Sarcopenia is an ageing-related disease featured by the loss of skeletal muscle quality and function. Advanced glycation end-products (AGEs) are a complex set of modified proteins or lipids by non-enzymatic glycosylation and oxidation. The formation of AGEs is irreversible, and they accumulate in tissues with increasing age. Currently, AGEs, as a biomarker of ageing, are viewed as a risk factor for sarcopenia. AGE accumulation could cause harmful effects in the human body such as elevated inflammation levels, enhanced oxidative stress, and targeted glycosylation of proteins inside and outside the cells. Several studies have illustrated the pathogenic role of AGEs in sarcopenia, which includes promoting skeletal muscle atrophy, impairing muscle regeneration, disrupting the normal structure of skeletal muscle extracellular matrix, and contributing to neuromuscular junction lesion and vascular disorders. This article reviews studies focused on the pathogenic role of AGEs in sarcopenia and the potential mechanisms of the detrimental effects, aiming to provide new insights into the pathogenesis of sarcopenia and develop novel methods for the prevention and therapy of sarcopenia. Cite this article: Bone Joint Res 2025;14(3):185–198

Introduction: Pathological conditions, which determine human atrophy, are numerouses and heterogeneous. Experimental studies prove that these different pathological conditions use common enzymatic pathways leading muscle atrophy. In every catabolic conditions where there is proteolyses’s increase, this one happens in association with up-regulation of two specific genes of skeletal muscle atrophy. These genes, MuRf1 (muscle ring finger-1) and MAFbx (muscle atrophy F-box), encode ubiquitin ligases. These ligases bind and mediate ubiquitination of myofibrillar proteins for subsequent degradation during muscle atrophy. The aim of our study is to obtain a better understanding of human muscle physiopathology in atrophy by use of histochemistry and immunolocalisation of MuRF-1 and MAFbx. Patients and Methods: 15 patients, amputated at third distal or proximal leg because of different acute or chronic pathology, were divided in two group. Group A: 12 elderly patients (mean age 72 years) amputated for vascular diseases (8) and complication of a diabetic foot (4). Group B: 3 young patients involved in car accident (mean age 25) amputated for limb’s acute arterial insufficiency. Gastrocnemius muscle biopsy specimens were obtained for all the patients, after that the informed consent was obtain, for histochemical (haematossilineosin), and immunohistochemical (anti- MuRf1, anti- MAFbx) analysis. Results: Histochemistry: Group A: skeletal muscle showed a decrease in fiber size in cross-sectional area and fiber length with adipose tissue. Group B: light skeletal muscle structural alteration. Immuno-histochemistry: in group A, in muscular drawings, polyclonal antibodies direct against MuRf1 and MAFbx had stained muscle biopsy specimens. Muscle fiber cells showed MuRf1 and MAFbx subsarcolemmatic immunoreactivity and weakly immunoreactivity of the extracellular matrix. We noticed no positivity to anti- MuRf1 and anti- MAFbx less in sections from group B muscle biopsy specimens and in sections in which were present tissue muscle degeneration with replacement of adipose tissue. Conclusion: The pathological results supported the concept that MuRf1 and MAFbx appeared to be regulatory peptide in cellular pathology that conduce to muscular atrophy. Our data support the hypothesis that different pathological conditions use common enzymatic pathways leading muscle atrophy. The demonstration that the muscle-specific proteins MAFbx and MuRF1 are upregulated in multiple pathological conditions of skeletal muscle atrophy it is critical to continue studying the cellular pathways to discover promising targets for the development of effective new treatments for skeletal muscle disease

MicroRNAs (miRNAs) are a class of small non-coding RNAs that have emerged as potential predictive, prognostic, and therapeutic biomarkers, relevant to many pathophysiological conditions including limb immobilization, osteoarthritis, sarcopenia, and cachexia. Impaired musculoskeletal homeostasis leads to distinct muscle atrophies. Understanding miRNA involvement in the molecular mechanisms underpinning conditions such as muscle wasting may be critical to developing new strategies to improve patient management. MicroRNAs are powerful post-transcriptional regulators of gene expression in muscle and, importantly, are also detectable in the circulation. MicroRNAs are established modulators of muscle satellite stem cell activation, proliferation, and differentiation, however, there have been limited human studies that investigate miRNAs in muscle wasting. This narrative review summarizes the current knowledge as to the role of miRNAs in the skeletal muscle differentiation and atrophy, synthesizing the findings of published data.

Cite this article: Bone Joint Res 2020;9(11):798–807.

Chondrocyte hypertrophy represents a crucial turning point during endochondral bone development. This process is tightly regulated by various factors, constituting a regulatory network that maintains normal bone development. Histone deacetylase 4 (HDAC4) is the most well-characterized member of the HDAC class IIa family and participates in different signalling networks during development in various tissues by promoting chromatin condensation and transcriptional repression. Studies have reported that HDAC4-null mice display premature ossification of developing bones due to ectopic and early-onset chondrocyte hypertrophy. Overexpression of HDAC4 in proliferating chondrocytes inhibits hypertrophy and ossification of developing bones, which suggests that HDAC4, as a negative regulator, is involved in the network regulating chondrocyte hypertrophy. Overall, HDAC4 plays a key role during bone development and disease. Thus, understanding the role of HDAC4 during chondrocyte hypertrophy and endochondral bone formation and its features regarding the structure, function, and regulation of this process will not only provide new insight into the mechanisms by which HDAC4 is involved in chondrocyte hypertrophy and endochondral bone development, but will also create a platform for developing a therapeutic strategy for related diseases.

Cite this article: Bone Joint Res. 2020;9(2):82–89.