Roles of focal adhesion proteins in skeleton and diseases

The skeletal system, which contains bones, joints, tendons, ligaments and other elements, plays a wide variety of roles in body shaping, support and movement, protection of internal organs, production of blood cells and regulation of calcium and phosphate metabolism. The prevalence of skeletal diseases and disorders, such as osteoporosis and bone fracture, osteoarthritis, rheumatoid arthritis, and intervertebral disc degeneration, increases with age, causing pain and loss of mobility and creating a huge social and economic burden globally. Focal adhesions (FAs) are macromolecular assemblies that are composed of the extracellular matrix (ECM), integrins, intracellular cytoskeleton and other proteins, including kindlin, talin, vinculin, paxillin, pinch, Src, focal adhesion kinase (FAK) and integrin-linked protein kinase (ILK) and other proteins. FA acts as a mechanical linkage connecting the ECM and cytoskeleton and plays a key role in mediating cell-environment communications and modulates important processes, such as cell attachment, spreading, migration, differentiation and mechanotransduction, in different cells in skeletal system by impacting distinct outside-in and inside-out signaling pathways. This review aims to integrate the up-to-date knowledge of the roles of FA proteins in the health and disease of skeletal system and focuses on the specific molecular mechanisms and underlying therapeutic targets for skeletal diseases.

Matrix Stiffness Affects Mitochondrial Heterogeneity of Tibial Plateau Chondrocytes in Knee Osteoarthritis / 医用生物力学

Objective To investigate the difference of matrix stiffness in different regions of tibial plateau in osteoarthritis (OA) and its effects on morphology of the cartilage and mitochondria. Methods The tibial plateau cartilage specimens of OA were obtained for nanoindentation test, transmission electron microscopy and histological analysis. The stiffness of cartilage matrix in different regions of OA tibial plateau was detected by nano-indentation. The morphology of cartilage mitochondria in different regions was observed by transmission electron microscopy, and the changes of mitochondrial plane area, shape and ridge volume density were quantitatively analyzed. Cartilage injury in different regions of OA tibial plateau was observed by histological staining. Results The cartilage of OA tibial plateau showed regional heterogeneity, and the cartilage and mitochondria on medial side of varus knee OA were more severe, and the matrix stiffness was higher. The OA scores were positively correlated with matrix stiffness. There was also a significant correlation between OA scores and mitochondrial morphology: the higher OA scores, the larger and rounder mitochondrial plane area, and the lower cristae volume density. Conclusions The differences of tibial plateau revealed the correlation between cartilage matrix stiffness, OA scores and mitochondrial morphological parameters. The increased cartilage matrix stiffness may be the main cause of chondrocyte mitochondrial injury, and further aggravate the progression of OA.

Advances in Mechanotransduction Pathway of Macrophage / 医用生物力学

Mechanical stimulation in micro-environment ( such as matrix stiffness, surface topography, cyclical stretch) can be perceived by macrophages through receptors on cell membrane, transmitted to the nucleus along the adhesion protein molecular chain and cytoskeleton, and also converted into biochemical signal to stimulate gene transcription. Mechanical stimulation drives various biological functions in macrophages, such as adhesion, proliferation, migration, and polarization, thereby playing a corresponding role in disease progression and tissue regeneration. This study demonstrates the role of micro-environment mechanics in macrophages polarization and function, and elucidates the related mechanism of mechanotransduction pathway in macrophages, so as to provide molecular biomechanics insights into the development of macrophage-targeting immunomodulatorybiomaterials.

Role of Chondrocyte Mechanotransduction in Development of Osteoarthritis / 医用生物力学

Abnormal mechanical loading is the main risk factor for the development of osteoarthritis (OA), and it can lead to collagen degradation, glycosaminoglycan loss and chondrocyte apoptosis, as well as damage to articular cartilage and subchondral bone. However, due to the lack of understanding in chondrocytes mechanotransduction pathway and invalid method of cartilage repair and regeneration, there is an urgent need for understanding chondrocytes mechanotransduction pathway and mechanism of cartilage damage induced by mechanical loading. In this review, how chondrocytes sense and transmit mechanical signals from cell membrane to cecullar mechanosensors is introduced in detail, and the role of chondrocytes mechanotransduction in OA development is discussed with emphasis.

