Interaction of rate of latent heat removal during freezing and rates of subsequent cooling and warming on survival of the blood protozoan, Babesia rodhaini

Babesia rodhaini parasites in murine blood containing 1.5 m DMSO were frozen at two rates, as judged by the duration of the “freezing plateau”, then cooled to ?196 °C and rewarmed at two rates to detect interactions between the duration of the plateau and rates of subsequent cooling and rewarming. Infectivity tests showed that fast and slow freezing (plateau times of about 1 sec and 30 sec, respectively) had similar effects on parasite survival when cooling was at 130 °C/min and warming was at 800 °C/min. However, when either the cooling rate was increased to 3500 °C/min or the warming rate was decreased to 2.3 °C/min, fast freezing decreased parasite survival more than did slow freezing. It is suggested that fast freezing accentuated the damaging effects of fast cooling and slow warming by increasing intracellular ice formation.     

Effects of differences in substrate supply on the energy metabolism of hypothermically perfused canine kidneys

Experiments were performed on the effects of differences in substrate supply on canine kidneys. Following 2 min of ischemia and flush perfusion for 5 min the kidneys were continuously perfused at 6 °C using albumin perfusate containing free fatty acids and glucose or Haemaccel perfusate without substrates.During 120 hr of perfusion neither potassium nor LDH nor GOT accumulation differed between the two perfusates and up to the 48th hr the tissue contents of adenine nucleotides as well as the energy charge potential were almost identical. The results show that in canine kidneys glucose or FFA supply during hypothermic continuous perfusion does not influence the overall cellular integrity and energetic capacity of the renal cortex at least up to the 48th hr of preservations.     

The effect of cooling and warming rate on cortical cell function of glycerolized rabbit kidneys

Experiments previously reported (I. A. Jacobsen, D. E. Pegg, H. Starklint, J. Chemnitz, C. J. Hunt, P. Barfort, and M. P. Diaper, Cryobiology19, 668, 1982) suggested that rabbit kidneys permeated with 2 M glycerol are least damaged during freezing and thawing if they are cooled very slowly (1 °C/ hr). Using similar techniques of glycerolization, cooling, storage at ?80 °C, rewarming, and deglycerolization, active cell function in cortical tissue slices prepared from such kidneys has now been studied. Oxygen uptake, tissue $\text{K}{}^{\mathrm{+}}\text{Na}{}^{\mathrm{+}}$ ratio after incubation, and slice/medium PAH ratio after incubation were measured. Kidneys cooled at 3.1 °C/min and warmed at 4.2 °C/min gave poor results in the previous studies and the lowest levels of cell function in the present experiments. Kidneys cooled at 1 °C/hr exhibited degrees of slice function that were dependent on warming rate: warming at 1 °C/min was better than warming at either 1 °C/hr or c.20 °C/min. These results refine the previously drawn conclusions, (loc cit) and indicate optimal cooling and warming rates for rabbit kidneys containing 2 M glycerol, in the region of 1 °C/hr cooling and 1 °C/min warming. These rates are much lower than have hitherto been used by others for any system. Some implications of these findings are discussed.     

Effect of cooling and warming rate on glycerolized rabbit kidneys

Cooling and warming rates are known to be important determinants of viability for cryopreserved cells, but optimal rates have not previously been determined for any whole organ. In this study, rabbit kidneys, permeated with 2 M glycerol were cooled to -80 degrees C at four rates varying from 1 degrees C/hr to 3.1 degrees C/min and then rewarmed at four rates from 1 degrees C/hr to 4.2 degrees C/min, giving 16 experimental treatments. After gradual deglycerolization at 10 degrees C, each kidney was autografted and observed for 30 min. Assessment was by measurement of vascular resistance, immediate post-thaw lactate dehydrogenase (LDH) release, gross appearance, light- and electron microscopy, and tissue K+/Na+ ratio 30 min after transplantation. The best results were obtained after cooling at 1 degrees C/hr; warming rate had little apparent influence on the criteria used to assess function with the exception of LDH release, which indicated a preferred warming rate around 1 degrees C/min. Histological studies revealed extensive vascular damage, notably to the glomerular capillaries, that was minimized by very slow cooling. Freeze substitution, carried out on samples removed at -80 degrees C, demonstrated extensive ice formation in the interstitial space and, at the faster cooling rates, in the glomerular capillaries. Intracapillary ice formation was reduced in the kidneys cooled at 1 degrees C/hr.     

