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OBJECTIVE@#This study aimed to reveal the insomnia burden and relevant influencing factors among informal caregivers (ICs) of hospitalized patients with lung cancer.@*METHODS@#A cross-sectional study on ICs of hospitalized patients with lung cancer was conducted from December 31, 2020 to December 31, 2021. ICs' burden was assessed using the Caregiver Reaction Assessment (CRA), Hospital Anxiety and Depression Scale (HADS), and Insomnia Severity Index (ISI). Linear and logistic regression models were used to identify the influencing factors.@*RESULTS@#Among 289 ICs of hospitalized patients with lung cancer, 83 (28.72%), 53 (18.34%), and 14 (4.84%) ICs experienced mild, moderate, and severe insomnia, respectively. The scores concerning self-esteem, lack of family support, financial problems, disturbed schedule, and health problems were 4.32 ± 0.53, 2.24 ± 0.79, 2.84 ± 1.14, 3.63 ± 0.77, and 2.44 ± 0.95, respectively. ICs with higher Activities of Daily Living Scale (ADLS) scores were associated with a lower risk of insomnia, with an odd ratio ( OR) and 95% confidence interval ( CI) of 0.940 (0.898-0.983). Among the ICs, female gender ( OR = 2.597), alcohol consumption ( OR = 3.745), underlying medical conditions ( OR = 11.765), long-term caregiving experience ( OR = 37.037), and higher monthly expenses ( OR = 5.714) were associated with a high risk of insomnia.@*CONCLUSION@#Of the hospitalized patients with lung cancer, 51.9% experienced insomnia. Patients' ADL, ICs gender, alcohol consumption, underlying medical conditions, caregiving duration, and monthly expenses were influencing factors. Therefore, prompt screening and early intervention for ICs of patients with lung cancer is necessary.
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Humans , Female , Caregivers , Activities of Daily Living , Cross-Sectional Studies , Sleep Initiation and Maintenance Disorders/epidemiology , Lung Neoplasms/epidemiologyABSTRACT
Objective To explore the effect of hypergravity on morphology and osteogenesis function of preosteoblast MC3T3-E1 ceils.Methods The cultured MC3T3-E1 cells under hypergravity by different loading forces were divided into five groups,including control group,5 g group,10 g group,15 g group and 20 g group.The experimental groups were loaded for 30 min each time in 3 successive days,and the control group with no g-value was synchronously exposed to the same surrounding.The morphology of cytoskeletal protein was observed by phalIoidin staining,The alkaline phosphatase (ALP) content was examined by ALP activity assay kit,the gene expression of ALP,collagen Ⅰ (Col Ⅰ),osteocalcin (OC),runt-related transcription factors (Runx2) was measured by real-time quantitative PCR,and the protein expression of Col Ⅰ and OC was tested by Western blotting.Results Under the condition of hypergravity,cell body of osteoblast became thinner,but its surface area increased significantly;with the structure of skeletal arrangement becoming loose,actin microfilament structure reduced so that the orderly arrangement of actin-like dispersion lowered.The gene expressions of related indicators of osteogenic differentiation including ALP,Col][,OC,Runx2 were significantly up-regulated,which was the same as Col Ⅰ protein and OC protein after hypergravity loading.A very minute quantity of small red-orange nodules was found in the control group,while the cells in experimental groups after hypergravity loading obviously formed various sizes of red-orange nodules.Conclusions Under hypergravity,changes in osteoblast morphology can be triggered by rearrangements of skeletal structure.Furthermore,osteoblast maturation and differentiation can be stimulated effectively by up-regulating differentiation-related gene and protein expressions.