Interactions between cells and biomaterials in tissue engineering: a review / 生物工程学报

Seed cells, biomaterials and growth factors are three important aspects in tissue engineering. Biomaterials mimic extra cellular matrix in vivo, providing a sound environment for cells to grow and attach, so as to maintain cell viability and function. The physicochemical properties and modification molecules of material surface mediate cell behaviors like cell adhesion, proliferation, migration and differentiation, which in turn affect cellular function and tissue regeneration efficacy. Furthermore, the modification molecules of material surface are the direct contact point for cell adhesion and growth. Therefore, the interactions between cells and surface modification molecules are the key to tissue engineering. This review summarizes the effects of surface modification molecules on cell phenotypes and functions.

Low-intensity pulsed ultrasound stimulates proliferation of stem/progenitor cells: what we need to know to translate basic science research into clinical applications / 亚洲男科学杂志(英文版)

Low-intensity pulsed ultrasound (LIPUS) is a promising therapy that has been increasingly explored in basic research and clinical applications. LIPUS is an appealing therapeutic option as it is a noninvasive treatment that has many advantages, including no risk of infection or tissue damage and no known adverse reactions. LIPUS has been shown to have many benefits including promotion of tissue healing, angiogenesis, and tissue regeneration; inhibition of inflammation and pain relief; and stimulation of cell proliferation and differentiation. The biophysical mechanisms of LIPUS remain unclear and the studies are ongoing. In recent years, more and more research has focused on the relationship between LIPUS and stem/progenitor cells. A comprehensive search of the PubMed and Embase databases to July 2020 was performed. LIPUS has many effects on stem cells. Studies show that LIPUS can stimulate stem cells in vitro; promote stem cell proliferation, differentiation, and migration; maintain stem cell activity; alleviate the problems of insufficient seed cell source, differentiation, and maturation; and circumvent the low efficiency of stem cell transplantation. The mechanisms involved in the effects of LIPUS are not fully understood, but the effects demonstrated in studies thus far have been favorable. Much additional research is needed before LIPUS can progress from basic science research to large-scale clinical dissemination and application.

Effects of chronic stretching on soleus muscle of Wistar female rats / Efectos del estiramiento crónico en el músculo sóleo de ratas hembras Wistar

The purpose of this study was to evaluate the chronic effects of stretching exercise on soleus muscle histomorphology and histomorphometry of young and aged rats. Thirty-eight female rats were divided into young control group (YCG, n=10;274±50 g); young stretching group (YSG, n=8;274±12 g); aged control group (ACG, n=10;335±39 g); and aged stretching group (ASG, n=10;321±32g). A mechanical apparatus was used to stretch muscle in 4 repetitions, 60 s each, 30 s interval between repetitions in each session, 3 times a week for 3 weeks. Twenty-four hours after the last stretching session, soleus muscle was removed for micromorphology and immunostaining analysis. Data analyses were performed with one-way ANOVA, post-hoc Tukey, or Kruskal-Wallis tests for parametric and nonparametric, respectively (p≤0.05). Muscle fiber cross-sectional area (MFCSA) of ACG was lower (18 %) compared to the YCG. Stretching increased MFCSA comparing YSG to YCG (5,681.15± 1,943.61 µm2 vs 5,119.84±1,857.73 µm2, p=0.00), but decreased comparing ASG to ACG (3,919.54± 1,694.65 µm2 vs 4,172.82±1,446.08 µm2, p=0.00). More serial sarcomere numbers were found in the YSG than YCG (12,062.91±1,564.68 vs 10,070.39±1,072.38, p=0.03). Collagen I and collagen III were higher in YSG than ASG (7.44±7.18 % vs 0.07±0.09 %, p=0.04) and (14.37 %± 9.54 % vs 5.51 %±5.52 %, p=0.00), respectively. TNF-a was greater in ASG than YSG (43.42 %±40.19 % vs 1.72 ± 2.02 %, p=0.00). Epimysium was larger in the YSG compared to YCG (201.83±132.07 % vs 181.09±147.04 %, p=0.00). After 3-week stretching the soleus muscles from aged rats were smaller than their younger counter-parts. Interestingly, while stretching appeared to positively affect young soleus muscle, the opposite was detected in the muscle of the aged rats.