Ischemia-reperfusion Model of Acute Kidney Injury and Post Injury Fibrosis in Mice

Ischemia-reperfusion induced acute kidney injury (IR-AKI) is widely used as a model of AKI in mice, but results are often quite variable with high, often unreported mortality rates that may confound analyses. Bilateral renal pedicle clamping is commonly used to induce IR-AKI, but differences between effective clamp pressures and/or renal responses to ischemia between kidneys often lead to more variable results. In addition, shorter clamp times are known to induce more variable tubular injury, and while mice undergoing bilateral injury with longer clamp times develop more consistent tubular injury, they often die within the first 3 days after injury due to severe renal insufficiency. To improve post-injury survival and obtain more consistent and predictable results, we have developed two models of unilateral ischemia-reperfusion injury followed by contralateral nephrectomy. Both surgeries are performed using a dorsal approach, reducing surgical stress resulting from ventral laparotomy, commonly used for mouse IR-AKI surgeries. For induction of moderate injury BALB/c mice undergo unilateral clamping of the renal pedicle for 26 min and also undergo simultaneous contralateral nephrectomy. Using this approach, 50-60% of mice develop moderate AKI 24 hr after injury but 90-100% of mice survive. To induce more severe AKI, BALB/c mice undergo renal pedicle clamping for 30 min followed by contralateral nephrectomy 8 days after injury. This allows functional assessment of renal recovery after injury with 90-100% survival. Early post-injury tubular damage as well as post injury fibrosis are highly consistent using this model.     

Survival of the parasitic protozoan, Babesia bigemina, in blood cooled at widely different rates to -196 degrees C

Survival of the parasitic protozoan, Babesia bigemina, in blood cooled at widely different rates to ? 196°C. International Journal for Parasitology4: 169–172. The infectivity of Babesia bigemina in blood containing 2 m DMSO was tested in 99 cattle after the blood had been cooled to ? 196°C at eight rates ranging from 0·73–3070°C/min. Blood cooled at each rate was infective; 95 of the recipients became infected, the exceptions being four of the seven cattle inoculated with blood cooled at 3070° C/min. The infectivity of blood cooled at 39, 82 and 212°C/min was higher than that of blood cooled at slower or faster rates. Least depression of infectivity occurred at 82°C/min.     

The effect of cooling and warming rates on the survival of cryopreserved L-cells

A tissue culture assay has been used to measure the survival of murine lymphoma cells (L-cells) after freezing and thawing in the presence of 2 M glycerol or 1.6 M dimethyl sulfoxide. The effect of variations in cooling rate (0.1 to 10.0 °C/min) and warming rate (0.3 to 200 °C/min) were studied. It was found that survival exhibited a peak at the “conventional” combination of slow cooling and rapid warming (~1 and 200 °C/ min, respectively). It was also shown, however, that a second peak of similar magnitude occurred when the cells were cooled and rewarmed at 0.2-0.3 °C/min. These results are interpreted on the basis of current theories of freezing injury, stressing the importance of damage produced by the recrystallization of intracellular ice and by solute loading. The ultraslow rates of cooling and rewarming which produced the second survival peak are practicable for whole organs, and their potential importance for organ cryopreservation is apparent.     

Microwave thawing of frozen kidneys: A theoretically based experimentally-effective design

Equipment was designed and fabricated for uniformly thawing frozen canine kidneys using single-frequency electromagnetic radiation. Complete and uniform warming of frozen kidneys from ?70 to +14 °C over periods ranging from 1.5 to 4.5 min was achieved without “cooking” or experiencing thermal runaway. Dielectric measurements of renal slices (medulla and cortex) were performed as a function of temperature at a frequency of 918 MHz for a Me₂SO cryoprotectant concentration of 5% (0.7 M). Results of these measurements were then employed as an input to analytical computer models which were used to predict the internal field intensities and power distribution results for both frozen and thawed kidneys. From these predictions, a 918-MHz EM illuminator for thawing canine kidneys was designed and fabricated. Twenty-seven kidneys were thawed using this illumination system. Of these, excellent uniformity of thawing was achieved for 17 kidneys, good uniformity for 8 kidneys, and for only 2 kidneys was thawing uniformity fair to poor.     

