Impact du diabète de type 2 sur la réparation osseuse et vasculaire des défauts osseux craniaux / Impact of type 2 diabetes mellitus on osseous and vascular repairs of cranial bone defects

Caliaperoumal, Guavri

25 June 2018

A l’heure où le diabète prend des proportions pandémiques, nous nous sommes intéressés dans le cadre de cette thèse à l’étude de l’impact du diabète de type 2 (TD2M) sur l’os. Il y a peu d’études documentant l’impact de T2DM sur les os maxillo-faciaux d’origine endomembranaire et leurs réparations. Après une introduction bibliographique sur l’os, le diabète et les modèles d’études animaux, nous exposerons nos résultats sur (i) l’étude de la réparation vasculaire et osseuse des défauts de calvaria de rats diabètiques ZDF; (ii) l’impact du T2DM sur la structure osseuse et vasculaire des fémurs de rats ZDF; et (iii) l’altération des propriétés angiogéniques et du sécrétome des cellules souches mésenchymateuses de la moelle osseuse (BMSC) par le T2DM. Ces études ont permis de mettre en évidence l’altération de la réparation osseuse dans les défauts de taille-critique et l’altération de la réparation vasculaire dans les défauts de tailles critique et sous-critique de la calvaria de rats T2DM. De même, la microarchitecture osseuse (corticale et trabéculaire) et la vascularisation se trouvent significativement altérées par le T2DM dans les fémurs de rats ZDF. Au niveau cellulaire, le sécrétome des BMSCs de rat ZDF présente un profil angiogénique différent de celui des rats ZL contrôles, ce qui peut apporter des éléments de réponses permettant la compréhension de la vascularisation paradoxale dans un contexte T2DM. Ces résultats devraient permettre d’améliorer la compréhension de l’effet du T2DM sur la cicatrisation osseuse, afin d’améliorer les stratégies thérapeutiques. / Now that diabetes reaches pandemic proportions, this thesis focuses on the effect of T2DM on bone. Very few studies document the effect of T2DM on maxillo-facial bone and their endomembraneous repair.After a short review on bone, diabetes and animal study models, we will showcase our results of the impact of T2DM on, (i) vascular and bone repair of calvarial defects in ZDF rats; (ii) the vascular and bone microarchitechture of ZDF rat’s femur; (iii) the secretome and angiogenic properties of zdf rat’s bone marrow stromal cells (BMSC). These studies showed an alteration of bone repair in critical size defects, and an impaired vascular repair in critical and subcritical T2DM defects. We also found evidences of bone and vascular microarchitechture impairement in ZDF femur. At a cellular level, T2DM BMSCs have an unique angiogenic profile. These findings may contribute to the better understanding of the adverse vascular healing in T2DM and provide successful bone healing therapies for patients with T2DM.

TD2M

Cicatrisation osseuse

Réparation vasculaire

TD2M

Bone healing

Vascular repair

Silencing Endothelial EphA4 Alters Transcriptional Regulation of Angiogenic Factors to Promote Vessel Recovery Following TBI