El propósito de este estudio fue evaluar los efectos crónicos del ejercicio de estiramiento sobre la histomorfología e histomorfometría del músculo sóleo de ratas jóvenes y envejecidas. Se dividieron 38 ratas hembras en un grupo control joven (YCG, n = 10; 274 ± 50 g); grupo de estiramiento joven (YSG, n = 8; 274 ± 12 g); grupo control de edad (ACG, n = 10; 335 ± 39 g); y grupo estiramiento envejecido (ASG, n = 10; 321 ± 32 g). Se usó un aparato mecánico para estirar el músculo en 4 repeticiones, 60 s cada una, intervalo de 30 s entre repeticiones en cada sesión, 3 veces por semana, durante 3 semanas. Veinticuatro horas después de la última sesión de estiramiento, se extrajo el músculo sóleo para análisis de micromorfología e inmunotinción. Los análisis de datos se realizaron con pruebas ANOVA de una vía, Tukey post-hoc o Kruskal-Wallis para pruebas paramétricas y no paramétricas, respectivamente (p≤0,05). El área de la sección transversal de fibra muscular (MFCSA) de GCE fue menor (18 %) en comparación con el GCJ. El estiramiento aumentó ASTFM comparando GEJ con GCJ (5.681,15 ± 1.943,61 µm2 vs 5.119,84 ± 1.857,73 µm2, p = 0,00), pero disminuyó comparando GEE con GCE (3.919,54 ± 1.694,65 µm2 vs 4.172,82 ± 1.446,08 µm2, p = 0,00). Se encontraron más sarcómeros en serie en el GEJ que en el GCJ (12.062,91 ± 1.564,68 vs 10.070,39 ± 1,072.38, p = 0,03). El colágeno I y el colágeno III fueron más numerosos en GEJ que en GEE (7,44 ± 7.18 % vs 0,07 ± 0,09 %, p = 0,04) y (14,37 % ± 9,54 % vs 5,51 % ± 5,52 %, p = 0,00), respectivamente. TNF-α fue mayor en GEE que GEJ (43,42 % ± 40,19 % vs 1,72 ± 2,02 %, p = 0,00). El epimisio fue mayor en el GEJ en comparación con el GCJ (201,83 ± 132,07 % vs 181,09 ± 147,04 %, p = 0,00). Después de 3 semanas de estiramiento, los músculos sóleo de las ratas envejecidas eran más pequeños que sus contrapartes más jóvenes. Curiosamente, si bien el estiramiento pareció afectar positivamente el músculo sóleo joven, se detectó lo contrario en el músculo de las ratas envejecidas.

Biomechanical Effects of Primary Cilia in Articular Cartilage / 医用生物力学

Biomechanical factors play a crucial role in the steady-state maintenance of articular cartilage. The primary cilium (PC) is a kind of organelle which can sense mechanical and chemical signals at the same time. It is also distributed on the surface of chondrocyte membrane. It is involved in multiple signal transduction pathways as well as in the process of chondrocyte phenotype maintenance and material metabolism. Abnormalities in PC are also associated with a variety of human bone and joint diseases. This paper mainly discusses the mechanism of PC in mechanical microenvironment of chondrocytes and the interaction with other signaling pathways, and explores its relationship with bone and joint diseases, so as to provide some scientific basis for clinical and basic research in orthopedics.

