Bone texture modifications during bone regeneration and osteocyte cell-signaling changes in response to treatment with Teriparatide

Bone texture modifications during bone regeneration and osteocyte cell-signaling changes in response to treatment with Teriparatid

Effect of PTH (1-34) on trabecular bone of rat vertebral body in induced-biochemical osteoporosis by calcium- deprived diet

Rats fed calcium-deprived diet were used as experimental model for studying bone modelling alterations during biochemical osteoporosis and recovery of bone loss. Such model is suitable to evaluate the possible effects exerted by PTH(1-34) in preventing as well as in recovering metabolic osteoporosis. Three-month-old Sprague Dawley male rats were divided in different groups: some fed normal diet or calcium-deprived diet with/without 40µg/Kg/day PTH(1-34), provided by Eli Lilly-USA, for 4 weeks and some with restoration of normal diet with/without PTH (1-34) for further 4 weeks. To evaluate the occurrence of osteogenesis during the first 4 weeks of the experimental period, rats received three labels of bone deposition at 1st, 20th and 27th day (and then were sacrificed); during the successive 4 weeks (in which those rats previously fed with calcium-deprived diet had restoration of normal diet), animals received three labels of bone deposition at 1st, 7th and 14th day. Histomorphometrical analyses were performed on cortical and trabecular bone taken from the central level of the 5th lumbar vertebral body, transversely sectioned. The results showed that differences among the groups were observed mainly in trabecular bone with respect to cortical one, thus underlining the different role of the two types of bone architecture in mineral and skeletal homeostasis. Concerning trabecular bone, the observations showed that administration of PTH (1-34) during calcium-deprived diet and/or during the restoration of normal diet induces higher deposition of trabecular bone with respect to that recorded in rats that never received PTH(1-34), neither during calcium-deprived diet nor during restoration of normal diet. Since increments of trabecular bone are detectable only after the period of diet restoration (but not before), the authors suggest that a chronic administration of PTH (1-34) is necessary to achieve appreciable results on bone mass recovery

Effects of PTH(1-34) during fracture healing after experimental bone drilling in rat femur: novel aspects

The study concerns the role of PTH(1-34) during bone lesion repair. 3-month-old male Sprague-Dawley rats, in which trans-cortical holes were drilled at femur middiaphysis, were divided in groups with/without Teriparatide administration (40g/ Kg/day), and sacrificed at different times (10, 28, 45 days). In 2002 (1) we demonstrated the occurrence of two successive bone forming processes during both skeletal organogenesis and bone repair, i.e. static (SO) and dynamic (DO) osteogenesis: the former (due to stationary osteoblasts, haphazardly grouped in cords) producing preliminary bad quality trabecular bone, the latter (due to typical polarized osteoblasts organized in ordered movable laminae) producing mechanically valid bone tissue. In brief, the primary function of SO is to provide a rigid scaffold, containing osteocytes (i.e. mechano-sensors), to DO-osteoblastic laminae; therefore, in DO mechanical factors can play a crucial role in transduction of mechanical stresses into biological signals. In the present work, histomorphometric analysis showed that, already after 10 days from drilling, notwithstanding the holes are temporarily filled by the same amount of newly-formed trabecular bone (produced by SO) independently from the treatment, the number of movable osteoblast laminae (typical of DO), covering the trabecular surface, is statistically higher in animals submitted to PTH(1-34) administration than in the control ones; this suggests that the mere effect of Teriparatide is to anticipate the occurrence of dynamic osteogenesis involved in the production of good quality bone more suitable to loading. These findings are also supported by the higher values of microhardness as well as the more ordered-fibered texture (observed by polarized light) in treated animals with respect to control ones that strongly indicates the qualitative (instead of quantitative) effect of PTH (1-34) in improving bone healing. The present investigation could be of crucial importance in further translational clinical research in humans to define the best therapeutic strategies in recovering skeletal lesions, particularly in terms of time of administration of PTH(1-34)

Induced Biochemical osteoporosis: Effects of 1-month calcium–deprived diet on rat bone remodelling with/without contemporary administration of PTH(1-34)

