# In Vivo Models of Diabetes: Unravelling Molecular Pathways in Metabolic and Skeletal Complications

**Authors:** Haryati Ahmad Hairi, Nor Hidayah Mustafa, Ahmad Nazrun Shuid, Muhammad Zulfiqah Sadikan

PMC · DOI: 10.3390/biomedicines14010243 · Biomedicines · 2026-01-21

## TL;DR

This paper reviews in vivo models of diabetic osteoporosis to understand how diabetes affects bone health and identify potential treatments.

## Contribution

The paper systematically summarizes in vivo models and molecular pathways involved in diabetic osteoporosis for preclinical research.

## Key findings

- High-fat-diet and STZ models reveal mechanisms like AGE accumulation and osteoblast suppression in diabetic osteoporosis.
- Combined HFD + STZ models closely mimic type 2 diabetes and related bone complications.
- Impaired insulin/IGF-I signaling and oxidative stress are key drivers of diabetic bone fragility.

## Abstract

Background/Objectives: Diabetic osteoporosis (DOP) is a metabolic bone disorder marked by reduced bone mass, impaired microarchitecture and elevated fracture risk arising from type 1 and type 2 diabetes. Understanding its pathophysiology is essential for developing effective interventions. Method: A broad literature search of Scopus and PubMed (2015–2025) using diabetic osteoporosis-related keywords identified relevant English in vivo studies, which were screened, extracted, and narratively summarised for this review. Results: In vivo models, including high-fat-diet (HFD), streptozotocin (STZ) and combined HFD + STZ protocols, are widely used to investigate DOP mechanisms. HFD models mimic obesity-induced insulin resistance, chronic hyperglycaemia and low-grade inflammation, leading to suppressed osteoblast activity, enhanced osteoclastogenesis and accumulation of advanced glycation end products (AGEs). Ultimately, they compromise bone microarchitecture and mechanical strength. STZ models replicate type 1 diabetes by inducing β-cell destruction, insulin deficiency, oxidative stress, osteoblast apoptosis and inflammatory pathways promoting bone resorption. The combined HFD + STZ model integrates insulin resistance and partial β-cell dysfunction, closely reflecting type 2 diabetes pathology, including trabecular bone loss, collagen glycation and disrupted osteoblast–osteoclast signalling. Mechanistically, DOP involves impaired insulin/IGF-I signalling, AGE–RAGE interactions, oxidative stress and inflammation, resulting in diminished bone formation and quality. These models provide robust platforms for exploring molecular mechanisms and evaluating potential therapies, including Wnt pathway modulators, antioxidants and ferroptosis inhibitors. Conclusions: Collectively, preclinical in vivo models are indispensable for understanding DOP pathophysiology and developing strategies to mitigate diabetic bone fragility.

## Linked entities

- **Proteins:** AGER (advanced glycosylation end-product specific receptor), Wnt (protein Wnt-2)
- **Chemicals:** insulin (PubChem CID 70678557)
- **Diseases:** type 1 diabetes (MONDO:0005147), type 2 diabetes (MONDO:0005148)

## Full-text entities

- **Genes:** AGER (advanced glycosylation end-product specific receptor) [NCBI Gene 177] {aka RAGE, SCARJ1, sRAGE}, RENBP (renin binding protein) [NCBI Gene 5973] {aka RBP, RNBP}, INS (insulin) [NCBI Gene 3630] {aka IDDM, IDDM1, IDDM2, ILPR, IRDN, MODY10}, IGF1 (insulin like growth factor 1) [NCBI Gene 3479] {aka IGF, IGF-I, IGFI, MGF}
- **Diseases:** obesity (MESH:D009765), metabolic bone disorder (MESH:D001851), DOP (MESH:D010024), diminished bone formation (MESH:D058426), type 1 and type 2 diabetes (MESH:D003924), bone loss (MESH:D001847), Diabetes (MESH:D003920), type 1 diabetes (MESH:D003922), insulin deficiency (MESH:D007333), inflammation (MESH:D007249), fracture (MESH:D050723)
- **Chemicals:** AGEs (MESH:D017127), fat (MESH:D005223), STZ (MESH:D013311)

## Full text

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## Figures

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## References

79 references — full list in the complete paper: https://tomesphere.com/paper/PMC12838559/full.md

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Source: https://tomesphere.com/paper/PMC12838559