The Trans-Scale Conduction Behavior of Fluid Stimulation in Loaded Bone / 医用生物力学

Objective To investigate the conduction behavior of fluid flow induced by physiological loads at different scales of bone. Method sThe multiscale bone models were established by using the COMSOL Multiphysics software, and the fluid behaviors were investigated at macro-, meso- and micro-scale. Results At macro-meso scale，the distribution of pore pressure and fluid velocity of osteon near the periosteum and endoosteum were different from that in other parts. Due to the different structure and material parameters at different layers, the loading and fluid pressure caused different biomechanical responses in the process of transferring from macro-scale to micro-scale. Conclusions The multi-scale layered modeling of bone structure-osteon-lacunae-bone canaliculi was established, which provided the theoretical reference for deeper understanding of fluid stimulation and mechanotransduction.

Exercise Countermeasures for the Spine in Microgravity

Weakness and neuromuscular deconditioning of the anti-gravity spine muscles develop after 6-month missions in space. There is also a high incidence of herniated nucleus pulposus in cervical and lumbar discs with back pain post-flight. Prolonged microgravity reduces the physiological loading forces needed for spine homeostasis and may alter neuromuscular postural reflexes leading to injury upon return to 1G. Nine astronauts were tested using the Biering-Sorensen test to measure spine isometric endurance pre- and post-flight. The results show significant decrements in muscle isometric endurance and correlates with atrophy of the multifidus, erector spinae, quadratus lumborum and psoas, reduced cross-sectional area and functional cross-sectional area with MRI measurements. Current ISS exercise countermeasures appear to be insufficient in mitigating loss of spinal function due to lack of specifically designed exercises to address specific antigravity muscles. Intensity of resistance loading is proposed to be specific to the muscle isoform that needs the most optimal mechanotransduction using adjustable pulley resistance vectors in line or parallel to the target muscle fibre orientations. Pulley apparatus may be in the form of flywheel or pneumatic derived resistance. Since antigravity muscles are predominantly Type I muscle isoform, endurance and stability are the main functional qualities which would require higher repetitions in good form, moderate resistance, and multiple sets. This proposal is intended to define efficient type of spine exercises to counter the maladaptive effects from prolonged spaceflight and lead to accepted countermeasures. Supported by NASA Grants NNXlOAM18G and NNX13AM89G.

La debilidad y el desacondicionamiento neuromuscular de los músculos de la columna vertebral encargados de la anti-gravedad aparecen a partir del sexto mes de estancia en el espacio. En la etapa posterior al vuelo también se observa una elevada incidencia de núcleos pulposos herniados en discos cervicales y lumbares con dolor de espalda. La microgravedad prolongada reduce las fuerzas de carga fisiológica necesarias para la homeostasis de la columna vertebral, además de que puede alterar los reflejos posturales neuromusculares provocando lesiones al regresar a 1G. Nueve astronautas fueron evaluados con la prueba de Biering-Sorensen para medir la resistencia isométrica de la columna vertebral antes y después del vuelo. Los resultados muestran decrecimientos significativos en la resistencia isométrica muscular y correlatos con atrofia del multifidus, erector spinae, quadratus lumborum y psoas, reducción del área transversal y área transversal funcional con mediciones IRM. Las contramedidas actuales de la EEI para los ejercicios parecen ser insuficientes para mitigar la pérdida de función espinal provocada por la falta de ejercicios dirigidos a músculos antigravedad específicos. Se propone que la intensidad de la carga de resistencia sea específica para la isoforma muscular que requiere la mecanotransducción más óptima usando vectores de resistencia de polea ajustables alineados o paralelos a las orientaciones de la fibra muscular a que estén dirigidos. El dispositivo de poleas puede tomar la forma de volante o de resistencia derivada de fuerza neumática. Como los músculos antigravedad son predominantemente isoformas musculares Tipo I, la resistencia y la estabilidad son las principales cualidades funcionales que requerirían mayores repeticiones en buena forma, resistencia moderada y múltiples ciclos. La propuesta que aquí se presenta está dirigida a definir el tipo eficiente de ejercicios para la columna vertebral para contrarrestar los efectos de adaptación inadecuada provocados por un vuelo espacial prolongado, así como avanzar hacia la creación de contramedidas aceptables. Realizado con el apoyo de las subvenciones de la NASA NNXlOAM18G y NNX13AM89G.

