Gap junctional communication in osteocytes is amplified by low intensity vibrations in vitro.

The physical mechanism by which cells sense high-frequency mechanical signals of small magnitude is unknown. During exposure to vibrations, cell populations within a bone are subjected not only to acceleratory motions but also to fluid shear as a result of fluid-cell interactions. We explored displacements of the cell nucleus during exposure to vibrations with a finite element (FE) model and tested in vitro whether vibrations can affect osteocyte communication independent of fluid shear. Osteocyte like MLO-Y4 cells were subjected to vibrations at acceleration magnitudes of 0.15 g and 1 g and frequencies of 30 Hz and 100 Hz. Gap junctional intracellular communication (GJIC) in response to these four individual vibration regimes was investigated. The FE model demonstrated that vibration induced dynamic accelerations caused larger relative nuclear displacement than fluid shear. Across the four regimes, vibrations significantly increased GJIC between osteocytes by 25%. Enhanced GJIC was independent of vibration induced fluid shear; there were no differences in GJIC between the four different vibration regimes even though differences in fluid shear generated by the four regimes varied 23-fold. Vibration induced increases in GJIC were not associated with altered connexin 43 (Cx43) mRNA or protein levels, but were dependent on Akt activation. Combined, the in silico and in vitro experiments suggest that externally applied vibrations caused nuclear motions and that large differences in fluid shear did not influence nuclear motion (<1%) or GJIC, perhaps indicating that vibration induced nuclear motions may directly increase GJIC. Whether the increase in GJIC is instrumental in modulating anabolic and anti-catabolic processes associated with the application of vibrations remains to be determined.

Devastation of adult stem cell pools by irradiation precedes collapse of trabecular bone quality and quantity.

Stem cell depletion and compromised bone marrow resulting from radiation exposure fosters long-term deterioration of numerous physiologic systems, with the degradation of the skeletal system ultimately increasing the risk of fractures. To study the interrelationship of damaged bone marrow cell populations with trabecular microarchitecture, 8- and 16-week-old C57BL/6 male mice were sublethally irradiated with 5 Gy of (137)Cs γ-rays, and adult stem cells residing in the bone marrow, as well as bone quantity and quality, were evaluated in the proximal tibia after 2 days, 10 days, and 8 weeks compared with age-matched controls. Total extracted bone marrow cells in the irradiated 8-week, young adult mice, including the hematopoietic cell niches, collapsed by 65% ± 11% after 2 days, remaining at those levels through 10 days, only recovering to age-matched control levels by 8 weeks. As early as 10 days, double-labeled surface was undetectable in the irradiated group, paralleled by a 41% ± 12% and 33% ± 4% decline in bone volume fraction (BV/TV) and trabecular number (Tb.N), respectively, and a 50% ± 10% increase in trabecular separation (Tb.Sp) compared with the age-matched controls, a compromised structure that persisted to 8 weeks postirradiation. Although the overall collapse of the bone marrow population and devastation of bone quality was similar between the "young adult" and "mature" mice, the impact of irradiation--and the speed of recovery--on specific hematopoietic subpopulations was dependent on age, with the older animals slower to restore key progenitor populations. These data indicate that, independent of animal age, complications arising from irradiation extend beyond the collapse of the stem cell population and extend toward damage to key organ systems. It is reasonable to presume that accelerating the recovery of these stem cell pools will enable the prompt repair of the skeletal system and ultimately reduce the susceptibility to fractures.

Heparin cryoprecipitation reduces plasma levels of non-traditional risk factors for atherosclerosis in vitro.

AIMS: To show that heparin cryoprecipitation (HCP), an in vitro method of plasma purification, reduces the levels of in vivo modified proteins and non-traditional risk factors from plasma of atherosclerotic hemodialysis (HD) patients. METHODS: HCP was applied to plasma obtained from HD patients and controls, forming a precipitate--cryogel. Levels of fibrinogen, albumin, CRP, TNF-alpha, IL-6, advanced oxidation protein products, carbonylated fibrinogen and carbonylated albumin were determined in plasma before and after applying HCP and in the cryogel. RESULTS: Treatment of HD plasma with HCP, beyond the significant reduction of the increased levels of all the above-mentioned molecules, reduced fibrinogen, TNF-alpha, carbonylated fibrinogen and carbonylated albumin to control levels which were simultaneously found in the cryogel. CONCLUSIONS: HCP applied to plasma enables the simultaneous precipitation of modified molecules and circulating non-traditional risk factors for atherosclerosis. This study may serve as a base for the future development of a clinical purification technique.

Marek's disease vaccines cause temporary U-lymphocyte dysfunction and reduced resistance to infection in chicks.

One-day-old chicks were vaccinated with one of the commercially used vaccines [herpes virus of turkeys (HVT), bivalent HVT+SB1 or Rispens] and the immune response and resistance to infection evaluated. A temporary depletion of B-lymphocyte activity of varying intensity was found, as demonstrated by a diminished response to a B-lymphocyte-specific mitogen in vitro, and by decreased antibody production to BSA in vivo. Of the three vaccines tested, the bivalent vaccine (HVT+SB1) and Rispens were the most damaging. A temporary decreased resistance to pathogenic E coli infection in vaccinated chicks was observed.