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Objective To explore the effect of hypergravity on morphology and osteogenesis function of preosteoblast MC3T3-E1 ceils.Methods The cultured MC3T3-E1 cells under hypergravity by different loading forces were divided into five groups,including control group,5 g group,10 g group,15 g group and 20 g group.The experimental groups were loaded for 30 min each time in 3 successive days,and the control group with no g-value was synchronously exposed to the same surrounding.The morphology of cytoskeletal protein was observed by phalIoidin staining,The alkaline phosphatase (ALP) content was examined by ALP activity assay kit,the gene expression of ALP,collagen Ⅰ (Col Ⅰ),osteocalcin (OC),runt-related transcription factors (Runx2) was measured by real-time quantitative PCR,and the protein expression of Col Ⅰ and OC was tested by Western blotting.Results Under the condition of hypergravity,cell body of osteoblast became thinner,but its surface area increased significantly;with the structure of skeletal arrangement becoming loose,actin microfilament structure reduced so that the orderly arrangement of actin-like dispersion lowered.The gene expressions of related indicators of osteogenic differentiation including ALP,Col][,OC,Runx2 were significantly up-regulated,which was the same as Col Ⅰ protein and OC protein after hypergravity loading.A very minute quantity of small red-orange nodules was found in the control group,while the cells in experimental groups after hypergravity loading obviously formed various sizes of red-orange nodules.Conclusions Under hypergravity,changes in osteoblast morphology can be triggered by rearrangements of skeletal structure.Furthermore,osteoblast maturation and differentiation can be stimulated effectively by up-regulating differentiation-related gene and protein expressions.
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Objective To construct a three-dimensional (3D) solid model of the cortical bone including osteons,verify the stress concentration effect of osteons,simulate and predict the stress concentration location under fatigue using finite element analysis (FEA).Methods The 3D solid model of the cortical bone including osteons was constructed in Pro/E wildfire 5.0,and local stress and strain distributions in the cortical bone under different axial compression were calculated and analyzed in ANSYS 12.0.Fatigue simulation on the selected locations was conducted to evaluate fatigue status of the model subjected to different fatigue loading intensities.Results Obvious stress concentration at the junction of osteon and the interstitical bone appeared under axial compressive loads,and the percentage of pathological local strain in the cortical bone increased with the axial compression increasing.Fatigue simulation on the selected locations demonstrated that bone fatigue risk during physiological or daily activities was very low,while a high fatigue or fracture risk might occur during high-intensity exercises or training.Conclusions The 3 D solid model of the cortical bone including osteons is successfully established,the stress concentration effect of osteons is verified,and the location of bone fatigue damage under strenuous exercise and its risk are predicted.These experimental results can provide references for training management and athletic fatigue damage prevention in military recruits and long distance running athletes.
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Objective To study the effect of the icariin on apoptosis and cytoskeleton of osteoblasts in response to overload damage. Methods The four-point bending loading device was used to simulate the mechanical environment of overload damage and establish the cell overload damage model. According to whether the drugs were added before or after mechanical loading, the experiment was divided into blank control group, icariin group, damage group, damage prevention group and damage treatment group. Cell apoptosis was detected by flow cytometry. The specific fluorescent dyes were used to label the actin filament and the nucleus, and the changes of cytoskeleton were observed under laser scanning confocal microscope. Results Compared with control group, the apoptosis rate of damage group was the highest, and the icariin group was the lowest (P<0.05). Compared with damage group, the apoptosis rate of the damage prevention group was the lowest (P<0.05). The damage group showed cell shrinkage deformation, microfilaments disorganization, loosely arranged skeleton with vague outline, even broken skeleton. The morphological changes of cytoskeleton in damage prevention group were not significant, and there was no obvious change in cell nucleus. Conclusions Icariin can inhibit the apoptosis of osteoblasts after overload injury and maintain the stability of cytoskeleton to some extent.
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Objective To explore the effect of hypergravity on morphology and osteogenesis function of preosteoblast MC3T3-E1 cells. Methods The cultured MC3T3-E1 cells under hypergravity by different loading forces were divided into five groups, including control group, 5 g group, 10 g group, 15 g group and 20 g group. The experimental groups were loaded for 30 min each time in the three successive days, and the control group was synchronously exposed to the same surrounding except for difference in g-value. The morphology of cytoskeletal protein was observed by phalloidin staining, The alkaline phosphatase (ALP) content was examined by ALP activity assay kit, the gene expression of ALP, collagen Ⅰ(ColⅠ), osteocalcin (OC), runt-related transcription factors (Runx2) was measured by real-time quantitative PCR, and the protein expression of ColⅠ and OC was tested by Western blot. Results Under the condition of hypergravity, cell body of osteoblast became thinner, but its surface area increased significantly; with the structure of skeletal arrangement becoming loose, actin microfilament structure reduced so that arrangement of actin-like dispersion orderly lowered. The gene expressions of related indicators of osteogenic differentiation including ALP, ColⅠ, OC, Runx2 loaded by hypergravity were significantly up-regulated, which was the same as ColⅠ protein and OC protein after hypergravity loading. There was only a very minute quantity of small red-orange nodules in the control group, while the cells after hypergravity loading in experimental groups obviously formed various sizes of red-orange nodules. Conclusions Under hypergravity, changes in osteoblast morphology can be triggered by rearrangements of skeletal structure. Furthermore, osteoblast maturation and differentiation can be stimulated effectively by up-regulating differentiation-related gene and protein expressions.