McGuire, David Robert

09 July 2020

Traumatic brain injury (TBI) can cause a number of deleterious effects to the neurovascular system, including reduced cerebral blood flow (CBF), vascular regression, and ischemia, resulting in cognitive decline. Research into therapeutic targets to restore neurovascular function following injury has identified endothelial EphA4 receptor tyrosine kinase as a major regulator of vascular regrowth. The research outlined herein utilizes an endothelial-specific EphA4 knockout mouse model (KO-EphA4flf/Tie2-Cre) to determine the extent to which this receptor may influence vascular regrowth following TBI. Analysis of the colocalization and proximity of endothelial and mural cell markers (i.e. PECAM-1 and PDGFRβ, respectively) in immunohistochemically-stained brain sections demonstrates that EphA4 silencing does not seem to affect the physical association between, nor total amounts of, endothelial cells and pericytes, between genotypes by 4 days post-injury (dpi). Nevertheless, these measures demonstrate that these cell types may preferentially proliferate and/or expand into peri-lesion tissue in both KO-EphA4flf/Tie2-Cre) and WT-EphA4fl/fl mice. These data further suggest that both genotypes experience homogeneity of PECAM-1 and PDGFRβ expression between regions of the injury cavity. Gene expression analysis using mRNA samples from both genotypes reveals that KO-EphA4flf/Tie2-Cre CCI-injured mice experience increased expression of Vegfa, Flt1, and Fn (Fibronectin) compared to sham-injured condition knockouts. These results demonstrate changes in expression of angiogenic factors in the absence of early differences in patterns of vessel formation, which may underlie improved vascular regrowth, as well as outline a potential mechanism wherein the interplay between these factors and EphA4 silencing may lead to improved cognitive outcomes following TBI. / Master of Science / Every day in the United States, an average of 155 people die due to the consequences of traumatic brain injury (TBI), with many survivors suffering life-long debilitating effects, including deficits in behavior, mobility, and cognitive ability. Because of this, there is a need for researchers to identify therapeutic strategies to stimulate recovery and improve patient outcomes. Recent advancements in the field of vascular biology have identified the regrowth of the blood vessels in the brain following TBI-induced damage as an important step in the recovery process, since the resulting increases in blood flow to damaged tissue will provide oxygen and nutrients necessary to fuel recovery. The work presented in this Masters thesis follows in this vein by examining a protein receptor known as EphA4, which is found on cells within blood vessels and has been implicated in reducing the rate of vessel growth under injury conditions. By blocking the activity of EphA4, we hoped to find increased vascular regrowth following brain injury in mice. During the experiments outlined herein, it was found that there were no statistically significant differences in vessel-associated cell densities between mice with or without EphA4 activity 4 days after injury, but there were differences in the levels of proteins and/or signals associated with vessel growth. Based on these results, we conclude that removing EphA4 activity increases expression of these pro-vessel growth proteins in mouse brains following injury at these early time points, potentially leading to increased vessel growth and improved recovery over subsequent weeks following injury.

Ephrin receptor tyrosine kinase

Vascular repair

Pericytes

Endothelial cells

Heparan sulphate releasing biomaterials for tissue engineering

Emma Luong-van

Unknown Date

Tissue repair is a complex process that is difficult to emulate. The addition of the glycosaminoglycan heparan sulfate (HS), a multi-potential regulator of numerous growth factors and cytokines endogenously expressed during the repair process, may represent a valuable tool for tissue engineering. The addition of exogenous HS into wound site has previously been shown to promote tissue repair in a number of models, however, the incorporation of HS into controlled release systems or biomaterials for tissue engineering had not been explored prior to the work presented here. Thus, this thesis explores the incorporation of HS and its analogue heparin into synthetic biodegradable polymer biomaterials with different potential applications, either as a slow releasing drug reservoir, or as a drug releasing cell scaffold. Polycaprolactone was used to make microcapsules and electrospun fibers for HS or heparin entrapment. These materials were characterized for their drug release profiles, biocompatibility and bioactivity. Microcapsules encapsulating heparin or HS were made by the oil - in - water solvent evaporation method which allowed fabrication of slow releasing drug reservoirs. Either pure water or a poly(vinyl alcohol) solution was used in the drug phase which resulted in capsules with similar size and drug loading. However the internal morphology and drug release profiles showed differences depending on the drug phase, in either case release was sustained for over 30 days. These capsules elicited no pro-inflammatory response from macrophages in vitro, and the released HS retained its bioactivity to induce the proliferation of human mesenchymal stem cells, an important cell type for bone tissue engineering. Heparin and HS were incorporated into electrospun fibers as a drug releasing scaffold for two different tissue engineering applications. Heparin fibers were studied as a drug releasing membrane that could be used in vascular repair to prevent the unwanted proliferation of vascular smooth muscle cells. Heparin release was sustained from the fibers for at least 2 weeks. The fibers did not induce a pro-inflammatory response from macrophages in vitro and the released heparin retained the ability to inhibit the proliferation in vascular smooth muscle cells. HS fibers were studied as a tissue engineering scaffold for bone repair using human mesenchymal stem cells. HS release was maintained for over 30 days which is thought to be an appropriate time for bone repair applications. The release profiles depended on the HS concentration in the spinning solution which affected the morphology of the fibers. The fibers did not elicit a pro-inflammatory response in cultured macrophages and supported the proliferation and mineralization of human mesechymal stem cells. The HS fibers were then taken through to an in vivo model to study ectopic bone formation of pre-osteoblast cells on HS releasing scaffolds. The fibers produced a chronic inflammatory response in vivo, which lead to the clearance of implanted cells and no mineralization of the scaffold. The HS and heparin materials made in this work showed sustained release over appropriate time frames for different tissue repair applications. The released HS and heparin maintained bioactivity and showed good biocompatibility in vitro, however, further in vivo studies are required to fully test their efficacy for tissue engineering.

