Resonance in the mouse tibia as a predictor of frequencies and locations of loading-induced bone formation

To enhance new bone formation for the treating of patients with osteopenia and osteoporosis, various mechanical loading regimens have been developed. Although a wide spectrum of loading frequencies is proposed in those regimens, a potential linkage between loading frequencies and locations of loading-induced bone formation is not well understood. In this study, we addressed a question: Does mechanical resonance play a role in frequency-dependent bone formation? If so, can the locations of enhanced bone formation be predicted through the modes of vibration? Our hypothesis is that mechanical loads applied at a frequency near the resonant frequencies enhance bone formation, specifically in areas that experience high principal strains. To test the hypothesis, we conducted axial tibia loading using low, medium, or high frequency to the mouse tibia, as well as finite element analysis. The experimental data demonstrated dependence of the maximum bone formation on location and frequency of loading. Samples loaded with the low-frequency waveform exhibited peak enhancement of bone formation in the proximal tibia, while the high-frequency waveform offered the greatest enhancement in the midshaft and distal sections. Furthermore, the observed dependence on loading frequencies was correlated to the principal strains in the first five resonance modes at 8.0–42.9 Hz. Collectively, the results suggest that resonance is a contributor to the frequencies and locations of maximum bone formation. Further investigation of the observed effects of resonance may lead to the prescribing of personalized mechanical loading treatments.     

Time-dependent functional maturation of scaffold-free cartilage tissue analogs

One of the most critical parameters in cartilage tissue engineering which influences the clinical success of a repair therapy is the ability to match the load-bearing capacity of the tissue as it functions in vivo. While mechanical forces are known to positively influence the development of cartilage matrix architecture, these same forces can induce long-term implant failure due to poor integration or structural deficiencies. As such, in the design of optimal repair strategies, it is critical to understand the timeline of construct maturation and how the elaboration of matrix correlates with the development of mechanical properties. We have previously characterized a scaffold-free method to engineer cartilage utilizing primary chondrocytes cultured at high density in hydrogel-coated culture vessels to promote the formation of a self-aggregating cell suspension that condenses to form a cartilage-like biomass, or cartilage tissue analog (CTA). Chondrocytes in these CTAs maintain their cellular phenotype and deposit extracellular matrix to form a construct that has characteristics similar to native cartilage; however, the mechanical integrity of CTAs had not yet been evaluated. In this study, we found that chondrocytes within CTAs produced a robust matrix of proteoglycans and collagen that correlated with increasing mechanical properties and decreasing cell-matrix ratios, leading to properties that approached that of native cartilage. These results demonstrate a unique approach to generating a cartilage-like tissue without the complicating factor of scaffold, while showing increased compressive properties and matrix characteristics consistent with other approaches, including scaffold-based constructs. To further improve the mechanics of CTAs, studies are currently underway to explore the effect of hydrodynamic loading and whether these changes would be reflective of in vivo maturation in animal models. The functional maturation of cartilage tissue analogs as described here support this engineered cartilage model for use in clinical and experimental applications for repair and regeneration in joint-related pathologies.     

Colony formation by chicken hematopoietic cells and virus-induced myeloblasts

Leukemic myeloblasts and cells derived from normal chick hematopoietic tissue produced colonies in soft agar. Colonies produced by leukemic myeloblasts differed from normal chick tissue in their morphological characteristics, in the greater initial number of cells required for colony formation and in their decreased dependence on conditioned medium for development. The colony forming cells for both types were enriched when allowed to grow for several days in liquid growth medium. In soft agar, myeloblasts differentiated into more mature granulocytic cells and macrophages. These differentiated cells accumulated between one and two weeks after seeding. When tested for release of avian myeloblastosis virus (AMV), 6 out of 18 colonies were releasing AMV at one week whereas 3 out of 39 were releasing AMV at two weeks. Five two week old colonies which were negative for AMV were producing myeloblastosis associated viruses (MAVs). Normal colony forming cells were present in leukemic buffy coat and although colonies made by these cells contained MAVs, no AMV could be detected. The data obtained with normal avian tissues were similar to those obtained by others with mammalian hematopoietic tissue. Colony formation by normal hematopoietic tissues was strictly dependent on factors present in conditioned medium. Tissues producing colonies included bone marrow, yolk sac, spleen and peripheral leukocytes. Colonies were not obtained from thymus and bursa. Furthermore, the colony origin did not appear to be erythroid in nature.     