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Objective To construct a three-dimensional (3D) solid model of the cortical bone including osteons, verify the stress concentration effect of osteons, simulate and predict the stress concentration location under fatigue using finite element analysis (FEA). Methods The 3D solid model of the cortical bone including osteons was constructed in Pro/E wildfire 5.0, and local stress and strain distributions in the cortical bone under different axial compression were calculated and analyzed in ANSYS 12.0. Fatigue simulation on the selected locations was conducted to evaluate fatigue status of the model subjected to different fatigue loading intensities. Results Obvious stress concentration at the junction of osteon and the interstitical bone appeared under axial compressive loads, and the percentage of pathological local strain in the cortical bone increased with the axial compression increasing. Fatigue simulation on the selected locations demonstrated that bone fatigue risk during physiological or daily activities was very low, while a high fatigue or fracture risk might occur during high-intensity exercises or training. Conclusions The 3D solid model of the cortical bone including osteons is successfully established, the stress concentration effect of osteons is verified, and the location of bone fatigue damage under strenuous exercise and its risk are predicted. These experimental results can provide references for training management and athletic fatigue damage prevention in military recruits and long distance running athletes.
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The growth and metabolism of bone are controlled by osteogenesis of osteoblasts and absorption of osteoclasts, and osteoblasts play a main role in the process of osteogenesis. Overload will affect proliferation and differentiation of osteoblasts, while the loading mode, intensity, duration and other factors can change the biological properties of osteoblasts and further affect the functional activity of osteoblasts. However, the mechanism of osteoblast response to overload is still at the exploratory stage and needs in-depth study. Numerous studies have demonstrated that icariin, a kind of Chinese herbal medicine, can promote proliferation and differentiation of osteoblasts, and icariin with a certain concentration plays an important role in the repair of osteoblast injuries. In this paper, the response of osteoblasts to overload stimulation and repair of osteoblast injuries by icariin were summarized.
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In the environment of adaptive mechanics, osteoblasts, which are the main functional cells of bone formation, are one of the main cells in response to the mechanical loading. With the development of technology, more and more astronauts, pilots and other are exposed to the hypergravity environment. In order to better understand the mechanobiology response of osteoblasts under hypergravity, this paper reviews the mechanobiological research progress in morphology, gene expression, cytokine secretion and signal transduction pathways of ostoblasts, so as to thoughts and preparations for mechanobiology research of bone tissues in hypergravity environment.
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Objective To investigate the effect of 1,25-(OH)2-vitamin D3 (VD3) or mechanical strain alone and their combined treatment on proliferation and differentiation of pre-osteoblast MC3T3-E1 cells in vitro, as well as gene and protein expression of osteoprotegerin (OPG) and receptor activator of nuclear factor-кB ligand (RANKL) in those cells. Methods MC3T3-E1 cells were treated with 10 nmol/L VD3, intermitted mechanical strain or with a combination of these two factors. Cell proliferation was assessed with flow cytometry, and alkaline phosphatase (ALP) activity was measured using a fluorometric detection kit. The mRNA expression of ALP, runt-related transcriptional factor 2 (Runx2), OPG, and RANKL genes was determined by real-time PCR. The proteins expression of Runx2, OPG, and RANKL was determined by Western blotting. ResultsVD3 inhibited the proliferation of MC3T3-E1 cells, but the mechanical strain had no effect on cell proliferation. Mechanical strain, VD3, and the combined treatment enhanced the ALP activity of MC3T3-E1 cells as well as the protein expression of Runx2. The effect of combined treatment was less pronounced than the effect of VD3 or mechanical strain alone. Mechanical strain promoted the gene and protein expression of osteoprotegerin (OPG) and increased the ratio of OPG/RANKL. However, the combination of VD3 and mechanical strain led to a decrease in ratio of OPG/RANKL. Conclusions Mechanical strain might be effective in inducing osteogenic differentiation and increasing bone formation. A joint stimulation with VD3 and strain can decrease proliferation and osteogenic differentiation and increase RANKL expression, which might affect bone remodeling. This study supplies some new data, which might be important in theoretical and clinical research of osteoporosis (OP) and other related bone diseases.