06 Biological Sciences

Heparan sulphate

heparin

regenerative medicine

polycaprolactone

drug delivery

microencapsulation

electrospinning

bone repair

vascular repair

Étude des interactions entre les cellules progénitrices endothéliales et l’adiponectine

Lavoie, Véronique

11 1900

L’adiponectine, une adipokine aux niveaux plasmatiques inversement associés aux composantes du syndrome métabolique, protège contre l’athérosclérose et réduit les risques d’infarctus du myocarde. Les cellules progénitrices endothéliales (EPCs) jouent un rôle dans la réparation vasculaire et leur nombre est réduit chez les patients atteints de maladies cardiovasculaires. Nous croyons que les effets de l’adiponectine peuvent s’expliquer entre autres via ses interactions avec les EPCs. Trois sous-population d’EPCs, isolées du sang de donneurs sains, ont été caractérisées par immunophénotypage par cytométrie en flux. L’expression des récepteurs de l’adiponectine, AdipoR1, AdipoR2 et H-cadherin par les EPCs et les cellules endothéliales a été évaluée par qPCR. Les effets de l’adiponectine sur la migration et l’apoptose des EPCs et sur l’apoptose des HUVECs ont été étudiés. L’expression de l’élastase des neutrophiles par les EPCs et son activité ont été testées. Les résultats de qPCR montrent que l’AdipoR1 est plus fortement exprimé que l’AdipoR2 alors qu’H-cadhérine n’est pas détectable dans les EPCs. Les EPCs précoces expriment aussi l’élastase. L’expression d’AdipoR1 a été confirmée par immunobuvardage. L’adiponectine augmente de façon significative la survie de deux sous-populations d’EPCs, mais pas celle des HUVECs, en condition de privation de sérum. L’activité de l’élastase a été confirmée dans le milieu conditionné par les EPCs. Les EPCs expriment les récepteurs de l’adiponectine et l’élastase. L’adiponectine protège les EPCs contre l’apoptose et pourrait augmenter leur capacité de réparation vasculaire. L’activité élastase des EPCs pourrait moduler localement l’activité de l’adiponectine par la génération de sa forme globulaire. / Adiponectin, an adipokine whose plasma levels are inversely correlated to metabolic syndrome components, protects against atherosclerosis and reduces myocardium infarction-associated risks. Endothelial progenitor cells (EPCs) are involved in vascular repair and their number is reduced in patients with cardiovascular disease. We hypothesized that positive effects of adiponectin against atherosclerosis are explained in part by its interaction with EPCs. EPCs were obtained from healthy volunteers’ venous blood by mononuclear cell isolation and plating on collagen-coated dishes. Three subpopulations of EPCs were characterized by flow cytometry immunophenotyping. Expression of adiponectin receptors, AdipoR1, AdipoR2 and H-cadherin was evaluated by qPCR in EPCs and endothelial cells. Effects of recombinant adiponectin on apoptosis of EPCs and HUVECs were assessed. Expression of neutrophil elastase by EPCs and enzymatic activity on adiponectin processing were assessed. Quantitative PCR of EPCs and HUVECs mRNA showed a higher expression of AdipoR1 compared to AdipoR2 and no expression of H-cadherin in EPCs. Expression of AdipoR1 in EPCs was confirmed by Western Blot. We demonstrated that early EPCs express neutrophil elastase. Adiponectin significantly increased survival of two subpopulations of EPCs in condition of serum deprivation but had no effects on HUVECs. Neutrophil elastase activity was confirmed in EPCs conditioned media. Adiponectin protects some EPCs subpopulations against apoptosis and therefore could modulate their involvement in vascular repair. Neutrophil elastase activity of EPCs could locally modify adiponectin activity by its ability to generate the globular form of adiponectin.