It is known that rats fed calcium-deprived diet develop osteoporosis due to en-hanced bone resorption secondary to parathyroid overactivity resulting from nutritional hypocalcemia. Therefore, rats provide a good experimental animal model for studying bone remodelling alterations during biochemical osteoporosis. This preliminary study is performed in 3 month-old Sprague Dawley male rats, divided into 4 groups (5 rats each): 1) base line, 2) normal diet for 4 weeks, 3) calcium-deprived diet for 4 weeks; 4) calcium-deprived diet for 4 weeks plus contemporary administration of PTH(1-34) 40µg/kg/day. Three labels of osteogenesis were performed at 1st , 20th and 27th day of experimental period in order to evaluate bone formation during animal treatment. His-tomorphometrical analyses were performed on cortical bone of femoral diaphyses, as well as on trabecular bone of distal femoral metaphyses, both transversely sectioned. The preliminary results showed that at femur mid-diaphyseal level the diet induced a reduction of cortical bone area (even if not significant) with enlargement of the medul-lary canal due to endosteal resorption, while periosteal neo-deposition is similar in all groups and particularly abundant in those periosteal regions mainly devoted in answering the mechanical demands. PTH(1-34) treatment seems to reduce endosteal resorption only in those surfaces where periosteal mechanical loading are less consistent. Conversely, PTH(1-34) treatment doesn't seem to affect osteoblast activity. Moreover, in distal femoral metaphyses, diet induced osteoclast activity, with a decrease in the amount of trabecular bone volume, confirming that this architecture is mainly devoted in answering the metabolic demands. The novelty of the proposed model Is the contemporary administration of PTH(1-34) together with calcium deprived diet to evaluate induced-biochemical osteoporosis. This model seems a good starting point for successive studies in order to study bone alterations during unbalanced calcium metabolism frequently occurring in aging and to define time and manner of bone mass recovery

Biocompatibility Analyses of Al₂O₃-Treated Titanium Plates Tested with Osteocyte and Fibroblast Cell Lines

Osseointegration of a titanium implant is still an issue in dental/orthopedic implants durable over time. The good integration of these implants is mainly due to their surface and topography. We obtained an innovative titanium surface by shooting different-in-size particles of Al₂O₃ against the titanium scaffolds which seems to be ideal for bone integration. To corroborate that, we used two different cell lines: MLO-Y4 (murine osteocytes) and 293 (human fibroblasts) and tested the titanium scaffolds untreated and treated (i.e., Al₂O₃ shot-peened titanium surfaces). Distribution, density, and expression of adhesion molecules (fibronectin and vitronectin) were evaluated under scanning electron microscope (SEM) and confocal microscope (CM). DAPI and fluorochrome-conjugated antibodies were used to highlight nuclei, fibronectin, and vitronectin, under CM; cell distribution was analyzed after gold-palladium sputtering of samples by SEM. The engineered biomaterial surfaces showed under SEM irregular morphology displaying variously-shaped spicules. Both SEM and CM observations showed better outcome in terms of cell adhesion and distribution in treated titanium surfaces with respect to the untreated ones. The results obtained clearly showed that this kind of surface-treated titanium, used to manufacture devices for dental implantology: (i) is very suitable for cell colonization, essential prerequisite for the best osseointegration, and (ii) represents an excellent solution for the development of further engineered implants with the target to obtain recovery of stable dental function over time

Up-regulation of the chemo-attractive receptor ChemR23 and occurrence of apoptosis in human chondrocytes isolated from fractured calcaneal osteochondral fragments

