Influence of cooling rate on Saccharomyces cerevisiae destruction during freezing: unexpected viability at ultra-rapid cooling rates

The purpose of this work was to study cell viability as a function of cooling rate during freezing. Cooling rate strongly influences the viability of cells during cold thermal stress. One of the particularities of this study was to investigate a large range of cooling rates and particularly very rapid cooling rates (i.e., faster than 20000 degrees C min (-1)). Four distinct ranges of cooling rates were identified. The first range (A(')) corresponds to very slow cooling rates (less than 5 degrees C min (-1)), and results in high cell mortality. The second range (A) corresponds to low cooling rates (5-100 degrees C min (-1)), at which cell water outflow occurs slowly and does not damage the cells. The third range (B) corresponds to rapid cooling rates (100-2000 degrees C min (-1)), at which there is competition between heat flow and water flow. In this case, massive water outflow, which is related to the increase in extracellular osmotic pressure and the membrane-lipid phase transition, can cause cell death. The fourth range (C) corresponds to very high cooling rates (more than 5000 degrees C min (-1)), at which the heat flow is very rapid and partially prevents water exit, which seems to preserve cell viability.     

Natural and human causes of earwig mortality during winter: temperature,parasitoids and soil tillage

Beneficial arthropods are often used for suppressing specific pest outbreaks in agricultural crop systems. The European earwig, Forficula auricularia L., (Dermaptera: Forficulidae), is an important natural enemy in fruit orchards. Recently, ecological studies were published describing earwig dispersal and survival during summer, hereby revealing clear differences between populations with a single brood (SBP) and two broods a year (DBP). In this article, we will describe three potential mortality factors of earwigs during the underground winter period, namely cold temperatures, parasitoids and soil tillage. This knowledge is essential for making efficient management strategies for increasing earwig abundance in fruit orchards. The effect of cold temperatures was checked during a 3‐year semi‐field experiment. Parasitism rates of Triarthria spp. (Fallén) and Ocytata pallipes (Fallén) (Diptera: Tachinidae) were obtained in a rearing experiment. The negative effect of soil tillage on the survival of earwigs nests was checked in a field experiment covering a 4‐year time period. A strong, negative relation between temperature [cooling day degrees (CDD)] and survival of female and male earwigs during winter was found. Male earwigs of SBP died very quickly, mimicking natural conditions. Between 60% and 90% of females do not survive winter. Survival of females in DBP was higher than in SBP. Parasitism rates vary a lot between species, generation, year and location (0–20%). During winter, we found a maximum mortality of 13%. There is a clear trend that soil tillage can reduce the number of nymphs in spring and summer by 50%. Implications for biocontrol are the following: (i) mortality owing to temperature can be predicted using CDD and if necessary preventive management actions can be undertaken to control pests; (ii) parasitism rates are negligible compared to high impact of temperature; and (iii) soil tillage can be timed more accurately using a recently developed day degree model.     

Cryopreservation of eukaryotic algae – a review of methodologies

Since pioneering work in the early 1960s, there has been growing interest and numerous experimental investigations into the cryopreservation of algal material. Mostly, these studies relate to the requirement for long term preservation and storage of algal material contained in culture collections or used in the seaweed mariculture industry. The present review deals with techniques used in the cryopreservation of biological samples and their application to both micro- and macroalgae. Methods for the prevention of cell damage and freezing injury during the cooling and low-temperature storage of algal material are discussed with reference to the effect on viability of such variables as cooling rates, final temperatures attained, the use of various types and concentrations of cryoprotectants, thawing rates, and storage times and temperatures. Some consideration is also given to the various methods used for increasing cell viability, including the induction of freezing tolerance. Cryopreservation protocols employed by numerous workers in this field are detailed, and concluding remarks are made on those techniques and conditions providing optimum viability of cryopreserved algae. This revised version was published online in June 2006 with corrections to the Cover Date.     

Simulation of scalp cooling by external devices for prevention of chemotherapy-induced alopecia

Hypothermia of the scalp tissue during chemotherapy treatment (scalp cooling) has been shown to reduce or prevent chemotherapy-induced hair loss. In this study, numerical models are developed to investigate the interaction between different types of external scalp cooling devices and the human scalp tissue. This work focuses on improving methods of modeling scalp cooling devices as it relates specifically to the prevention of chemotherapy-induced alopecia. First, the cooling power needed for any type of device to achieve therapeutic levels of scalp hypothermia is investigated. Subsequently, two types of scalp cooling devices are simulated: a pre-cooled/frozen cap design and a liquid-cooled cap design. For an average patient, simulations show that 38.5 W of heat must be extracted from the scalp tissue for this therapy in order to cool the hair follicle to 22 °C. In practice, the cooling power must be greater than this amount to account for thermal losses of the device. Simulations show that pre-cooled and liquid-cooled cap designs result in different tissue temperatures over the course of the procedure. However, it is the temperature of the coolant that largely determines the resulting tissue temperature. Simulations confirm that the thermal resistance of the hair/air layer has a large impact on the resulting tissue temperatures. The results should be correlated with experimental data as an effort to determine the optimal parameter choices for this model.     