athérosclérose

apoptose

réparation vasculaire

adipokine

élastase des neutrophiles

atherosclerosis

apoptosis

vascular repair

neutrophil elastase

Heparan sulphate releasing biomaterials for tissue engineering

Emma Luong-van

Unknown Date

Tissue repair is a complex process that is difficult to emulate. The addition of the glycosaminoglycan heparan sulfate (HS), a multi-potential regulator of numerous growth factors and cytokines endogenously expressed during the repair process, may represent a valuable tool for tissue engineering. The addition of exogenous HS into wound site has previously been shown to promote tissue repair in a number of models, however, the incorporation of HS into controlled release systems or biomaterials for tissue engineering had not been explored prior to the work presented here. Thus, this thesis explores the incorporation of HS and its analogue heparin into synthetic biodegradable polymer biomaterials with different potential applications, either as a slow releasing drug reservoir, or as a drug releasing cell scaffold. Polycaprolactone was used to make microcapsules and electrospun fibers for HS or heparin entrapment. These materials were characterized for their drug release profiles, biocompatibility and bioactivity. Microcapsules encapsulating heparin or HS were made by the oil - in - water solvent evaporation method which allowed fabrication of slow releasing drug reservoirs. Either pure water or a poly(vinyl alcohol) solution was used in the drug phase which resulted in capsules with similar size and drug loading. However the internal morphology and drug release profiles showed differences depending on the drug phase, in either case release was sustained for over 30 days. These capsules elicited no pro-inflammatory response from macrophages in vitro, and the released HS retained its bioactivity to induce the proliferation of human mesenchymal stem cells, an important cell type for bone tissue engineering. Heparin and HS were incorporated into electrospun fibers as a drug releasing scaffold for two different tissue engineering applications. Heparin fibers were studied as a drug releasing membrane that could be used in vascular repair to prevent the unwanted proliferation of vascular smooth muscle cells. Heparin release was sustained from the fibers for at least 2 weeks. The fibers did not induce a pro-inflammatory response from macrophages in vitro and the released heparin retained the ability to inhibit the proliferation in vascular smooth muscle cells. HS fibers were studied as a tissue engineering scaffold for bone repair using human mesenchymal stem cells. HS release was maintained for over 30 days which is thought to be an appropriate time for bone repair applications. The release profiles depended on the HS concentration in the spinning solution which affected the morphology of the fibers. The fibers did not elicit a pro-inflammatory response in cultured macrophages and supported the proliferation and mineralization of human mesechymal stem cells. The HS fibers were then taken through to an in vivo model to study ectopic bone formation of pre-osteoblast cells on HS releasing scaffolds. The fibers produced a chronic inflammatory response in vivo, which lead to the clearance of implanted cells and no mineralization of the scaffold. The HS and heparin materials made in this work showed sustained release over appropriate time frames for different tissue repair applications. The released HS and heparin maintained bioactivity and showed good biocompatibility in vitro, however, further in vivo studies are required to fully test their efficacy for tissue engineering.