Microscopic observation of intracellular ice formation in unfertilized mouse ova as a function of cooling rate

A physical-chemical analysis of water loss from cells at subzero temperatures had shown that the likelihood of intracellular ice formation increased with increasing cooling rate (22). We have now used a modified version of a unique conductioncooled cryomicroscope stage (8) to observe the freezing of unfertilized mouse ova suspended in dimethyl sulfoxide. Survival measurements showed that the respective survivals of ova were about 65, 56, and 0% when they were cooled at rates of 0.2 to 1.5, 2.5, and 5.4 °C/min. Direct microscopic observation of mouse ova during freezing showed that the respective fractions of cells that froze intracellularly were 13, 72, and 100% when they were cooled at rates of 1.3, 2.9, and 4.8 °C/min or faster. These values agree with those predicted from the physical-chemical analysis for cells the size of mouse ova. The microscopic observations have also shown that intracellular freezing generally occurred at about ?40 to ?45 °C. We had previously observed that mouse embryos must be cooled slowly to ?50 °C or below if they are to survive subsequent rapid cooling to ?196 °C. The observation of intracellular ice formation at ?45 °C supports the interpretation that at temperatures above ?50 °C the embryos still contain water capable of freezing intracellularly.     

Optimizing conditions for cryopreservation of an insect cell line

A cell line (UM-BGE-2) derived from embryos of the cockroach Blattella germanica was frozen to ?196 °C under a variety of conditions and cell viability was assayed after warming. It was found that cell viability was affected by the cooling rate, the warming rate, the controlled cooling endpoint temperature, and the type and concentration of cryoprotectant. The best survival for cells suspended in Grace's tissue culture medium containing 1 M Me₂SO was obtained when cells were cooled at 1 °C/ min to at least ?90 °C before being placed in liquid nitrogen and warmed at more than 900 °C/min. Cultures initiated from these frozen cells produce typical growth curves and appear normal after several passages.     

Survival of frozen-thawed human red cells as a function of cooling and warming velocities

Human red cells were equilibrated for 30 min at 20 °C in buffered saline containing 2 m glycerol and then frozen to ?196 °C at 0.27, 1.7, 59, 180, 480, 600, and 1300 °C/ min and warmed at 0.47, 1, 26, 160, and 550 °C/min. Cells frozen at 600 and 1300 °C/min responded in the classical fashion for cells containing intracellular ice; i.e., survivals were low when warming was slow (<10%), but increased progressively with increasing warming rate. The sensitivity to slow warming presumably reflects the recrystallization of intracellular ice. Cells frozen at 59 and 180 °C/ min yielded high survivals at all warming rates. This response is also consistent with the findings for other cells cooled just slowly enough to preclude intracellular ice. Cells frozen very slowly at 0.27 and 1.7 °C/ min, however, responded differently; survivals were considerably higher when warming was slow (0.47 or 1 °C/min) than when it was 26, 160, or 550 °C/min. This response is analogous to that observed recently by others in mouse embryos and in higher plant tissue-culture cells and to that observed for many years in higher plants. It also confirms previous observations of Meryman in human red cells. It may reflect osmotic shock from rapid dilution but, if so, the basis of the osmotic shock is uncertain.     

Survival of canine kidneys after treatment with dimethyl-sulfoxide, freezing at --80 degrees C, and thawing by microwave illumination.

Forty canine kidneys were the subject of this pilot study where control groups perfused with Perfudex plus DMSO (1.4 m), modified Collins' solution with DMSO (1.4 m) and modified Sacks' solution with DMSO (1.4 m) showed little toxicity and life-sustaining conservation. In the experimental group, 16 kidneys were frozen for 15 min to ?80 °C, thawed by microwave illumination, and reimplanted. Of the 16 dogs, eight survived 2–14 months on their single kidney. The technique of inducing freezing by using intra-arterial cold helium and thawing with high-power microwave illumination gave an overall success rate of 50% long-term life-sustaining survival.     

Capacitation-like changes occur in mouse spermatozoa cooled to low temperatures

Previously we showed that > 70% of mouse spermatozoa cooled slowly from 37°C to 4°C and warmed have undergone capacitation-like changes as examined by a chlortetracycline staining assay. These membrane changes are reflected in the ability of cooled spermatozoa to achieve fertilization rates in vitro similar to those of uncooled controls when added to oocytes immediately upon warming. The aim of this study was to determine the nature of these membrane changes. We found they were not dependent upon the rate of cooling to 4°C and similar changes were observed when spermatozoa were cooled to higher temperatures (10° and 20°C), but it took longer for 50% of the spermatozoa to undergo such changes (3, 18, and 27 min for spermatozoa held at 4°, 10°, and 20°C, respectively). Mixing cooled spermatozoa with oocytes immediately upon warming produced fertilization rates similar to fresh spermatozoa capacitated in vitro for 90 min before the oocytes were added. The rate of sperm penetration as determined by the fluorescent DNA stain Hoescht 33258 was also similar. However, the penetration time for cooled spermatozoa was significantly shortened when they were preincubated for 90 min before being added to oocytes. We conclude that membrane changes resembling capacitation (1) occur during cooling to temperatures above freezing, (2) are independent of cooling rate, (3) proceed faster at lower temperatures, and (4) obviate the need for prior capacitation in vitro before mixing with oocytes. Mol. Reprod. Dev. 46:318–324, 1997. © 1997 Wiley-Liss, Inc.     