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Erythropoietin-producing hepatoma (EPH) receptors are considered the largest family of receptor tyrosine kinases and play key roles in physiological and pathologic processes in development and disease. EPH receptors are often overexpressed in human malignancies and are associated with poor prognosis. However, the functions of EPH receptors in epithelial-mesenchymal transition (EMT) remain largely unknown. This review depicts the relationship between EPH receptors and the EMT marker E-cadherin as well as the crosstalk between EPH receptors and the signaling pathways involved EMT. Further discussion is focused on the clinical significance of EPH receptors as candidates for targeting in cancer therapeutics. Finally, we summarize how targeted inhibition of both EPH receptors and EMT-related signaling pathways represents a novel strategy for cancer treatment.
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Humans , Antineoplastic Agents , Cadherins , Epithelial-Mesenchymal Transition , Neoplasms , Receptor Protein-Tyrosine Kinases , Receptors, Eph Family , Physiology , Signal TransductionABSTRACT
Objective To study mechanical properties of the medical water-jet scalpel when cutting parenchyma such as liver and verify its tissue-selective cutting characteristic. Methods The tension mechanical properties of porcine liver parenchyma and its vessels with different sizes were determined. Porcine and Wistar rat liver tissues were cut with arteriovenous vessels well reserved, and pathological section of the rats were analyzed by HE staining to explain the experimental phenomena. Results When the working pressure was set at 3 MPa, the incising and separating on the right lobe of porcine liver by medical water-jet scalpel in this experiment were done with minimal vessels of 0.8 mm in diameter left. Pathological sections from ordinary scalpel and medical water-jet scalpel showed that the medical water-jet scalpel caused smaller tissue damage. Conclusions The medical water-jet scalpel could cut heterogeneity soft tissue with highly-selective characteristics, which may effectively avoid the existing “one size fits all” phenomenon caused by ordinary scalpel.
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<p><b>OBJECTIVES</b>To construct the cancellous bone explant model and a method of culturing these bone tissues in vitro, and to investigate the effect of mechanical load on growth of cancellous bone tissue in vitro.</p><p><b>METHODS</b>Cancellous bone were extracted from rabbit femoral head and cut into 1-mm-thick and 8-mm-diameter slices under sterile conditions. HE staining and scanning electron microscopy were employed to identify the histomorphology of the model after being cultured with a new dynamic load and circulating perfusion bioreactor system for 0, 3, 5, and 7 days, respectively. We built a three-dimensional model using microCT and analyzed the loading effects using finite element analysis. The model was subjected to mechanical load of 1000, 2000, 3000, and 4000 με respectively for 30 minutes per day. After 5 days of continuous stimuli, the activities of alkaline phosphatase (AKP) and tartrate-resistant acid phosphatase (TRAP) were detected. Apoptosis was analyzed by DNA ladder detection and caspase-3/8/9 activity detection.</p><p><b>RESULTS</b>After being cultured for 3, 5, and 7 days, the bone explant model grew well. HE staining showed the apparent nucleus in cells at the each indicated time, and electron microscope revealed the living cells in the bone tissue. The activities of AKP and TRAP in the bone explant model under mechanical load of 3000 and 4000 με were significantly lower than those in the unstressed bone tissues (all P<0.05). DNA ladders were seen in the bone tissue under 3000 and 4000 με mechanical load. Moreover, there was significant enhancement in the activities of caspase-3/8/9 in the mechanical stress group of 3000 and 4000 με(all P<0.05).</p><p><b>CONCLUSIONS</b>The cancellous bone explant model extracted from the rabbit femoral head could be alive at least for 7 days in the dynamic load and circulating perfusion bioreactor system, however, pathological mechanical load could affect the bone tissue growth by apoptosis in vitro. The differentiation of osteoblasts and osteoclasts might be inhibited after the model is stimulated by mechanical load of 3000 and 4000 με.</p>
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Animals , Male , Rabbits , Acid Phosphatase , Metabolism , Alkaline Phosphatase , Metabolism , Apoptosis , Bone Development , Caspases , Metabolism , Finite Element Analysis , Isoenzymes , Metabolism , Stress, Mechanical , Tartrate-Resistant Acid Phosphatase , X-Ray MicrotomographyABSTRACT
Objective To investigate the effect of mechanical loading with different magnitudes on the proliferation, differentiation and activity of preosteoclasts and osteoclasts. Methods One group of RAW264.7 preosteoclastic cells cultured in osteoclast inductive medium were subjected to the cyclic tensile strain for three days, and then cultured for four days; the other group of RAW264.7 cells were induced in osteoclast inductive medium for four days to be osteoclasts, then subjected to the cyclic tensile strain for three days. Results Under the tensile strain at different magnitudes, the proliferation variations in two groups of RAW264.7 cells were approximately identical, but changes in the activities of tartrate-resistant acid phosphatage (TRAP) and numbers of TRAP-positive multinucleated cells (osteoclasts) in the two groups were significantly different. Under the moderate tensile strain (2 500 με), the reduction of TRAP activity and osteoclasts number were both the highest in the first group, and both the lowest in the second group. Conclusions The influence of different tensile strain on osteoclast differentiation and osteoclastic activity of preosteoclasts in early differentiation is different to that of the preosteoclasts already differentiated into osteoclasts.