06 Biological Sciences

Heparan sulphate

heparin

regenerative medicine

polycaprolactone

drug delivery

microencapsulation

electrospinning

bone repair

vascular repair

Étude des interactions entre les cellules progénitrices endothéliales et l’adiponectine

Lavoie, Véronique

11 1900

No description available.

athérosclérose

apoptose

réparation vasculaire

adipokine

élastase des neutrophiles

atherosclerosis

apoptosis

vascular repair

neutrophil elastase

Investigating the deleterious effects of type 1 diabetes mellitus on microvascular repair in the mouse cortex

Mehina, Eslam

25 May 2021

Microglia and brain-resident macrophages are the sentinel immune cells of the central nervous system (CNS), and are ideally situated to respond to any damage to the brain parenchyma or vasculature. Circulating leukocytes are generally excluded from the CNS environment under homeostatic conditions but can gain access to this region in diseases that disrupt immune system function and blood-brain barrier integrity. Although these diverse immune cells exhibit properties that may engender them to be well-suited to resolve microcirculatory insults, their relative contributions to the recanalization of capillary rupture in the cortex, known as cerebral microbleeds (CMBs), has yet to be described. CMBs are particularly concerning in conditions, such as diabetes mellitus (DM), in which these insults occur more frequently and potentially underlie the onset and progression of cognitive decline. Using in vivo 2-photon microscopy and confocal imaging, here I highlight the compromised repair of CMBs in a mouse model of type 1 DM and characterize the robust, heterogeneous macrophage response to these insults. Specifically, 20% of damaged capillaries were eliminated from the circulation in the diabetic cortex and chronic insulin treatment failed to prevent this microvascular loss. Administration of interferon-α or interferon-γ neutralizing antibodies to dampen inflammatory signalling, or dexamethasone to reduce global inflammation, also failed to improve repair rates of damaged microvessels in diabetic mice. In contrast, CMBs in nondiabetic mice repaired without exception. Interestingly, depletion of CNS macrophages using the colony stimulating factor-1 receptor antagonist PLX5622 resulted in microvascular elimination in nondiabetic mice. Given the robust depletion of brain macrophage populations with this treatment, at first these data suggested that these cells were necessary for microvascular repair since their elimination produced vessel loss. However, by parsing the data I identified that microvessels repaired in all cases where macrophages were not identified at the CMB; when CX3CR1+ aggregate was localized to the injury, ~20% of microvessels were eliminated. These findings show that CNS macrophages are not required for microvascular repair following CMB. Immunofluorescent co-labelling of various microglial and macrophage markers within the diabetic CMB milieu revealed a novel population of Mac2+/TMEM119- cells, distinct from homeostatic TMEM119+ microglia. These cells reliably localized to CMBs that failed to repair and rarely associated with vessels that recanalized; Mac2+/TMEM119- cells were not found within nondiabetic CMBs. Treatment of diabetic mice with clodronate liposomes (CLR) to deplete circulating phagocytic leukocytes prevented aggregation of Mac2+/TMEM119- cells to CMBs and improved capillary repair rates. The efficacy of CLR in excluding these cells from the CMB aggregate, coincident with eradication of monocytes from circulation, indicated that these cells likely arose from the periphery. In vivo 2-photon imaging revealed significant increases in lipofuscin at the site of diabetic CMBs relative to the nondiabetic context; other phagocytic markers including CD68 and TREM2 were also upregulated. Mac2+/TMEM119- cells showed elevated lipofuscin content relative to homeostatic microglia; their association with CMBs may thus signal an increase in phagocytosis that contributes to capillary pruning. Taken together, these data identify a novel Mac2+/TMEM119- macrophage associated with pathological microvascular elimination following CMB in the diabetic neocortex. These findings highlight the diversity of immune cell responses to CNS injury and provide insights into the cellular mechanisms of capillary pruning. Furthermore, these advances in our understanding of the regulation of microvascular elimination in the diabetic brain may have clinical implications for patients with DM as they provide evidence for putative adjuvant anti-inflammatory treatments, such as CLR, in mitigating cerebrovascular pathology. / Graduate / 2022-05-06

microvessel

cerebral microbleed

vascular repair

inflammation

immune cells

microglia

macrophage

Mac2

type 1 diabetes mellitus

2-photon

confocal

in vivo imaging

clodronate

phagocytosis