Some effects of propane-1,2-diol on human platelets

The Kedem-Katchalsky equations and permeability data previously reported (F. G. Arnaud and D. E. Pegg. Permeation of glycerol and propane-1,2-diol into human platelets. Cryobiology 27, 130-136, 1990) have been used to design methods for adding and removing propane-1,2-diol (propylene glycol, PG) with human platelets. Mean platelet volume was kept within the tolerated range of 60 to 120% of normal. PG concentrations of 0.5, 1.0, 2.0, 2.5, and 3.0 M were studied at 2, 21, and 37 degrees C. PG was removed only at 21 degrees C. The effects of concentration of PG, temperature, and duration of exposure on the hypotonic stress response and ADP-induced aggregation were measured. It was found that platelets would tolerate exposure to PG concentrations up to 2 M at 21 or 2 degrees C for up to 15 min. The extent of damage increased considerably at higher temperatures and concentrations. These data provide the necessary basis for experiments to cryopreserve platelets with PG.     

Platelet cryopreservation with glycerol, dextran, and mannitol: recovery of 5-hydroxytryptamine uptake and hypotonic stress response

Human platelets were frozen in 0.5 M glycerol, 0.5 M glycerol + 3% Dextran T40, or 0.5 M glycerol + 5% mannitol. The recovery of active transport of 5-hydroxytryptamine (5-HT) and the hypotonic stress response after freezing were dependent on the rate of cooling: the optimum range of rates was between 12 and 23 degrees C/min. The numerical recovery of cells was independent of cooling rate, but freezing altered the cell-size distribution. The combination of dextran and glycerol was no better than glycerol alone at protecting platelets against freezing damage. Mannitol, however, adversely affected platelet 5-HT uptake, and this was reflected in a low recovery of that activity after freezing platelets in glycerol supplemented with mannitol.     

The effects of 1,2-propanediol as a cryoprotectant on the freezing of mouse oocytes

Cryopreservation of mammalian eggs has been successfully accomplished using 1,2-propanediol (PG). Effects of holding times of 0 and 30 min at -40 degrees C and storage times of 1 d and 1 mo at -196 degrees C were investigated in combination with various concentrations of PG (1.0, 1.5, and 2.0M) to determine the survival and fertilizability of mouse oocytes rapidly frozen and thawed in straws. A rapid one-step dilution using 0.5 M sucrose solution inside the straws was used following the thawing of oocytes. A significant effect of PG concentration was found between 1.0 M and 1.5 or 2.0 M (P<0.01), but no significance was discovered between 1.5 M and 2.0 M (P>0.05) on subsequent survival and fertilizability of frozen and thawed mouse oocytes. With 2.0 M PG, the best survival rate (58.3%) and fertilizability rate (19.0%) were obtained by holding at -40 degrees C for 30 min and by storage at -196 degrees C for 1 d. Thirty minutes of holding at -40 degrees C reduced oocyte damage during the procedure but not significantly (P>0.05). In addition, there was no significant difference in the various storage periods (P>0.05). This study demonstrated that mammalian oocytes can be cryopreserved in the presence of 1,2-propanediol by utilizing a rapid freezing and thawing procedure.     

Development of optimal techniques for cryopreservation of human platelets. I. Platelet activation during cold storage (at 22 and 8 degrees C) and cryopreservation.