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Objective To design and build a new dynamic load and circulating perfusion bioreactor system and test its performance. Methods The design principle of the bioreactor system was specified and the dynamic strain loading system and 3D perfusion culture system were designed and built accordingly. A special culture chamber for 3D perfusion and compressive loading was also developed. The sterility of the culture chamber and the accuracy and stability of the strain loading were measured, and the result from the culture of tissue engineering bone was preliminarily observed. Results This bioreactor system could provide compressive strains with different magnitudes and frequencies, as well as perfusions under different flow conditions. It could be controlled accurately and operated easily with a steady performance. No germs were grown in the culture medium after 5 days’ running. The preliminary results showed that after the tissue engineering bones were cultured in the bioreactor for 10 days, cell proliferation and ALP activity in this perfusion culture and loading group were significantly higher than those in the static culture group and the simple perfusion culture group. Conclusions The bioreactor could be an ideal dynamic culture and loading device for biomechanical study of tissue engineering bone.
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Objective To observe the adhesion of MC3T3-EI osteoblastic progenitor cells to the three-dimensional chitosan-decellularised-derma scaffolds,and evaluate the cytocompatibility of the scaffolds.Method The threedimensional chitosan-decellularised-derma scaffolds were prepared by the freeze-dtying method,the porosity,density and water absorption of which were measured.The microscopic morphology of the composite scaffolds was analyzed by the scanning electron microscopy(SEM).The MC3T3-E1 cells cultivated in vitro were seeded onto the composite scaffolds,and then co-cultured for 2,3,4 and 5 hours.At each time point,three specimens from each matrix were taken to determine the cell-adhesion rate and the best time of the cell-adhesion.The cells were seeded onto the composite scaffolds,and then co-cultured for 1,3,5,7,9,11 and 13 days.The MC3T3-E1 cells inside were evaluated with MTS test.The cell morphology was observed by the histological staining.The compression tests were performed using a Universal Testing Machine,at room temperature,as compared with no-cell-scaffolds.Results The three-dimensional chitosan-decellularised-derma scaffolds have high interval poroslty with the porosity(92.8%),the density(0.09796 g/ml)and the water absorption(2169±100)%.The cytocompatibility test shows that the seeded MC3T3-E1 cells can adhere to the scaffolds and proliferate.Conclusions The three-dimensional chitosan-decellularised-derma scaffolds have high interval porosity with the welldistributed diameter.The MC3T3-E1 cells are easy to adhere the scaffolds and proliferate which shows that the scaffolds have a good cytocompatibility.
