Is the cortical capillary renamed as the transcortical vessel in diaphyseal vascularity?

Asghar, Adil; Kumar, Ashutosh; Narayan, Ravi Kant; Naaz, Shagufta

doi:10.1002/ar.24461

Cited by 20 publications

(26 citation statements)

References 40 publications

(67 reference statements)

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“…The location of the adiponectin -/low FF BMAds aligns with known sites of arteriolar entry and distribution within the femur and tibia (26,27). These cells also expressed Cxcl12, though this was decreased relative to control BMAds.…”

Section: Ectopic Ff Bmads Originate From Adiponectin -/Low Progenitors and Express Low Levels Of Cxcl12supporting

confidence: 60%

A bone-specific adipogenesis pathway in fat-free mice defines key origins and adaptations of bone marrow adipocytes with age and disease

Zhang

Robles²,

Magee³

et al. 2021

eLife

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Bone marrow adipocytes accumulate with age and in diverse disease states. However, their origins and adaptations in these conditions remain unclear, impairing our understanding of their context-specific endocrine functions and relationship with surrounding tissues. In this study, by analyzing bone and adipose tissues in the lipodystrophic 'fat-free' mouse, we define a novel, secondary adipogenesis pathway that relies on the recruitment of adiponectin-negative stromal progenitors. This pathway is unique to the bone marrow and is activated with age and in states of metabolic stress in the fat-free mouse model, resulting in the expansion of bone marrow adipocytes specialized for lipid storage with compromised lipid mobilization and cytokine expression within regions traditionally devoted to hematopoiesis. This finding further distinguishes bone marrow from peripheral adipocytes and contributes to our understanding of bone marrow adipocyte origins, adaptation, and relationships with surrounding tissues with age and disease.

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Section: Ectopic Ff Bmads Originate From Adiponectin -/Low Progenitors and Express Low Levels Of Cxcl12supporting

confidence: 60%

A bone-specific adipogenesis pathway in fat-free mice defines key origins and adaptations of bone marrow adipocytes with age and disease

Zhang

Robles²,

Magee³

et al. 2021

eLife

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“…This ectopic BMA population did not rescue circulating adiponectin in the FF mice and had decreased expression of Adipoq, reinforcing the efficacy of the DTA. The location of the FF BMAs aligns with known sites of arteriolar entry and distribution within the femur and tibia (24,25). These cells also expressed Cxcl12, though this was decreased relative to control BMAs.…”

Section: Discussionsupporting

confidence: 64%

A novel skeletal-specific adipogenesis pathway defines key origins and adaptations of bone marrow adipocytes with age and disease

Robles

Xiao

Magee

et al. 2021

Preprint

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SUMMARYBone marrow adipocytes (BMAs) accumulate with age and in diverse disease states. However, their age- and disease-specific origins and adaptations remain unclear, impairing our understanding of their context-specific endocrine functions and relationship with surrounding tissues. In this study, we identified a novel, bone marrow-specific adipogenesis pathway using the AdipoqCre+/DTA+ ‘fat free’ mouse (FF), a model in which Adipoq-Cre drives diphtheria toxin-induced cell death in all adiponectin-expressing cells. Adiponectin is highly expressed by BMAs, peripheral adipocytes, and a subset of bone marrow stromal progenitor cells with preadipocyte-like characteristics. Consistent with this, FF mice presented with uniform depletion of peripheral white and brown adipose tissues, in addition to loss of BMAs in canonical locations such as the tail vertebrae. However, unexpectedly, a distinctly localized subset of BMAs accumulated with age in FF mice in regions such as the femoral and tibial diaphysis that are generally devoid of bone marrow adipose tissue (BMAT). Ectopic BMAs in FF mice were defined by increased lipid storage and decreased expression of cytokines including hematopoietic support factor Cxcl12 and adipokines adiponectin, resistin, and adipsin. FF BMAs also displayed resistance to lipolytic stimuli including cold stress and β3-adrenergic agonist CL316,243. This was associated with reduced expression of adrenergic receptors and monoacylglycerol lipase. Global ablation of adiponectin-expressing cells regulated bone accrual in an age- and sex-dependent manner. High bone mass was present early in life and this was more pronounced in females. However, with age, both male and female FF mice had decreased cortical thickness and mineral content. In addition, unlike BMAs in healthy mice, expansion of ectopic BMAs in FF mice was inversely correlated with cortical bone volume fraction. Subcutaneous fat transplant and normalization of systemic metabolic parameters was sufficient to prevent ectopic BMA expansion in FF mice but did not prevent the initial onset of the high bone mass phenotype. Altogether, this defines a novel, secondary adipogenesis pathway that relies on recruitment of adiponectin-negative stromal progenitors. This pathway is unique to the bone marrow and is activated with age and in states of metabolic stress, resulting in expansion of BMAs specialized for lipid storage with compromised lipid mobilization and endocrine function within regions traditionally devoted to hematopoiesis. Our findings further distinguish BMAT from peripheral adipose tissues and contribute to our understanding of BMA origins and adaptation with age and disease.