Using the current blood bank storage conditions at 22 degrees C, the viability and function of human platelets can be maintained for only 5 days. This does not allow for the necessary and extensive banking of platelets needed to treat patients afflicted with thrombocytopenia, a side effect of many invasive surgeries such as cardiopulmonary bypass or bone marrow transplantation. The development of optimal techniques for long-term cryopreservation and banking of human platelets would provide the ability to greatly extend the viable life of the platelet and would fulfill an increasing and urgent need in many clinical applications. To determine the optimal techniques for platelet preservation, the expression of an activation marker, phosphatidylserine, on the platelet membrane during storage at 22 and 8 degrees C as well as during the different freezing preservation processes was examined using flow cytometry and annexin V binding assay. Human platelets were identified by both CD41 and light scatter in flow cytometry. In cryopreservation experiments, effects of the following factors on platelet activation were evaluated: (a) cryoprotective agents (CPAs) type: dimethyl sulfoxide (Me2SO), ethylene glycol (EG), and propylene glycol (PG), (b) CPA concentration ranging from 0 to 3 M, and (c) ending temperatures of a slow cooling process at -1 degrees C/min. Our results demonstrated that (a) approximately 50% of platelets were activated on days 7 and 16 at 22 and 8 degrees C, respectively; (b) platelets were not significantly activated after 30-min exposure to 1 M Me2SO, EG, and PG at 22 degrees C, respectively, and (c) there was a significant difference in cryoprotective efficacy among these three CPAs in preventing platelets from cryoinjury. After being cooled to -10 degrees C, 74% of the cryopreserved platelets survived (nonactivated) in 1 M Me2SO solution, while in 1 M EG and 1 M PG solutions, 62 and 42% of the platelets survived, respectively. Using the information that Me2SO consistently yields higher percentages of nonactivated platelets and does not seem to be cytotoxic to platelets for 30-min exposure time, this was found to be the optimal cryoprotective agent for platelets. In addition, significant Me2SO toxicity to platelets was not noted until Me2SO concentrations exceeded 2 M. Finally, a concentration of 1 M Me2SO proved to be the most effective at all cryopreservation ending temperatures tested (-10, -30, -60, and -196 degrees C). In conclusion, under the present experimental conditions, a storage temperature of 8 degrees C appeared to be much better than 22 degrees C. Although the potential chemical toxicity of 1 M Me2SO, EG, or PG is negligible, 1 M Me2SO was found to be optimum for cryopreservation of human platelets. PG has the least cryoprotective function for low-temperature platelet survival.     

The effects of osmotic stress on human platelets

The effect of osmotic stress on human platelets was investigated at 0, 25, and 37 degrees C. The osmolality of the suspending plasma was decreased by adding water or increased by adding sodium chloride or sucrose. After 5 min, isotonicity was restored by dilution with an excess of isotonic phosphate-buffered saline. After centrifugation, the platelets were resuspended in autologous plasma and then incubated for 1 hr at 37 degrees C before assaying the active transport of 5-hydroxytryptamine (5-HT) and the hypotonic stress response. Anisosmotic conditions had a greater effect on the extent of volume reversal in the hypotonic stress test than on 5-HT uptake. At 25 degrees C, only moderate degrees of hypotonicity (0.25 osmol/kg) or hypertonicity (0.59 osmol/kg) were sufficient to depress the hypotonic stress response. In general, platelets tolerated departures from isotonic conditions better at 0 degree C than at the higher temperatures. Furthermore, at 0 and 25 degrees C approximately equiosmolal concentrations of sucrose and sodium chloride depressed the hypotonic stress response to similar extents, but at 37 degrees C high osmolalities (greater than 2 osmol/kg) were tolerated better when the additive was sucrose than when it was sodium chloride. Platelets shrank when subjected to hyperosmotic conditions, but their discoid shape and the peripheral band of microtubules were maintained.     

Temperature dependence of the survival of human erythrocytes frozen slowly in various concentrations of glycerol.

One widely accepted explanation of injury from slow freezing is that damage results when the concentration of electrolyte reaches a critical level in partly frozen solutions during freezing. We have conducted experiments on human red cells to further test this hypothesis. Cells were suspended in phosphate-buffered saline containing 0-3 M glycerol, held for 30 min at 20 degrees C to permit solute permeation, and frozen at 0.5 or 1.7 degrees C/min to various temperatures between -2 and -100 degrees C. Upon reaching the desired minimum temperature, the samples were warmed at rates ranging from 1 to 550 degrees C/min and the percent hemolysis was determined. The results for a cooling rate of 1.7 degrees C/min indicate the following: (a) Between 0.5 and 1.85 M glycerol, the temperature yielding 50% hemolysis (LT50) drops slowly from -18 to -35 degrees C. (b) The LT50's over this range of concentrations are relatively independent of warming rate. (c) With glycerol concentrations of 1.95 and 2.0 M, the LT50 drops abruptly to -60 degrees C and to below -100 degrees C, respectively, and becomes dependent on warming rate. The LT50 is lower with slow warming at 1 degree C/min than with rapid. With still higher concentrations (2.5 and 3.0 M), there is no LT50, i.e., more than 50% of the cells survive freezing to-100 degrees C. Results for cooling at 0.5 degrees C/min in 2 M glycerol were similar except that the LT50s were some 10-20 degrees C higher. A companion paper (Rall et al., Biophys. J. 23:101-120, 1978) examines the relation between survival and the concentrations of salts produced during freezing.     