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Objective To observe the adhesion of MC3T3-EI osteoblastic progenitor cells to the three-dimensional chitosan-decellularised-derma scaffolds,and evaluate the cytocompatibility of the scaffolds.Method The threedimensional chitosan-decellularised-derma scaffolds were prepared by the freeze-dtying method,the porosity,density and water absorption of which were measured.The microscopic morphology of the composite scaffolds was analyzed by the scanning electron microscopy(SEM).The MC3T3-E1 cells cultivated in vitro were seeded onto the composite scaffolds,and then co-cultured for 2,3,4 and 5 hours.At each time point,three specimens from each matrix were taken to determine the cell-adhesion rate and the best time of the cell-adhesion.The cells were seeded onto the composite scaffolds,and then co-cultured for 1,3,5,7,9,11 and 13 days.The MC3T3-E1 cells inside were evaluated with MTS test.The cell morphology was observed by the histological staining.The compression tests were performed using a Universal Testing Machine,at room temperature,as compared with no-cell-scaffolds.Results The three-dimensional chitosan-decellularised-derma scaffolds have high interval poroslty with the porosity(92.8%),the density(0.09796 g/ml)and the water absorption(2169±100)%.The cytocompatibility test shows that the seeded MC3T3-E1 cells can adhere to the scaffolds and proliferate.Conclusions The three-dimensional chitosan-decellularised-derma scaffolds have high interval porosity with the welldistributed diameter.The MC3T3-E1 cells are easy to adhere the scaffolds and proliferate which shows that the scaffolds have a good cytocompatibility.
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Objective: To observe the adhesion of MC3T3-El osteoblastic progenitor cells to the three-dimensional chitosan-decellularised-derma scaffolds, and evaluate the cytocompatibility of the scaffolds. Methods: The three-dimensional chitosan-decellularised-derma scaffolds were prepared by the freeze-drying method, the porosity, density and water absorption of which were measured. The microscopic morphology of the composite scaffolds was analyzed by the scanning electron microscopy (SEM). The MC3T3-E1 cells cultivated in vitro were seeded onto the composite scaffolds, and then co-cultured for 2, 3, 4 and 5 hours. At each time point, three specimens from each matrix were taken to determine the cell-adhesion rate, in order to ascertain the best time of the cell-adhesion. The cells were seeded onto the composite scaffolds, and then co-cultured for 1, 3, 5, 7, 9, 11 and 13 days. The MC3T3-E1 cells inside were evaluated with MTS test. The cell morphology was observed by the histological staining. The compression tests were performed using a Universal Testing Machine, at room temperature, as compared with no-cell-scaffolds.Results: The three-dimensional chitosan-decellularised-derma scaffolds had high interval porosity with the porosity (92.8%), the density (0.09796g/ml) and the water absorption (2169±100)%. The cytocompatibility test showed that the seeded MC3T3-E1 cells could adhere to the scaffolds and proliferate.Conclusion:The three-dimensional chitosan-decellularised-derma scaffolds had high interval porosity with the well-distributed diameter. The MC3T3-E1 cells were easy to adhere the scaffolds and proliferate which showed that the scaffolds had a good cytocompatibility.
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<p><b>BACKGROUND</b>For partial-thickness tears of the rotator cuff, double-row fixation and transtendon single-row fixation restore insertion site anatomy, with excellent results. We compared the biomechanical properties of double-row and transtendon single-row suture anchor techniques for repair of grade III partial articular-sided rotator cuff tears.</p><p><b>METHODS</b>In 10 matched pairs of fresh-frozen sheep shoulders, the infraspinatus tendon from 1 shoulder was repaired with a double-row suture anchor technique. This comprised placement of 2 medial anchors with horizontal mattress sutures at an angle of ≤ 45° into the medial margin of the infraspinatus footprint, just lateral to the articular surface, and 2 lateral anchors with horizontal mattress sutures. Standardized, 50% partial, articular-sided infraspinatus lesions were created in the contralateral shoulder. The infraspinatus tendon from the contralateral shoulder was repaired using two anchors with transtendon single-row mattress sutures. Each specimen underwent cyclic loading from 10 to 100 N for 50 cycles, followed by tensile testing to failure. Gap formation and strain over the footprint area were measured using a motion capture system; stiffness and failure load were determined from testing data.</p><p><b>RESULTS</b>Gap formation for the transtendon single-row repair was significantly smaller (P < 0.05) when compared with the double-row repair for the first cycle ((1.74 ± 0.38) mm vs. (2.86 ± 0.46) mm, respectively) and the last cycle ((3.77 ± 0.45) mm vs. (5.89 ± 0.61) mm, respectively). The strain over the footprint area for the transtendon single-row repair was significantly smaller (P < 0.05) when compared with the double-row repair. Also, it had a higher mean ultimate tensile load and stiffness.</p><p><b>CONCLUSIONS</b>For grade III partial articular-sided rotator cuff tears, transtendon single-row fixation exhibited superior biomechanical properties when compared with double-row fixation.</p>