The cytotoxic and photodynamic inactivation of micro-organisms by Rose Bengal

Rose Bengal was cytotoxic to the following bacteria at the concentrations given in parentheses (highest concentrations of dye in mol/l at which growth occurred on nutrient medium): Brochothrix thermosphacta and Deinococcus radiodurans (1 X 10(-6) or less); Streptococcus, Micrococcus, Staphylococcus, Bacillus, Arthrobacter and Kurthia spp. (1 X 10(-5)-1 X 10(-4], and Pseudomonas spp. and Enterobacteriaceae (5 X 10(-3)-1 X 10(-2) or greater). These organisms were killed rapidly when suspended in illuminated (170 microE/m2/s) solutions of Rose Bengal (1 X 10(-4) mol/l) providing oxygen was present. Singlet oxygen was identified as the lethal agent, because the rate of killing was increased by dissolving the dye in deuterium oxide while the organism were protected against photoinactivation by L-histidine or crocetin. Yeasts from chilled foods were killed in illuminated solutions of Rose Bengal but a light intensity of 315 microE/m2/s was needed for a death rate comparable with that of bacteria. The yeasts present in a range of chilled meat and dairy products failed to form colonies on Rose Bengal (5 X 10(-5) mol/l) media exposed continuously to modest illumination (55-80 microE/m2/s).     

Organ and species specific differences in cytoskeletal protein profiles of cultured microvascular endothelial cells.

1. Using two-dimensional gel electrophoresis and immunoblotting techniques we systematically document the structural diversity of cytoskeletal proteins in tight and leaky cultured microvascular endothelial cells (MEC). Bovine pulmonary and eel rete mirabile MEC primarily express cytokeratins 8 and 19. Cytokeratins 8 and 18 were found to be prominent in rat pulmonary MEC. Bovine retinal MEC contained cytokeratins 8, 18 and 19. Bovine adrenal MEC contain vimentin as their sole intermediate filament protein. 2. Four principal actin isoforms were resolved in micro/macrovascular endothelial cells as well as in vascular smooth muscle cells. Retinal pericytes expressed three principal actin isoforms. 3. These results indicate that MEC are diverse, highly differentiated cells displaying a large repertoire of cytoskeletal protein profiles suited for specific tissue functions.     

Effect of sodium hexanitrocobaltate (III) decomposition on its staining of intracellular potassium ions.

The effect was examined of the chemical decomposition of the potassium stain sodium hexanitrocobaltate (III) (SHC), on its ability to produce stain granules of consistent size that could be used to estimate the K+ contents of stomatal guard cells. Stomata in detached epidermis from leaves of Vicia faba (fava bean) were stimulated to accumulate K+ by treating them with fusicoccin. Stomatal apertures and the fraction of guard cell area covered by K+ precipitate granules (K+ score) were measured by digitizing photographic enlargements, and K+ scores were correlated with the age of stain that had been stored either in open or closed containers. The ability of stain aged in open containers to produce consistent fractional cell coverage was compared to 1) the ability of identically treated stain to precipitate K+ from solutions of KCI, and to 2) the kinetics of decomposition of SHC. It was found that the fractional coverage of guard cells of stomata opened to the same apertures decreased with a first order rate constant of 2.3 x 10(-5)/sec. The mass of precipitate formed by treatment of KCl solutions was unchanged for 2 hr after initial preparation of the SHC, and decreased thereafter with a first order rate constant of 1.0 x 10(-5)/sec. When stored in tightly sealed containers, nearly 100 hr were required for an occasionally opened bottle of SHC to decay to the same efficacy as a solution left open to the air for 8 hr.     

Analysis of fatty acids of human red cells without lipid extraction

Exposure of human red cells to 2 N HCl for 18-20 hr at 110 degrees C appears to release the total fatty acid, which can then be esterified for GLC analysis. This technique is simpler and may be more reliable than the conventional methods that depend on lipid extraction of the red cells.     

International Society for Reef Studies (ISRS)

International Society for Reef Studies (ISRS)