LINC Complex and Intracellular Mechanotransduction / 医用生物力学

As mechanoreceptors, cells can sense and transmit mechanical forces exerted on their surfaces, meanwhile adjust their own mechanical properties to maintain stability. The mechanical force is transferred from cell surface or cytoplasm to the nucleus depending on the complete cytoskeletal system. This cytoskeletal system consists of cytoplasmic skeleton and nuclear skeleton, and these two parts are connected mechanically by the LINC complex (linker of nucleoskeleton and cytoskeleton complex), which plays an important role in cellular mechanotransduction. This review discusses the basic structure of mechanical transmission part in LINC complex and the changes in the nuclear morphology, the location of transcription factor, and the spatial conformation of chromatin induced by mechanotransduction, so as to lay a foundation for further exploring the role of LINC complex in cell mechanotransduction and gene expression.

Effects of Microenvironment on Osteogenesis of Bone Marrow Mesenchymal Stem Cells Through Cytoskeleton Tension / 医用生物力学

Extracellular matrix is the main element to provide mechanical clues for cells. The response of stem cells to mechanical signals is mainly achieved through the cytoskeleton. After mechanical signal is transmitted, cytoskeleton can form contractile microfilaments that actively generate tension through reorganization induced by microenvironment changes. The mechanical signals can regulate gene expression through either coupling with the nuclear skeleton directly or being transformed by the second message. Recent studies have proven that cytoskeleton tension has a series of impact on lineage specification, proliferation, differentiation and apoptosis of bone mesenchymal stem cells (BMSCs). BMSCs are of great significance in bone reconstruction and clinical treatment. The possible mechanisms about mechanotransduction and its effects of cytoskeleton tension on osteogenesis of BMSCs after micro-environmental changes were summarized.

Trypanosoma cruzi down-regulates mechanosensitive proteins in cardiomyocytes

BACKGROUND Cardiac physiology depends on coupling and electrical and mechanical coordination through the intercalated disc. Focal adhesions offer mechanical support and signal transduction events during heart contraction-relaxation processes. Talin links integrins to the actin cytoskeleton and serves as a scaffold for the recruitment of other proteins, such as paxillin in focal adhesion formation and regulation. Chagasic cardiomyopathy is caused by infection by Trypanosoma cruzi and is a debilitating condition comprising extensive fibrosis, inflammation, cardiac hypertrophy and electrical alterations that culminate in heart failure. OBJECTIVES Since mechanotransduction coordinates heart function, we evaluated the underlying mechanism implicated in the mechanical changes, focusing especially in mechanosensitive proteins and related signalling pathways during infection of cardiac cells by T. cruzi. METHODS We investigated the effect of T. cruzi infection on the expression and distribution of talin/paxillin and associated proteins in mouse cardiomyocytes in vitro by western blotting, immunofluorescence and quantitative real-time polymerase chain reaction (qRT-PCR). FINDINGS Talin and paxillin spatial distribution in T. cruzi-infected cardiomyocytes in vitro were altered associated with a downregulation of these proteins and mRNAs levels at 72 h post-infection (hpi). Additionally, we observed an increase in the activation of the focal adhesion kinase (FAK) concomitant with increase in β-1-integrin at 24 hpi. Finally, we detected a decrease in the activation of FAK at 72 hpi in T. cruzi-infected cultures. MAIN CONCLUSION The results suggest that these changes may contribute to the mechanotransduction disturbance evidenced in chagasic cardiomyopathy.