To study the expression level of a panel of pro/anti-apoptotic factors and inflammation-related receptors in chondral fragments from patients undergoing surgical treatment for intra-articular calcaneal fractures, cartilage fragments were retrieved from calcaneal fractures of 20 patients subjected to surgical treatment. Primary cultures were performed using chondral fragments from fractured and control patients. Chondrocyte cultures from each patient of the fractured and control groups were subjected to immunofluorescence staining and quantitatively analyzed under confocal microscopy. Proteins extracted from the cultured chondrocytes taken from the fractured and control groups were processed for Western blot experiments and densitometric analysis. The percentage of apoptotic cells was determined using the cleaved PARP-1 antibody. The proportion of labelled cells was 35% for fractured specimens, compared with 7% for control samples. Quantification of caspase-3 active and Bcl-2 proteins in chondrocyte cultures showed a significant increase of the apoptotic process in fractured specimens compared with control ones. Fractured chondrocytes were positively stained for ChemR23 with statistically significant differences with respect to control samples. Densitometric evaluation of the immunoreactive bands confirmed these observations. Human articular chondrocytes obtained from patients with intra-articular calcaneal fractures express higher levels of pivotal pro-apoptotic factors, and of the chemoattractive receptor ChemR23, compared with control cultures. On the basis of these observations, the authors hypothesize that consistent prolonged chondrocyte death, associated with the persistence of high levels of proinflammatory factors, could enhance the deterioration of cartilage tissue with consequent development of post-traumatic arthritis following intra-articular bone fracture

Chondrocyte expression of apoptotic and pro-inflammatory factors in the development of post- traumatic arthritis in humans

The development of post-traumatic arthritis following intra-articular fracture remains an important unsolved clinical problem. The possibility that extensive chondrocyte apoptosis occurs following intra-articular fracture, thus contributing to the development of post-traumatic arthritis, has received increasing attention [1]. It has been demonstrated the existence of a direct correlation between the rate of apoptosis and the severity of osteoarthritis [2]. Pharmacologic inhibitors of enzymes involved in apoptosis have been explored as potential therapeutic agents [3]. In the present study we aimed to deepen the characterization of apoptotic mediators, expressed by chondrocytes, involved in human post-traumatic arthritis following intra-articular fracture and the possible implication of pro-inflammatory receptors in arthritis. The expression of a panel of pro/anti apoptotic factors (Caspase-3, PARP-1, BCL2) and inflammation-related receptors (ChemR23) were analysed in chondrocytes from patients undergoing surgery for intra-articular calcaneal fractures. The factors were investigated by immunofluorescence coupled with confocal analysis and western blotting, followed by densitometric evaluation of chondrocyte cultures harvested from patients with intra-articular fractures compared with control ones. The results clearly demonstrated that a statistically significant difference exists in the expression of pro/anti apoptotic factors and ChemR23 between fractured and control patients. In conclusion our data suggest that increased chondrocyte death, occurring after cartilage injury together with inflammatory process, could play a pivotal role in the onset of arthritic disease. References [1]. Hembree W.C. et al. (2007) Viability and apoptosis of human chondrocytes in osteochon-dral fragments following joint trauma. J Bone Joint Surg Br 89(10): 1388-95. [2] Kim H.A. et al. (2000) Apoptotic chondrocyte death in human osteoarthritis. J Rheumatol 27: 455\u2013462. [3] D'Lima D. et al. (2006) Caspase inhibitors reduce severity of cartilage lesions in experi-mental osteoarthritis. Arthritis Rheum 54(6): 1814-1821

Oral surgery biomaterials: analyses of Al2O3-treated titanium surfaces tested with fibroblast and osteocyte cell lines

Two different cell lines - MLO-Y4 (murine osteocytes) and 293 (human fibroblasts) - cultured for 48 hours in standard media were used to analyse engineered bio-materials (i.e. Al2O3 shot-peened titanium surfaces). Distribution, density and expression of adhesion molecules (fibronectin and vitronectin) were evaluated under scanning electron microscope (SEM) and confocal microscope (CM) as previously described [1]. The engineered biomaterial surfaces showed under SEM irregular morphology displaying variously-shaped spicules, obtained by shooting different-in-size particles of Al2O3 against the scaffolds of biomaterial. DAPI and fluorochrome-conjugated antibodies were used to highlight nuclei, fibronectin and vitronectin, under CM; cell distribution was analysed after Gold-Palladium sputtering of samples by SEM. Both SEM and CM observations showed better outcome in terms of cell adhesion and distribution in treated titanium surfaces with respect to the untreated ones. The results obtained clearly showed that this kind of surface-treated titanium, used to manufacture devices for dental implantology: i) is very suitable for cell colonization, essential prerequisite for the best osseointegration, and ii) represents an excellent solution for the development of further engineered implants with the target to obtain recovery of dental function stable over time. Further studies on these Al2O3 shot-peened-titanium surfaces, both in vitro and in vivo, will be needed to obtain accurate definition of better biomaterial outcome, also after additional treatments. References [1] Palumbo et al. (2013) Immunocytochemical and structural comparative study of committed versus multipotent stem cells cultured with different biomaterials. Micron 47: 1–9