Effect of dimethylsulphoxide on the functional characteristics of isolated perfused rat liver

Exposure of rat liver, perfused with 7% BSA in Krebs-Ringer bicarbonate buffer, to 1.4 m Me₂SO at 35 °C had no effect on the release of potassium from the livers, but the rate of urea synthesis fell from 0.6 to 0.1 μmol/min. Bile production also decreased and the total amount collected during perfusion was only half that produced by controls. After perfusion for 4 hr at 35 °C control livers and those exposed to Me₂SO started to release GOT into the perfusate but livers exposed to the cryoprotective compound released the enzyme at a faster rate.Exposure of livers to Me₂SO at 5 °C resulted in potassium being released at a slower rate (0.98 μmol/min) than from cooled controls (1.19 μmol/min) and urea synthesis was decreased from 0.8 to 0.2 μmol/min. Bile production also declined but, because bile flow normally ceases during hypothermia, the effect on this aspect of liver function was probably less than was found at 35 °C. Release of GOT from livers exposed to Me₂SO at 5 °C was quite different from that observed at 35 °C; the enzyme appeared in the perfusate after about 8 hr and it was present in much lower concentration than was found with appropriately cooled controls which started to release the enzyme after 6 hr.Thus, exposure of rat liver to Me₂SO at 5 °C appears to be slightly less damaging than exposure at 35 °C and it may even have a beneficial effect on some aspects of liver function in vitro.     

Transition temperatures in the sensitivity of escherichia coli B/r to lysozyme

Lysozyme attacked Escherichia coli B/r in the absence of EDTA or imposed osmotic shocks when the cells were rapidly cooled below specific temperatures. Cells subjected to lysozyme while being cooled to below 20°C began to lose ability to subsequently form colonies. This sensitivity increased with decreasing temperatures and almost all cells cooled to 0°C were affected. Slightly hypertonic solutions did not improve survival. Cells cooled first to as low as 5°C and then subjected to lysozyme while cool did not lose their ability to form colonies subsequent to rewarming. However, 70% of the cells cooled first to 0°C and subjected to lysozyme lost their colony-forming ability. Cell lysis also began when treated near 5°C, but even when treated at 0°C about 50% of the cells maintained their rod shape in the presence of lysozyme. These results are discussed in terms of a possible phase transition in a portion of the cell envelope and/or a transient osmotic swelling as a results of metabolic pumps failing at the low temperatures.     

Freeze-thaw survival of the free-living nematode Caenorhabditis briggsae.

Approximately 75% or more of the L2 and L3 juvenile stages of the free-living nematode Caenorhabditis briggsae survived freezing and thawing without loss of fertility. Optimum survival depended upon a combination of conditions: (1) pretreatment with 5% DMSO at 0 °C for 10 min, (2) 0.2 °C per minute cooling rate from 0 to ?100 °C prior to immersion into liquid nitrogen, and (3) a 27.6 °C per minute warming rate from ?196 °C to ?10 °C. Storage at ?196 °C for more than 100 days was without effect on viability or fertility. Some of the L4 (about 50%) and adult (about 3%) stages survive the routine freeze-thaw treatment. However, there was no recovery of either embryonic stages or embryonated eggs from ?196 °C under these standard conditions. Either very fast cooling (about 545 °C/min) or fast warming (about 858 °C/min) rates diminished survival of the L2 and L3 stages drastically.Scanning electron microscopy revealed that freeze-thaw survivors with aberrant swimming behavior had cuticular defects. In juvenile forms, the altered swimming motion was lost after a molt whereas as abnormal adults grew, sinusoidal movement resumed. In the L4 and adult forms the cuticular abnormalities lowered viability and fertility. It is concluded that survival of nematodes from a freeze-thaw cycle is contingent upon establishing specific cryobiological conditions by varying aspects of the procedure that gave high recoveries of L2 and L3 stages.     