A spectrophotometric method for following initial rate kinetics of blood platelet aggregation

A double-beam recording spectrophotometer was used to assay platelet aggregation. Agonist-induced turbidity changes, at 540 nm, in dilute suspensions of platelets (1 ml, 6-8 X 10(7) platelets) were recorded differentially against a reference cuvette, also containing platelets, as a function of time. The curves obtained showed downward pen deflections (decrease of turbidity) abolished by preincubation with the aggregation inhibitor, citrate. The turbidity decrease occurred simultaneously with microscopically determined single platelet recruitment into aggregates and its initial slope (r0) was a linear function of platelet concentration upto approximately 1.5 X 10(8) per ml. At a fixed platelet concentration the r0 values of ADP-induced aggregation of calf platelet-rich plasma varied as a hyperbolic function of ADP concentration at both 32 degrees C and 37 degrees C. The kinetic data at 37 degrees C were comparable to those, in the literature, obtained by following single platelet recruitment into aggregates. The increase in turbidity due to ADP-induced shape-change (6 +/- 1%, mean +/- S.E.M., n = 7) measured in the present study was substantially greater than that (3%) measured in the aggregometer.     

Seleno-DL-methionine and the protection of human platelets against freezing injury

The effect of seleno-DL-methionine, which has antioxidative properties, on the recovery of human platelets after freezing with 0.5 mol/liter glycerol or 0.7 mol/liter (5% v/v) dimethyl sulfoxide was investigated. Incubation of platelets with 2 mumol/liter seleno-DL-methionine for 30 min at room temperature before equilibration with the protective additives improved the post-thaw uptake of 5-hydroxytryptamine and the percentage reversal in the hypotonic stress test. The effect was small, but in view of the ability of seleno-DL-methionine to inhibit lipid peroxidation in membranes, the results suggest that oxidative damage is implicated in freezing injury. The dimethyl sulfoxide protocol apparently afforded greater protection to the platelets than the glycerol protocol. But, if the platelets were incubated for 24 hr at 37 degrees C after thawing, there was a marked improvement in the response of cells in the hypotonic stress test, particularly in the samples frozen with glycerol, and there was no longer any difference between the two additives. There was, however, a concomitant loss of almost half the number of cells in the thawed suspensions during the prolonged incubation at 37 degrees C.     

Fixation of potentially lethal radiation damage by post-irradiation exposure of Chinese hamster cells to 0.5 M or 1.5 M NaCl solutions.

The effect of 0.05 M and 1.5 M NaCl treatments on CHO cells during and after irradiation has been examined. Treatment with either hypotonic or hypertonic salt solutions during and after irradiation resulted in the fixation of radiation damage which would otherwise not be expressed. The half time for fixation was 4 to 5 min, and the increased expression of the potentially lethal damage by anisotonic solutions was mainly characterized by large decreases in the shoulder of the survival curve, as well as by decreases in DO. Fixation of radiation damage at 37 degrees C occurred to a much greater extent for the hypertonic treatment than for the hypotonic treatment and was greater at 37 degrees C than at 20 degrees C. Although both the hypotonic and hypertonic treatments during and after irradiation reduced or eliminated the repair of sublethal and potentially lethal damage, treatment during irradiation only, radiosensitized the cells when the treatment was hypotonic, and radioprotected the cells when the treatment was hypertonic. These observations are discussed in relation to salt treatments and different temperatures altering competition between repair and fixation of potentially lethal lesions, the number of which depends on the particular salt treatment at the time of irradiation.     

The effect of glycerol on aggregation and ultrastructure of human platelets

Cryopreservation of platelets depends on the use of cryoprotectants to reduce freezing damage. However, the cryoprotectants may in themselves be harmful, and it is important to determine the amount of damage caused by these compounds. Platelets were incubated at 37 °C in plasma containing 0, 0.5 and 1.0 mol/liter glycerol. The aggregation response to 10 and 5 μmol/liter ADP was determined after 2, 15, 30, 60, and 120 min of incubation. Samples were prepared for electron microscopy after 30 min at 37 °C. Glycerol at a concentration of 0.5 mol/liter had no effect on the extent of aggregation, whereas 1.0 mol/liter glycerol caused a progressive decline in the response. However, platelet ultrastructure appeared to be undisturbed by 1.0 mol/liter glycerol. The results demonstrated a lack of toxicity of 0.5 mol/liter glycerol and support the use of glycerol at concentrations less than 1.0 mol/liter for cryopreservation.     