Research on the correlation between mechanical signaling molecules of hypertrophic scar and post injury time in burn patients in scar remodeling stage / 中华烧伤杂志

Objective@#To analyze the correlation between integrin β1, focal adhesion kinase (FAK), extracellular signal-regulated kinase 1/2 (ERK1/2) of hypertrophic scar (HS) and post injury time in burn patients in scar remodeling stage.@*Methods@#Thirty-four patients with 34 HS specimens admitted to Department of Burns and Plastic Surgery of Chengdu No.2 Hospital and Institute of Burn Research of the First Affiliated Hospital of Army Medical University (originally the Third Military Medical University) from May 2013 to April 2016 were recruited by convenient sampling method, and normal skin specimens were obtained from donor sites of another 6 patients from the above-mentioned departments who had scar resection and skin grafting for this cross-sectional and observational study. Vancouver Scar Scale (VSS) was used to assess the height, vascularity, pigmentation, and pliability of scars. Diasonograph was used to assess scar thickness. Immunohistochemical method was used to observe the expressions of integrin β1, FAK, and ERK1/2 in dermis and epidermis of scar and normal skin. Correlations between the post injury time and the scar thickness, the post injury time and the expressions of integrin β1, FAK, and ERK1/2 in epidermis of scar, the post injury time and the expressions of integrin β1, FAK, and ERK1/2 in dermis of scar, the expressions of integrin β1, FAK, and ERK1/2 in dermis and those in epidermis of scar were analyzed by Pearson correlation analysis. Locally estimated scatterplot smoothing curve fitting line was used to demonstrate the non-linear regression relationship between the expressions of integrin β1, FAK, and ERK1/2 in dermis and those in epidermis of scar, the scar thickness and the post injury time.@*Results@#(1) The total VSS score of scars of patients was (8.3±2.3) points, with height scored (2.2±0.7) points, vascularity scored (2.0±0.8) points, pigmentation scored (2.3±0.7) points, and pliability scored (1.9±0.7) points. The thickness of scar was (2.8±1.1) mm. (2) The expressions of integrin β1, FAK, and ERK1/2 in dermis and epidermis of scar were more than those in normal skin. (3) There was significantly positive correlation between the scar thickness and the post injury time (r=0.39, P<0.05). There was significantly positive correlation between the expression of integrin β1 in epidermis of scar and the post injury time (r=0.33, P<0.05). There were no significantly correlations between the expressions of FAK and ERK1/2 in epidermis of scar and the post injury time (r=-0.03, -0.04, P>0.05). There was significantly negative correlation between the expression of FAK in dermis of scar and the post injury time (r=-0.34, P<0.05). There were no significantly correlations between the expressions of integrin β1 and ERK1/2 in dermis of scar and the post injury time (r=0.07, -0.23, P>0.05). There were significantly positive correlation between the expressions of integrin β1, FAK, and ERK1/2 in dermis and those in epidermis of scar (r=0.70, 0.60, 0.64, P<0.01). (4) The expressions of integrin β1, FAK, and ERK1/2 in dermis and epidermis of scar were changed from downtrend in 1 to 2 months post injury to uptrend in 2 to 3 months post injury, which reached the peak around 3 to 4 months post injury. Hereafter the expressions of mechanical signaling molecules in epidermis of scar were gradually declined, while the expressions of mechanical signaling molecules in dermis of scar were at a quite high level within half a year post injury. Scar thickness was steadily increased after 1 month post injury.@*Conclusions@#In scar remodeling stage of burn patients, the HS thickness increases continuously along with the increasing post injury time in the early stage of scar formation. The vulnerability of integrin β1, FAK, and ERK1/2 of HS to external mechanical stimuli increases gradually within 4 months post injury.