Subthreshold changes in excitable membranes of Cucurbits pepo L. stem cells during cooling-induced action-potential generation

The nature of subthreshold changes in excitable plasma membranes has been investigated in stem parenchyma cells of Cucurbita pepo L. during action-potential generation induced by gradual cooling (from 23 to 10 ° C). The character of the subthreshold depolarization of excitable cells is shown to be mainly defined by a decrease in the activity of the plasma-membrane electrogenie pump (H⁺-ATPase). In its turn, the pump activity is controlled by thermal changes in the structure of the membrane lipid matrix. Based on the results obtained, a sequence of subthreshold changes has been suggested in which thermally induced structural rearrangements of membrane lipids play the role of trigger.Abbreviations AP action potential - DCCD N,N-dicyclohexil-carbodiimide - E_m membrane potential - I_e/I_m ratio of pyrene excimer/monomer fluorescence intensities     

Proteomic analysis of hypothalamic injury in heatstroke rats

Ischemic and oxidative damage to the hypothalamus may be associated with decreased heat tolerance as well as heatstroke formation. The present study explores the hypothalamic proteome mechanisms associated with heatstroke‐mediated hypothalamic ischemia, and oxidative damage. Heatstroke rats had hypotension, hypothalamic ischemia, and lethality. In addition, they had hyperthermia and hypothalamic blood–brain–barrier disruption, oxidative stress, activated inflammation, and neuronal apoptosis and degeneration. 2DE combined LC‐MS/MS revealed that heatstroke‐induced ischemic injury and apoptosis were associated with upregulation of L‐lactate dehydrogenase but downregulation of both dihydropyriminase‐related protein and 14‐3‐3 Zeta isoform protein. Heat‐induced blood–brain–barrier disruption might be related to upregulation of glial fibrillary acidic protein. Oxidative stress caused by heatstroke might be related to upregulation of cytosolic dehydrogenase‐1. Also, heat‐induced overproduction of proinflammatory cytokines might be associated with downregulation of stathmin 1. Heat‐induced hypothalamic ischemia, apoptosis, injury (or upregulation of L‐lactate dehydrogenase), blood–brain–barrier disruption (or upregulation of glial fibrillary acidic protein), oxidative stress (or upregulation of cytosolic dehydrogenase‐1), and activated inflammation (or downregulation of stathmin 1) were all significantly reversed by whole body cooling. Our data indicate that cooling therapy improves outcomes of heatstroke by modulating hypothalamic proteome mechanisms.     

Successful cryopreservation of rat pronuclear-stage embryos by rapid cooling

Embryo cryopreservation is a valuable tool for efficient production of animals as well as banking of genetic resources. Even though the laboratory rat is one of the most important experimental animals for various research fields, it has been reported that survival and developmental ability of cryopreserved rat embryos are generally low, especially at the early stages. The aim of the present study was to establish rapid cooling method that can be applied for cryopreservation of rat pronuclear-stage embryos using Cryotops (a device). First, optimal equilibration time was examined. Pronuclear-stage embryos were equilibrated in 7.5% ethylene glycol (EG) + 7.5% dimethylsulfoxide (DMSO) + 20% fetal calf serum (FCS) for 7, 8 or 9 min at 20–22 °C and then 15% EG + 15% DMSO + 0.5 M sucrose + 20% FCS for 1 min at 20–22 °C, being plunged into liquid nitrogen on Cryotops. This established that development to the 2-cell (82.0 ± 9.7% to 96.1 ± 3.0%) and blastocyst (36.5 ± 2.1% to 40.3 ± 10.2%) stages in vitro was not influenced by the equilibration time. Furthermore development to term in vivo (56.0 ± 4.9%) was equivalent to the rate (54.8 ± 6.6%) obtained with control embryos. Taken together, this demonstrated that this method is suitable for the successful cryopreservation of pronuclear-stage embryos in rats.     

An experimental research on cryopreserving rabbit trachea by vitrification

Vitrification is a promising alternative to tissue preservation, in which the tissue is permeated with cryoprotective agents (CPAs) in order to circumvent the hazardous effects associated with ice formation. In this study, we evaluate the effect of vitreous cryopreservation of rabbit trachea, by comparing vitrification procedure with conventional computer-programmed slow freezing approaches. Harvested rabbit trachea were tailored and divided into groups and cryopreserved by vitrification and programmed freezing, respectively. The morphology and ultrastructure of the thawed tracheal fragments including HE dyes, terminal deoxynucleotidyl transferase-mediated dUTP-digoxigenin nick end-labeling (TUNEL) staining, transmission electron microscopy (TEM) and scanning electron microscopy (SEM) were studied to assess the integrity of the tracheal fragments. Morphological studies demonstrated that both cryopreservation procedure retained the integrity of trachea, both epithelial cells, cilia and cartilage cells were in good shape. Compared with slow freezing methods, vitrification was less detrimental to cartilage cells and had a higher survival rate of chondrocytes and coverage of epithelium and cilia. Therefore, vitrification procedure can be a more satisfactory method to preserve trachea and the survival of chondrocytes in situ in cartilage tissue is adequate and respiratory epithelium is soundly present.