Proteolytic degradation of vimentin and glial fibrillary acidic protein in rat astrocytes in primary culture

The receptor for ADP on the platelet membrane, which triggers exposure of fibrinogen-binding sites and platelet aggregation, has not yet been identified. Two enzymes with which ADP interacts on the platelet surface, an ecto-ATPase and nucleosidediphosphate kinase, have been proposed as possible receptors for ADP in ADP-induced platelet aggregation. In the present study, experiments were conducted with washed human platelets to examine if a relationship existed between platelet aggregation, fibrinogen binding and the enzymatic degradation of ADP. With 12 different platelet suspensions, a good correlation (P less than 0.01) was found between the extent of platelet aggregation and the amount of 125I-fibrinogen bound to platelets after ADP stimulation. No correlation was found between these parameters and the rate or extent of transformation of [14C]ADP to [14C]ATP or [14C]AMP. The binding of fibrinogen to platelets was inhibited in parallel with aggregation when ADP stimulation was impaired by the enzymatic degradation of ADP by the system creatine phosphate/creatine phosphokinase, or by the use of specific antagonists, such as ATP and AMP. These antagonists also influenced the enzymatic degradation of ADP. This effect occurred at lower concentrations of ATP or AMP than those required to inhibit ADP-induced platelet aggregation and fibrinogen binding. Our results demonstrate that ATP and AMP may be used as specific antagonists of the ADP-induced fibrinogen binding to platelets. They do not provide evidence to suggest that enzymes which metabolize ADP on the platelet surface are involved in the mechanism of ADP-induced platelet aggregation.     

Effects of gas bubbling and other forms of convection on platelets in vitro

Citrated platelet-rich human plasma was subjected to one of three experimental treatments at 37 degrees C for 15 min: stirring, bubbling (with stirring), and gentle agitation achieved by a rocking motion. The last two were "equiconvective" as judged by equilibration rates with CO2 and O2 but presumably differed in the shear stress they imposed on the cells. Stirring platelets in normal air or 5% CO2-air caused no significant aggregation. Bubbling air through platelet-rich plasma increased its pH and marked aggregation occurred. Bubbling CO2-air caused the platelet-rich plasma pH to attain its physiological level of 7.4 with less aggregation. In both cases, subsequent ADP-induced aggregation was diminished. Rocking (without stirring) in the presence of CO2-air caused negligible aggregation in platelets and an enhanced response to ADP. Because of the marked difference between the two equiconvective treatments, bubbling and rocking, the main factor in activating the human platelets is suggested to be shear stress (potentiated by high pH), with perhaps a lesser contribution from the air-plasma interface.     

Preservation of Pseudomonas putida bacteria at low temperatures]

We have found that the mode of cooling, composition of cryopreservation medium, original concentration of cells and storage temperature affect viability of Pseudomonas putida bacteria during low-temperature preservation. We have elaborated the conditions of preservation, providing for a high survival of bacteria, namely: one-stage cooling with the rates of 30, 40 degrees C/min or immersion into liquid nitrogen in the culturing medium with addition of sucrose, glycerol or dimexide in the concentration of 0.5 M; storage temperature is -80 degrees C divided by -196 degrees C.     

Combined effect of glycerol concentration and cooling velocity on motility and acrosomal integrity of boar spermatozoa frozen in 0.5 ml straws

The interaction of glycerol concentrations of 0-10% and cooling rates from 1 to 1,500 degrees C/min with boar spermatozoa motility and acrosomal integrity (proportion of spermatozoa with normal apical ridge) was studied after thawing 0.5 ml straws at a constant rate. While increasing the glycerol concentration from 0 to 4% progressively improved motility, the percentage of spermatozoa with a normal apical ridge gradually decreased. The magnitudes of the respective changes depended on cooling rate. A peak value of 48.1% and rating 3.8 were obtained in semen protected with 4% glycerol, frozen at 30 degrees C/min. Increasing the glycerol levels above 6% resulted in a gradual decrease in motility. The proportion of spermatozoa with normal apical ridge was highest in semen protected with 0-1% glycerol after cooling at 30 degrees C/min (64.4% and 66.1%, respectively), but at these glycerol concentrations the percentage of motile spermatozoa was low. At the 30 degrees C/min cooling rate, the decline in the proportion of cells with normal apical ridge due to increasing the glycerol levels to 3 and 4% was relatively slow (57.3% and 49.4%, respectively). Cooling at 1 degrees C/min was detrimental to acrosomal integrity, which decreased with increasing glycerol concentration, in contrast to increasing motility, which even at its maximum, remained low. The direct plunging of straws into liquid nitrogen (1,500 degrees C/min) resulted in damaged acrosomes in all spermatozoa with the total loss of motility. Balancing motility and acrosomal integrity, freezing boar semen protected with 3% glycerol by cooling at 30 degrees C/min resulted in optimal survival for boar semen frozen in 0.5 ml French straws.     