Effects of Fluid Shear Stress on Gene Expression of Piezo1 in the Cells During Osteogenic Differentiation / 医用生物力学

Objective To investigate the gene expression of Piezo1 in four types of bone cells at different stages of osteogenic differentiation under fluid shear stress (FSS). Methods The mouse-derived mesenchymal stem cells (MSC), osteoblast-like cells MC3T3-E1, post-osteoblasts MLO-A5 and osteocytes MLO-Y4 were exposed to FSS at different magnitude (0.1, 1.1 Pa) with a custom-made cone-plate flow chamber for 0.5, 1, 3, 6, 12 h, respectively. The expression of Piezo1 mRNA was assessed by quantitative real-time polymerase chain reaction. Results Both Piezo1 and Piezo2 were expressed in four types of bone cells. The expression of Piezo1 was significantly up-regulated in all cells under FSS stimulation, and the expression level under 1.1 Pa FSS was significantly higher than that under 0.1 Pa FSS. In addition, the expression of Piezo1 in MSC, MC3T3-E1 and MLO-A5 cells increased to the highest level at 1 h under FSS stimulation. The expression of Piezo1 in MC3T3-E1 cells was much higher than that in the other three types of cells. Conclusions The expression of Piezo1 was related to the process of osteogenic differentiation, FSS level and loading time, and this research finding is of great significance to reveal the mechanism of mechanotransduction in bone tissues and to establish clinical treatment for bone diseases.

Research progress on Mechanism of Fluid Shear Stress in Osteogenesis of Bone Mesenchymal Stem Cells / 医用生物力学

Cells are exposed to mechanical stress, such as fluid shear stress (FSS), mechanical strain, hydrostatic pressure in vivo. FSS is considered to be the most important stress during bone homeostasis and remodeling. At present, most studies are mainly about the FSS effect on osteocytes and osteoblasts. However, the effects of FSS on bone mesenchymal stem cell (BMSCs) are not fully understood. BMSCs are of great significance in bone reconstruction and clinical treatment, so researchers increasingly focus on the response of BMSCs to FSS. The response of BMSCs to FSS depends on the alteration of cytoskeleton, matrix stiffness and elasticity, osteogenic signaling pathways and so on. In this review paper, the recent researches about the mechanotransduction mechanism of FSS, and its effect on differentiation and function of BMSCs are summarized, so as to provide new insights for studying construction of tissue engineered bone and treatment of bone diseases.

Research progress in mechanical alteration-activated chondrocytes-mediated post-traumatic osteoarthritis / 复旦学报（医学版）

Post-traumatic osteoarthritis (PTOA) has been drawing great attention clinically because of its tight connections with sports medicine and complicated pathogenesis as well as difficulties to heal.Chondrocyte is the only cell type in articular cartilage,and it plays an important role in the pathogenesis and progression of PTOA.Recent years,researchers mostly focus on the mechanisms,signaling and potential targets to treat osteoarthritis.Combined effects of biomechanics and the imbalance between pro-inflammation and anti-inflammation induce the PTOA eventually.This review would make a summary of the pathogenesis based on the research progress of mechanical alterationactivated chondrocytes-mediated PTOA.

Evaluation of apoptosis and osteopontin expression in osteocytes exposed to orthodontic forces of different magnitudes

The in vivo response of osteocytes to different force magnitudes soon after they are applied remains to be elucidated. The aim of this study was to examine the early effects of applying a very light (LF: 0,16 N) and a very strong (SF: 2,26 N) orthodontic force during one hour on apoptosis and osteopontin (OPN) expression on alveolar bone osteocytes, in rats. Results: LF: compared to the control group, they showed a significant increase in OPN expression, and a significant decrease in the number of TUNELpositive osteocytes. SF: compared to the control group, they showed a significant increase in OPN expression and a significant decrease in the number of TUNELpositive osteocytes. Our results show that osteocytes respond very early to the application of tension and pressure forces of different magnitudes, and application of forces decreases the number of apoptotic osteocytes and increases OPN expression. These results allow concluding that osteocytes activate rapidly when subjected to locally applied forces, whether these forces be pressure or tension, light or strong forces. Grants: UBACyT 200201301002270 BA and School of Dentistry, University of Buenos Aires (AU)