Towards whole sheep ovary cryopreservation

Cryopreservation of ovarian tissue aims to assist young women who require treatments that may lead to sterility or infertility. Cryopreservation procedures should therefore be as simple and efficient as possible. This study investigates rapid cooling outcomes for whole sheep ovaries. Ovaries were perfused with VS4 via the ovarian artery, and cooled by quenching in liquid nitrogen in less than a minute (estimated cooling rate above 300 °C/min till the vitreous transition temperature). The ovaries were rewarmed in two stages: slow warming (12–16 °C/min from −196 to −133 °C) in liquid nitrogen vapour, followed by rapid thawing in a 45 °C water bath at about 200 °C/min. DSC measurements showed that under these cryopreservation conditions VS4 would vitrify, but that VS4 perfused ovarian cortex fragments did not vitrify, but formed ice (around 18.4%). Immediately following rewarming, a dye exclusion test indicated that 61.4 ± 2.2% of small follicles were viable while histological analysis showed that 48 ± 3.8% of the primordial follicles were normal. It remains to be clarified whether follicle survival rates will increase if conditions allowing complete tissue vitrification were used.     

Viability and Morphology of rat heart cells after freezing and thawing of the whole heart

Intact adult rat hearts were cooled in the presence of 10% DMSO according to an external cooling program which approximated the optimal external three-step cooling program for the isolated adult heart cells: 20 min at ?20 °C, 0.2 °C/min from ?20 to ?25, ?30, or ?50 °C, and rapid cooling to ?196 °C. Following rapid thawing, cells were isolated after perfusion with a 0.1% collagenase solution. Only cells which originated from the free wall of the right ventricle could be isolated, even after cooling to ?20 °C. Most cells from hearts cooled to ?196 °C did not survive. When the third cooling step was omitted and the end temperature of the second cooling step was ?30 °C, 38% of the cells excluded trypan blue, 29% were morphologically intact, and 30% showed spontaneous contractions after thawing, expressed as percentages of the control, A much lower survival was found after cooling to ?50 °C.Histological and electron microscopical study of the heart immediately after thawing revealed no differences between hearts cooled to ?20, ?30, or ?196 °C. Also no marked differences were observed between the morphological integrity after freezing and thawing of the atrium, the left and right ventricle walls, and the ventricular septum. The survival data suggest the presence of nonmorphologically detectable alterations in cells frozen to ?196 °C, compared to cells frozen to ?30 °C. The morphological investigations indicate no essential differences in resistance of atrial and ventricular cells to the freezing process.Experiments involving neonatal rat hearts cooled to ?196 °C, according to the method which gave optimal preservation of the isolated cells, revealed that after thawing cells are present from which growing and contracting cultures can be derived. It appears that cells in the neonatal rat heart are more resistant to freezing to ?196 °C than cells in the adult rat heart.     

Effect of warming rate on mouse embryos frozen and thawed in glycerol

Mouse embryos (8-cell) fully equilibrated in 1.5 M-glycerol were cooled slowly (0.5 degrees C/min) to temperatures between - 7.5 and - 80 degrees C before rapid cooling and storage in liquid nitrogen (-196 degrees C). Some embryos survived rapid warming (approximately 500 degrees C/min) irrespective of the temperature at which slow cooling was terminated. However, the highest levels of survival of rapidly warmed embryos were observed when slow cooling was terminated between -25 and -80 degrees C (74-86%). In contrast, high survival (75-86%) was obtained after slow warming (approximately 2 degrees C/min) only when slow cooling was continued to -55 degrees C or below before transfer into liquid N2. Injury to embryos cooled slowly to -30 degrees C and then rapidly to -196 degrees C occurred only when slow warming (approximately 2 degrees C/min) was continued to -60 degrees C or above. Parallel cryomicroscopical observations indicated that embryos became dehydrated during slow cooling to -30 degrees C and did not freeze intracellularly during subsequent rapid cooling (approximately 250 degrees C/min) to -150 degrees C. During slow warming (2 degrees C/min), however, intracellular ice appeared at a temperature between -70 and -65 degrees C and melted when warming was continued to -30 degrees C. Intracellular freezing was not observed during rapid warming (250 degrees C/min) or during slow warming when slow cooling had been continued to -65 degrees C. These results indicate that glycerol provides superior or equal protection when compared to dimethyl sulphoxide against the deleterious effects of freezing and thawing.     

Survival of tissue culture cells frozen by a two-step procedure to -196 degrees C. II. Warming rate and concentration of dimethyl sulphoxide.

Chinese hamster tissue culture cells in dimethyl sulphoxide (5%) required a lower holding temperature (?35 °C) for optimal survival on slow warming from ?196 °C using a two-step cooling schedule, compared with that required (?25 °C) when warming was rapid. A lower concentration of dimethyl sulphoxide (1%) did not affect the “protection” against damage on cooling from the holding temperature to ?196 °C and thawing. The results suggest that protective agents allow cells to be cooled initially to the holding temperature and minimize damage at the holding temperature. Damage following subsequent cooling and thawing may thus occur mainly as dilution shock on rewarming. This can be minimized by allowing the cells to shrink at the holding temperature.