Head dimensions of cryopreserved red deer spermatozoa are affected by thawing procedure

The objective of this study was to evaluate the effects of the thawing procedure on red deer spermatozoa distribution in morphologically distinct subpopulations after freezing and thawing. For this purpose, epididymal spermatozoa were thawed using two different thawing protocols (I = 37 degree celsius for 20 s vs. II = 70 degree celsius for 5 s). The spermatozoa, from 10 Iberian deer stags, were diluted at room temperature in a Triladyl-20 percent egg yolk medium and frozen in nitrogen vapor. Standard sperm freezability was judged by microscopic assessments of sperm motility. The thawing procedure had an effect on sperm motility percentage (P = 0.05), with the best overall recovery rates found with the use of protocol I (76.8 + or - 1.8 vs. 70.6 + or - 1.8). Moreover, the morphometric dimensions for a minimum of 200 sperm heads were analyzed from each sample by means of the Sperm-Class Analysez (SCA), and the mean measurements recorded. Deer sperm heads were significantly (P = 0.01) smaller when spermatozoa were thawed using protocol II than when using procedure I (area = 30.02 square micrometers vs. 30.32 square micrometers; width = 4.47 micrometers vs. 4.51 micrometers; length = 8.05 micrometers vs. 8.11 micrometers), but not for all stags. All sperm head measurements were placed in a statistical database and a multivariate cluster analysis performed. Mean measurements for all parameters of the major clusters for the two different thawing procedures were compared by ANOVA. The mean values for length, width, area, perimeter, shape factor and width/length in the major cluster of sperm head dimensions for thawing protocol I were significantly different from those for protocol II (P = 0.001). In addition, differences were found within all stags for whole morphometric parameters (P = 0.001), with the smallest overall sperm head dimensions found with the use of protocol II. Additionally, the rapid thawing protocol produced a dramatic loss of heterogeneity. Finally, our results showed that the greater the loss of heterogeneity, the greater the degree of sperm cryoinjury.     

Dead Ends and Detours En Route to Total Syntheses of the 1990s A list of abbreviations can be found at the end of the article

From the very beginning organic chemistry and total synthesis have been intimately joined. In fact, one of the first things that freshmen in organic chemistry learn is how to join two molecules together to obtain a more complex one. Of course they still have a long way to go to become fully mature synthetic chemists, but they must have the primary instinct to build molecules, as synthesis is the essence of organic chemistry. With the different points of view that actually coexist in the chemical community about the maturity of the science (art, or both) of organic synthesis, it is clear that nowadays we know how to make almost all of the most complex molecules ever isolated. The primary question is how easy is it to accomplish? For the readers of papers describing the total synthesis of either simple or complex molecules, it appears that the routes followed are, most of the time, smooth and free of troubles. The synthetic scheme written on paper is, apparently, done in the laboratory with few, if any, modifications and these, essentially, seem to be based on finding the optimal experimental conditions to effect the desired reaction. Failures in the planned synthetic scheme to achieve the goal, detours imposed by unexpected reactivity, or the absence of reactivity are almost never discussed, since they may diminish the value of the work reported. This review attempts to look at total synthesis from a different side; it will focus on troubles found during the synthetic work that cause detours from the original synthetic plan, or on the dead ends that eventually may force redesign. From there, the evolution from the original route to the final successful one that achieves the synthetic target will be presented. The syntheses discussed in this paper have been selected because they contain explicit information about the failures of the original synthetic plan, together with the evolution of the final route to the target molecule. Therefore, they contain a lot of useful negative information that may otherwise be lost.