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“…These periosteal vascular bed-derived TCVs are now recognized as the major cortical blood supply. (Moulopoulos & Koutoulidis, 2015) The channels have been variably labeled as capillaries, vascular lattices, or transosteal channels or vessels of the cortical canal, (Asghar et al, 2020) while Herisson et al (Herisson et al, 2018) and Grüneboom et al(Grüneboom et al, 2019) suggest labeling them at TCVs. Herisson et al (Herisson et al, 2018) reported 21.6 ± 0.9 μm diameter channels in mice distributed throughout skull cortices in mice, noting similar channels in humans (obtained during decompression surgery) have 5.3-fold larger diameters.…”

Section: Discussionmentioning

confidence: 99%

“…Some porotic alterations may be related to marrow hyperplasia, but another pathophysiologic mechanism deserves consideration. The recent article by Grüneboom et al (Grüneboom et al, 2019) described the presence of hundreds of transcortical capillaries in normal mice postcranial bones and that “diseases that affect bone physiology lead to substantial changes in TCV (transcortical vessel) numbers.” Asghar et al (Asghar et al, 2020) provides a historical review of bone vascularity, noting the first observation of small veins on the shinbone of a cow in 1679 by Antnie van Leeuwenhoek, Clopton Havers' 1,691 recognition of the significance of nutrient arteries penetrating bone, and Albinus' 1754 visualization of blood vessels in bony canals and that there is a combined periosteal and medullary circulation. Brookes (Brookes, 1960) notes communication of cortical capillaries with both the periosteal bed and marrow sinusoids and that centripetal flow occurs at least when medullary artery pressure is compromised.…”

Section: Discussionmentioning

confidence: 99%

Demographics and significance of porotic hyperostosis as assessed by surface microscopy

Rothschild

Jellema

Lambert

2022

The Anatomical Record

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Background Examination of parietal surface anatomy has been limited because standard techniques have insufficient resolution to identify and characterize the structures of interest. Perspectives derived thereof have not clarified their nature. Surface microscopy is pursued as a nondestructive technique to assess the character and implications of porotic pores (referred to as porotic hyperostosis), which have been subject of much speculation. Methods The external surface of the skulls, selected on the basis of age and gender, from the Hamann‐Todd human collection are examined by epi‐illumination microscopy for surface pores and to assess correlation with age, ethnicity, gender, anemia, infection, cancer, hypertrophic bone disorders, renal disease, and fractures. Results Pore‐like surface defects are present in 2.7%–5% of individuals in the third‐fifth decades of life; 7%, in the sixth‐eighth; and 25%, in the ninth‐11th, but absent in the second decade of life. They are gender and birthdate independent, but slightly more common in African Americans. Fractures are more common among individuals with parietal pores, while tuberculosis, cancer, and hypertrophic bone diseases and anemia are less common. Discussion This is the first study to actually examine the prevalence of parietal pores as a function of known age, race, and sex and provides a baseline for comparison with populations in which those variables are not clearly identifiable. While some porotic pores may be related to marrow hyperplasia, transcortical circulation may explain the majority.

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Is the cortical capillary renamed as the transcortical vessel in diaphyseal vascularity?

Cited by 20 publications

References 40 publications

A bone-specific adipogenesis pathway in fat-free mice defines key origins and adaptations of bone marrow adipocytes with age and disease

A bone-specific adipogenesis pathway in fat-free mice defines key origins and adaptations of bone marrow adipocytes with age and disease

A novel skeletal-specific adipogenesis pathway defines key origins and adaptations of bone marrow adipocytes with age and disease

Demographics and significance of porotic hyperostosis as assessed by surface microscopy

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