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Individuals with type 2 diabetes mellitus (T2D) have a three-fold greater hip fracture risk
than those without diabetes, independent of dual-energy x-ray absorptiometry (DXA)
determined bone mineral density (BMD) [1]. Previous large studies explain the BMD T-score
inability, a quantitative measure, to accurately predict fracture risk in T2D [2,3]. Mechanisms
underlying the inferior bone quality and skeletal fragility in diabetes are not fully understood,
making the clinical identification of individuals at risk for fractures difficult [4]. Therefore,
we aimed to investigate the comprehensive multiscale bone quality parameters such as
biomechanical, microstructural, material, and compositional bone properties in a rodent
model and clinical populations with and without T2D.
In a rodent study, we have used a combination of a high-fat diet (4 weeks, 58% kcal as fat)
and low dose streptozotocin (one time, 35 mg/kg) treatment to develop T2D in female
Sprague Dawley rats. In contrast, the control animal received a normal pellet diet (4 weeks,
12% kcal as fat) and an equivalent volume of vehicle (one time, 0.9% saline solution). After
eight weeks of establishing the T2D model, the femoral bones were excised, and multiscale
bone quality parameters were investigated. We found that the non-enzymatic crosslink ratio
(NE-xLR) is elevated in the T2D group. NE-xLR is strongly and negatively correlated with
post-yield-displacement, which directly relates to bone fragility. Along with that, the
decreased mineral-to-matrix ratio (Fourier transform infrared spectroscopy), decreased
nanoindentation determined modulus, increased indentation distance (cyclic reference point
indentation), and wider mineral crystal size (x-ray diffraction) in the T2D group compared to
non-diabetic, evidenced that the diabetic bone compositional and material properties have
changed (diminished), and diabetic bone became weaker and tends to fracture easily.
Altogether, our rodent model simulates the disease characteristics of late-stage (insulin
resistance and later hypoinsulinemia) for non-obese young T2D and provides potential
evidence of diabetic bone fragility at various organization levels [5].
In another study, the femoral head bone tissue specimens were collected from patients with
diabetes and known fragility fracture status. Trabecular bone quality parameters were
compared in samples of two groups: non-diabetic (n=40) and diabetic (n=30) with a mean
duration of disease 7.5±2.8 years. As a result, no significant difference was observed in DXA
determined BMD. Bone volume fraction was lower for the diabetic group. Apparent-level (strength) and tissue-level (nanoindentation determined) modulus and hardness were lower in
those with diabetes. Compositional differences between the non-diabetic and diabetic groups
included lower mineral-to-matrix ratio (gravimetric), wider mineral crystals, and bone
collagen modifications assessed as higher total fluorescent advanced glycation end-products
(fAGEs) and non-enzymatic crosslink ratio (NE-xLR). Our findings provide evidence of
hyperglycemia’s and AGEs detrimental effects on trabecular bone quality at multiple length
scales leading to lower energy absorption and toughness, indicative of an increased
propensity to bone fragility [6].
After understanding the negative impact of T2D on bone quality, we aim to explore further
possibilities of identifying a non-invasive, low-cost diagnostic technique that can help
clinicians to predict bone quality beyond bone mineral density accurately. Therefore, first, the
multiscale fingernail plate quality is investigated for healthy (HbA1c ≤ 5.9%), diabetic
controlled (HbA1c < 7.5%), and uncontrolled diabetic (HbA1c ≥ 7.5%) groups. It was found
that T2D had an adverse effect on the human fingernail plate quality too. The parameters of
fingernail plate quality were degraded in a pattern among all the three groups, where the
degradation was highest in the case of severity of T2D (uncontrolled) as compared to the
healthy group (healthy<diabetic controlled<uncontrolled) [7]. Secondly, the material and
compositional properties of bone/fingernail were investigated using nanoindentation studies,
and Fourier transform infrared spectroscopy, respectively, and a link in degradation pattern of
both compositional/material properties of bone and fingernail plate quality was established.
Both bone/fingernails in T2D had lower reduced modulus (Er), hardness (H), lower Amide I
and Amide II area ratio (protein content), higher sugar-to-matrix ratio, and relatively high
carboxymethyl-lysine (CML) content compared with non-diabetic patients. Sugar-to-matrix
ratio and relative carboxymethyl-lysine (CML) content were strongly and positively
correlated with HbA1c for both bone/fingernail. There was a positive correlation between
bone and fingernail glycation content. Our findings provide evidence that the degradation
pattern of bone and fingernail properties go hand-in-hand in individuals with T2D. Thus, with
these two studies, we concluded that the small-scale properties of the fingernail have the
potential to serve as a non-invasive surrogate marker of bone quality in T2D [8].
Altogether, this thesis presents the multiscale characterization of bone as a material, the role
of bone quality in diabetic fractures, and elucidates the importance of assessment of bone
quality to clinicians in understanding and assessing type 2 diabetic fragility fractures. This
thesis concluded that diabetes is detrimental to bone quality. The accumulation of AGEs is
one of the processes that favor deterioration of bone quality in diabetes leading to material, structural, compositional, and biomechanical dysfunctionality. Thus, highlight the need for
more specific measures to understand and diagnose the bone quality and bone fragility in
T2D. |
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