Correlation between the In Vitro Functionality of Stored Platelets and the Cytosolic Esterase-Induced Fluorescence Intensity with CMFDA

It has been hypothesized that the cytosolic esterase-induced fluorescence intensity (CEIFI) from carboxy dimethyl fluorescein diacetate (CMFDA) in platelets may related to platelet functions. In the present study, we measured the change of CEIFI in platelets during storage, and examined the correlations of CEIFI with the in vitro functionality of stored platelets, including the ADP-induced aggregation activity, hypotonic shock response, expression of CD62P as well as platelet apoptosis. The CEIFI of fresh platelets, when tested at 10 μM CMFDA, the mean fluorescence intensity index (MFI) was 305.9 ± 49.9 (N = 80). After 1-day storage, it was 203.8 ± 34.4, the CEIFI of the stored platelets started to decline significantly, and reduced to 112.7 ±27.7 after 7-day storage. The change in CEIFI is highly correlated to all four functional parameters measured, with the correlation coefficients being 0.9813, 0.9848, -0.9945 and -0.9847 for the ADP-induced aggregation activity, hypotonic shock response (HSR), expression of CD62P and platelet apoptosis respectively. The above results show that the CEIFI measurement of platelets represents well the viability and functional state of in vitro stored platelets. This may be used as a convenient new method for quality evaluation for stored platelets if this result can be further validated by the following clinical trials.     

Localization of fibrinogen during ADP- or thrombin-induced aggregation of washed rabbit platelets

In contrast to human platelets, which aggregate poorly in response to ADP unless fibrinogen is present in the external medium, washed rabbit platelets form large aggregates in response to ADP without fibrinogen in the suspending medium. Addition of fibrinogen to the suspending medium of rabbit platelets frequently has little or no effect on the extent of ADP-induced platelet aggregation. We examined washed rabbit platelets by immunocytochemistry during ADP-induced aggregation and deaggregation and during thrombin-induced aggregation when the external medium did not contain added fibrinogen to determine if (a) fibrinogen was expressed on the surface of rabbit platelets that could support aggregation when the platelets were stimulated, or (b) fibrinogen secreted from the alpha granules supports platelet aggregation. Glutaraldehyde-fixed samples were prepared at different times after addition of ADP or thrombin, embedded in Lowicryl K4M, sectioned, incubated with sheep anti-rabbit fibrinogen, washed, reacted with gold-labeled anti-sheep IgG, and prepared for electron microscopy. The alpha granules of rabbit platelets were heavily labeled with immunogold; the platelet membrane was not labeled. During platelet aggregation and deaggregation in response to ADP, fibrinogen was not detectable on the platelet surface. In response to thrombin, large aggregates formed before fibrinogen was secreted from the alpha granules; fibrinogen was detectable focally at sites of granule discharge by 30-60 sec and fibrin formed by 3 min. Therefore, stimulated washed rabbit platelets can adhere to each other without large amounts of fibrinogen taking part in the close platelet-to-platelet contact, since aggregation occurs before detectable secretion, and large areas where the platelets are in contact are devoid of fibrinogen between the adherent membranes. Adhesion mechanisms not involving fibrinogen may support the aggregation of washed rabbit platelets.     

A study of the separate effects of influence factors and their coupled interactions on cryoinjury of human erythrocytes

The separate effects of five influence factors and their coupled interactions on cryoinjury of human erythrocytes were investigated experimentally and statistically. The five factors, each having three levels, were as follows: (1) cooling rate: -0.5, -140, and -800 degrees C/min; (2) warming rate: +0.5, +25, and +200 degrees C/min; (3) hematocrit: 2, 11, and 60%; (4) concentration of cryoprotectant (glycerol): 1, 2, and 4 M in PBS; and (5) holding temperature at which the frozen samples were kept: no hold, -75 degrees C for 1.5 hr, and -196 degrees C for 1.5 hr. Twenty-seven special tests, which were chosen from the 243 possible tests by using the Fractional Factorial Design Technique, an optimum seeking technique, were performed. The conclusions are: (1) the cooling rate is the most significant or sensitive factor causing cryoinjury to the cells; (2) the main effects of the hematocrit and the concentration of cryoprotectant, the interaction between the cooling rate and the warming rate, and the interaction between the cooling rate and the concentration of cryoprotectant are next most significant; (3) the main effect of warming rate, and the interaction between the holding temperature and the cooling rate are less significant; (4) the holding temperature below -75 degrees C, and the remaining interactions between two factors are relatively not significant; and (5) in the present study, the optimal combination of the five factors for the survival of the cells is: cooling at -0.5 degrees C/min, warming at +0.5 degrees C/min, hematocrit at 11%, glycerol concentration at 4 M in PBS, and holding temperature below -75 degrees C.     

