Effects of freeze–thaw and micro-computed tomography irradiation on structure–property relations of porcine trabecular bone

We study the effects of freeze–thaw and irradiation on structure–property relations of trabecular bone. We measure the porosity, apparent density, mineral content, trabecular orientation, trabecular thickness, fractal dimension, surface area, and connectivity of trabecular bone using micro-computed tomography (micro-CT) and relate them to Young?s modulus and ultimate strength measured by uniaxial compression testing. The analysis is done on six-month porcine trabecular bone from femoral heads. The effects of freeze–thaw are studied by using bones from three different groups: fresh bone and bones frozen for one and five years. We find that the porosity and apparent density have most dominant influence on the elastic modulus and strength of fresh bone. Also, five years of freezing lowers both Young?s modulus and ultimate strength of trabecular bone. Additionally, the effects of radiation are investigated by comparing Young?s modulus before and after micro-CT exposure. We find that the micro-CT irradiation has a negligible effect on the Young?s modulus of trabecular bone. These findings provide insights on the effects of tissue preservation and imaging on properties of trabecular bone.     

Further Characterization of In Vitro Conditions Appropriate for GABA Determination in Human CSF: Impact of Acid Deproteinization and Freeze/Thaw

Recently established standardized protocols for collection, handling, and storage of CSF for measurement of gamma-aminobutyric acid (GABA) have proven valuable in the characterization of various CNS disorders. In response to two recent reports which may have an impact on certain widely used protocols, we have, using the confirmed ion-exchange/fluorometric procedure, systematically evaluated the effects of deproteinization with various concentrations of sulfosalicylic acid (SSA) ranging from 0 to 10% (100 mg/ml), as well as the effects of freeze/thaw (F/T) on CSF GABA levels. Results of F/T studies documented that levels are stable to freezing and thawing. Acid deproteinization studies revealed the presence of an equilibrium between strictly free GABA, demonstrable only in acid-free CSF, and a very loosely bound form of GABA, fully demonstrable only in CSF deproteinized with concentrations of SSA above 1% (10 mg/ml). The relationship between GABA concentrations in undeproteinized and acid-deproteinized CSF revealed a highly significant (p less than .001) correlation, suggesting that alterations of central GABAergic activity would be reflected by either the level of strictly free GABA or free plus loosely bound GABA. This hypothesis was upheld in studies of patients with Parkinson's disease (PD) and Huntington's disease (HD), two neurologic disorders in which dysfunctions of the GABA system have been implicated. Results indicated that CSF GABA levels are significantly reduced in both PD and HD patients compared with neurologically normal controls, whether the measurement is of free GABA or free plus loosely bound GABA. Thus, we conclude that the level of strictly free GABA is stable to freezing and thawing and can only be accurately determined in nonacidified CSF; however, existing protocols employing deproteinization in 5% SSA yield data that provide an equally good reflection of central GABAergic transmission.     

Detection of Leptospiraceae by amplification of 16S ribosomal DNA

The polymerase chain reaction (PCR) was developed to detect Leptospiraceae. Primers were used to amplify 1 631 base-pair (bp) 5'-region of 16S rDNA. Representative strains from the species, Leptospira interrogans sensu stricto, L. borgpetersenii, L. noguchii, L. santarosai, L. weilii, L. inadai, L. meyeri and the single member strain of Leptonema were amplified. In contrast, strains representing the saprophytic species. L. biflexa, L. wolbachii and L. parva were not amplified. There was no PCR product from 23 phylogenetically unrelated species of bacteria. As little as 10-1 pg of purified DNA and as few as 10-1 leptospires could be detected using the PCR analysis. Isolates of leptospires from clinical sources gave a positive PCR band, but those from surface waters did not.     

Low-order fine roots of Picea asperata have different physiological mechanisms in response to seasonal freeze and freeze–thaw of soil

• Seasonal soil freezing (F) and freeze–thaw cycles (FTCs) are common natural phenomena in high latitude or altitude areas of the world, and seriously affect plant physiological processes. However, studies on the effect of soil F and FTCs on fine roots are less common, especially in subalpine coniferous forests of western Sichuan, China.
• We set up a controlled experiment in growth chambers to explore the effects of F and FTCs on low-order fine roots of Picea asperata and differential responses of first-order roots and the first three root orders (1st, 2nd and 3rd order roots combined as a unit).
• Soil F and FTCs resulted in serious damage to cell membranes and root vitality of low-order fine roots, accompanied by increased MDA content and O₂·⁻ production. FTCs had a stronger effect than F treatment. In turn, low-order fine roots are the unit that responds to cold stress. These roots had increased unsaturated fatty acid contents, antioxidant enzyme activities, osmolytes and plant hormones contents when acclimation to cold stress. The first-order roots were more sensitive to cold stress than the combined first three root orders for several processes (e.g. antioxidant enzymes, osmolytes and hormones) because of their specific structure and physiological activity.
• This study explains physiological differences in responses of fine roots of different root orders to seasonal soil freezing, which will improve the understanding of fine root heterogeneity and support agriculture and forest management.