Hasta el momento no se ha dilucidado la respuesta temprana in vivo de los osteocitos a la aplicación de fuerzas de diferentes magnitudes sobre el hueso. El objetivo de este estudio fue examinar la respuesta temprana de la aplicación de una fuerza ortodóncica muy liviana (FL: 0,16 N) y muy fuerte (FF: 2,26 N) durante una hora sobre la expresión de apoptosis y osteopontina (OPN) en los osteocitos del hueso alveolar, en ratas. Resultados: FL: en comparación con el grupo control, mostraron un aumento significativo en la expresión de OPN y una disminución significativa en el número de osteocitos TUNELpositivos. FF: en comparación con el grupo control, mostraron un aumento significativo en la expresión de OPN y una disminución signi ficativa en el número de osteocitos TUNELpositivos. Nuestros resultados muestran que los osteocitos responden muy temprano a la aplicación de fuerzas de tensión y presión de diferentes magnitudes, y la aplicación de fuerzas disminuye el número de osteocitos apoptóticos y aumenta la expresión de OPN. Estos resultados permiten concluir que los osteocitos se activan rápidamente cuando se los somete a fuerzas aplicadas localmente, ya sean estas fuerzas de presión o tensión, livianas o fuertes (AU)

Perioperative implication of the endothelial glycocalyx / 대한마취과학회지

The endothelial glycocalyx (EG) is a gel-like layer lining the luminal surface of healthy vascular endothelium. Recently, the EG has gained extensive interest as a crucial regulator of endothelial funtction, including vascular permeability, mechanotransduction, and the interaction between endothelial and circulating blood cells. The EG is degraded by various enzymes and reactive oxygen species upon pro-inflammatory stimulus. Ischemia-reperfusion injury, oxidative stress, hypervolemia, and systemic inflammatory response are responsible for perioperative EG degradation. Perioperative damage of the EG has also been demonstrated, especially in cardiac surgery. However, the protection of the EG and its association with perioperative morbidity needs to be elucidated in future studies. In this review, the present knowledge about EG and its perioperative implication is discussed from an anesthesiologist's perspective.

A supramolecular look at microenvironmental regulation of limbal epithelial stem cells and the differentiation of their progeny / Uma visão supramolecular sobre a regulação microambiental de células tronco epiteliais limbais e a diferenciação de sua progênie

ABSTRACT Various approaches have been taken to improve our knowledge of the microenvironmental regulation of limbal epithelial stem cells. Researchers have extensively investigated the roles of growth factors, survival factors, cytokines, enzymes, and permeable molecules secreted by the limbal cells. However, recent evidence suggests that stem cell fate (i.e., self-renewal or differentiation) can also be influenced by biophysical and mechanical cues related to the supramolecular organization and the liquid crystalline (mesophase) nature of the stromal extracellular matrix. These cues can be sensed by stem cells and transduced into intracellular biochemical and functional responses, a process known as mechanotransduction. The objective of this review is to offer perspectives on the supramolecular microenvironmental regulation of limbal epithelial stem cells and the differentiation of their progeny.

RESUMO Muitas abordagens têm sido utilizadas para ampliar entendimentos sobre a regulação microambiental das células tronco epiteliais limbais. Neste contexto, pesquisadores têm exaustivamente investigado a participação de fatores de crescimento, fatores de sobrevida, citocinas, enzimas e moléculas permeáveis secretadas pelas células limbais. Entretanto, evidências recentes sugerem que o destino (ie. autorrenovação ou recrutamento para a via de diferenciação) das células tronco também sofre influência de estímulos biofísicos ou mecânicos relacionados à organização supramolecular e à natureza liquido-cristalina (mesofases) da matriz extracelular estromal. Esses estímulos podem ser percebidos e traduzidos pelas células tronco em sinais bioquímicos que geram respostas funcionais, através de um processo designado de mecanotransdução. Objetiva-se, com a presente revisão, oferecer ao leitor perspectivas supramoleculares sobre a regulação microambiental das células tronco epiteliais limbais e a diferenciação de sua progênie.