Cryopreservation of umbilical cord blood: 2. Tolerance of CD34(+) cells to multimolar dimethyl sulphoxide and the effect of cooling rate on recovery after freezing and thawing

Cryopreservation protocols for umbilical cord blood have been based on methods established for bone marrow (BM) and peripheral blood stem cells (PBSC). The a priori assumption that these methods are optimal for progenitor cells from UCB has not been investigated systematically. Optimal cryopreservation protocols utilising penetrating cryoprotectants require that a number of major factors are controlled: osmotic damage during the addition and removal of the cryoprotectant; chemical toxicity of the cryoprotectant to the target cell and the interrelationship between cryoprotectant concentration and cooling rate. We have established addition and elution protocols that prevent osmotic damage and have used these to investigate the effect of multimolar concentrations of Me(2)SO on membrane integrity and functional recovery. We have investigated the effect of freezing and thawing over a range of cooling rates and cryoprotectant concentrations. CD34(+) cells tolerate up to 60 min exposure to 25% w/w (3.2M) Me(2)SO at +2 degrees C with no significant loss in clonogenic capacity. Exposure at +20 degrees C for a similar period of time induced significant damage. CD34(+) cells showed an optimal cooling range between 1 degrees C and 2.5 degrees C/min. At or above 1 degrees C/min, increasing the Me(2)SO concentration above 10% w/w provided little extra protection. At the lowest cooling rate tested (0.1 degrees C/min), increasing the Me(2)SO concentration had a statistically significant beneficial effect on functional recovery of progenitor cells. Our findings support the conclusion that optimal recovery of CD34(+) cells requires serial addition of Me(2)SO, slow cooling at rates between 1 degrees C and 2.5 degrees C/min and serial elution of the cryoprotectant after thawing. A concentration of 10% w/w Me(2)SO is optimal. At this concentration, equilibration temperature is unlikely to be of practical importance with regard to chemical toxicity.     

Variation of cooling rate and concentration of dimethyl sulfoxide on rabbit kidney function

Rabbit kidney function was assessed in vitro after cryoprotection with either 3 or 4 M dimethyl sulfoxide. The introduction and removal of the cryoprotectant was carried out in a stepwise progressive manner and the removal in a stepwise progressive manner with hypertonic mannitol solutions. This in vitro model can be shown to respond to various ischemic-like states resulting in poor or absent function. Active tubular transport can be demonstrated. It has been used by many authors as an intermediate step prior to the ultimate test of reimplant and contralateral nephrectomy. Variations in the rate of cooling at cryoprotection levels of 3 and 4 M dimethyl sulfoxide concentration (Me2SO) were carried out. In general, at 3 M concentration of Me2SO, creatinine clearance, sodium and glucose reabsorption are preserved with a fair degree of success after cooling to -10, -15, and -20 degrees C in our model, when the rate of cooling to these levels is 1.0 degree C/min. When a cooling rate of 0.5 degree C/min is used, renal function is significantly reduced whether the final temperature is -10, -15, or -20 degrees C. Control rabbit kidneys will tolerate 4 M concentration of Me2SO and give fairly good function. When cooled to -15 or -20 degrees C, there is poor function at 0.1 and 0.5 degrees C/min. Fair function is obtained at the rate of 1 degree C/min to -10 degrees C. Therefore, at cryoprotectant levels of 3 and 4 M Me2SO, kidney function as assayed by in vitro perfusion, is better when the cooling rate is 1.0 degree C/min.     

Action of KCN on intact and refractory thrombocytes]

The effect of low KCN concentrations (5-10(4) M) on the ADP-induced aggregation of intact and refractory rabbit platelets was studied. KCN did not change the aggregation of the intact platelets, but stimulated that of the refractory platelets. The effect of the inhibitor stimulating the aggregation was not connected with the release of additional amounts of ADP. A different sensitivity of the aggregation capacity of the intact and refractory cells to the partial inhibition of metabolism was discussed in terms of the suggested earlier "calcium" model of autoregulation of platelet aggregation.