenotypes: sarcopenic, simple obese, sarcopenic obese, and normal composition. Notably, the muscle-to-fat ratio often exhibits superior predictive value for cardiovascular and microvascular complications compared to solitary parameters.

Conclusion: Body composition-based phenotyping via DXA offers a scalable approach for T2DM subtyping. Integrating these anatomical markers into clinical practice facilitates targeted interventions and improves long-term metabolic prognoses.

DOI: doi.org/10.63721/26/JCVI0118

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