Induction of altered cellular response to oxidative stress in HT29 colon cancer cells treated with Metformin

Accumulating evidences suggest that Metformin, a biguanide class of anti-diabet- ic drugs, possesses anti-cancer properties (1). In a number of preclinical and clinical studies, Metformin reduced proliferation, induced apoptosis, caused cell cycle arrest, and reduced incidence and growth of tumors (2). HT-29 is a human colorectal ade- nocarcinoma cell line with epithelial morphology and represents a xenograft tumor model for colorectal cancer. Nuclear factor E2-related factor 2 (Nrf2) is a transcription factor that controls the expression of a large pool of antioxidant and cytoprotective genes, regulating the cellular response to oxidative and electrophilic stress. Evidences have suggested that mutations in Nrf2 are common in cancer cells, which could help tumor cells surviving, and might be associated with poor survival of cancer patients. In our study the HT29 cells were treated with graded concentrations of Metformin for 24, 48 and 72 hours. We performed immunofluorescence experiments by means of confocal microscopy, western blot and cytofluorimetric analysis to evaluate a panel of factors involved in apoptotic/autophagic processes and oxidative stress response. Our results demonstrate that Metformin exerts growth inhibitory effects on cultured HT29 cells by increasing apoptosis and autophagy; moreover, it affects the survival of cultured cells inhibiting the transcriptional activation of both Nrf2 and NF-kB. The effects of Metformin on HT29 cells were dose dependent as well as time dependent, because it has been showed a significant change in the parameters analyzed after 72 hs versus 24 hs of treatment. Therefore, constitutive activation or augmented signal- ling of the Nrf2 pathway might be decisive for cell fate during tumorigenesis and could affect the response to chemotherapy

Effects of PTH(1-34) during fracture healing after experimental bone drilling in rat femur: novel aspects

The study concerns the role of PTH(1-34) during bone lesion repair. 3-month-old male Sprague-Dawley rats, in which trans-cortical holes were drilled at femur mid-diaphysis, were divided in groups with/without Teriparatide administration (40g/ Kg/day), and sacrificed at different times (10, 28, 45 days). In 2002 (1) we demonstrated the occurrence of two successive bone forming processes during both skeletal organogenesis and bone repair, i.e. static (SO) and dynamic (DO) osteogenesis: the former (due to stationary osteoblasts, haphazardly grouped in cords) producing pre- liminary bad quality trabecular bone, the latter (due to typical polarized osteoblasts organized in ordered movable laminae) producing mechanically valid bone tissue. In brief, the primary function of SO is to provide a rigid scaffold, containing osteocytes (i.e. mechano-sensors), to DO-osteoblastic laminae; therefore, in DO mechanical factors can play a crucial role in transduction of mechanical stresses into biological signals. In the present work, histomorphometric analysis showed that, already after 10 days from drilling, notwithstanding the holes are temporarily filled by the same amount of newly-formed trabecular bone (produced by SO) independently from the treatment, the number of movable osteoblast laminae (typical of DO), covering the trabecular surface, is statistically higher in animals submitted to PTH(1-34) administration than in the control ones; this suggests that the mere effect of Teriparatide is to anticipate the occurrence of dynamic osteogenesis involved in the production of good quality bone more suitable to loading. These findings are also supported by the higher values of microhardness as well as the more ordered-fibered texture (observed by polarized light) in treated animals with respect to control ones that strongly indi- cates the qualitative (instead of quantitative) effect of PTH (1-34) in improving bone healing. The present investigation could be of crucial importance in further translational clinical research in humans to define the best therapeutic strategies in recovering skeletal lesions, particularly in terms of time of administration of PTH(1-34)