Osmotic Separation of Pancreatic Exocrine Cells from Crude Islet Cell Preparations

A novel approach is introduced here to selectively lyse exocrine cells in an islet preparation by hypoosmotic treatment. Time to hypotonic cell lysis required for the islet cells was much longer than that for the exocrine cells, which permits a possibility of selectively killing the exocrine cells by hypotonic treatment. The first set of experiments was designed to select an appropriate osmolality for the hypotonic treatment. Kinetic changes in cell volume in response to extracellular anisosmolalities (30 to 90 mOsm/kg) were recorded using an electronic particle counter. The results indicated that, when exposed to a 30 mOsm/kg solution, islet cells swelled slowly to reach volumetric equilibrium in approximately 3 min. There was no significant hypotonic cell lysis observed even at the end of 4 min (n = 4). In contrast, pancreatic exocrine cells, when exposed to the same solution, expanded rapidly to the lytic volume and burst within 30 s. Significant exocrine cell lysis was invariably achieved within 30 s when cells were exposed to the osmolalities below 60 mOsm/kg. For osmolalities between 70 to 80 mOsm/kg, exocrine cell lysis was highly variable. When cells were exposed to 80 to 90 mOsm/kg, no significant cell lysis was observed. Thus, an osmolality of 50 mOsm/kg is recommended for hypotonic treatment, as it maximizes the lysis of exocrine cells without unnecessarily stressing (osmotically) the islet cells. The second set of experiments (time-course experiments, 20 to 120 s) was designed to determine the length of exposure time for which the exocrine cells were irreversibly damaged but the islet cells had only swollen to such a degree that cell function is restored upon returning to an isotonic condition. Viability of the hypotonic treated cells was evaluated at two different levels: membrane integrity, measured by combined fluorescent dye staining with propidium iodide (PI) and carboxyfluorescein diacetate (CFDA), and mitochondrial function, measured by colorimetric MTT assay. The results showed that hypotonic treatment in a 50 mOsm/kg solution for 30 s resulted in over 85% loss of the membrane integrity for the exocrine cells. About 90% of these membrane lysed cells lost mitochondrial function (n = 3). By contrast, under the same treatment, less than 15% of the islet cells lost membrane integrity and mitochondrial function (n = 3). In conclusion, hypotonic treatment with a 50 mOsm/kg solution for 20 to 30 s at room temperature is sufficient to lyse the majority of the contaminating exocrine cells in an islet cell preparation, while maintaining function in the islet cells.

MR spectroscopy measurement of the diffusion of dimethyl sulfoxide in articular cartilage and comparison to theoretical predictions

Cartilage cryopreservation requires optimal loading of protective solutes, most commonly dimethyl sulfoxide (DMSO), to maximize chondrocyte survival. Previously, diffusion models have been used to predict the distribution of solutes in tissue samples, but the accuracy of spatiotemporal predictions of these models have not been validated with empirical studies and remains unknown.

OBJECTIVE

In this study, magnetic resonance spectroscopic imaging was used to measure the spatial and temporal changes in DMSO and water concentrations in porcine articular cartilage plugs, throughout 1 h of solute loading.

DESIGN

A custom NMR spectroscopic imaging pulse sequence provided water and DMSO concentration images with an in-plane spatial resolution of 135 μm and a temporal resolution of 150 s, repeated for 60 min throughout DMSO loading. Delayed gadolinium-enhanced magnetic resonance of cartilage (d-GEMRIC) imaging provided fixed charge density and spin-density imaging provided water density images prior to DMSO loading.

RESULTS

The measured spatial and temporal distribution of DMSO in three different samples was compared to independent predictions of Fick's law and the modified triphasic biomechanical model by Abazari et al. (2011) with the empirical data more closely agreeing with the triphasic model.

CONCLUSION

Dynamic NMR spectroscopic imaging can measure spatial and temporal changes in water and cryoprotectant concentrations in articular cartilage. The modified triphasic model predictions for the interstitial distribution of DMSO were confirmed and its advantage over the predictions by Fick's law model, which is commonly used in the literature of cryobiology, was demonstrated.

A Multisolute Osmotic Virial Equation for Solutions of Interest in Biology

The osmotic virial equation was used to predict osmolalities of solutions of interest in biology. The second osmotic virial coefficients, Bi, account for the interactions between identical solute molecules. For multisolute solutions, the second osmotic virial cross coefficient, Bij, describes the interaction between two different solutes. We propose to use as a mixing rule for the cross coefficient the arithmetic average of the second osmotic virial coefficients of the pure species, so that only binary solution measurements are required for multisolute solution predictions. Single-solute data were fit to obtain the osmotic virial coefficients of the pure species. Using those coefficients with the proposed mixing rule, predictions were made of ternary solution osmolality, without any fitting parameters. This method is shown to make reasonably accurate predictions for three very different ternary aqueous solutions: (i) glycerol + dimethyl sulfoxide + water, (ii) hemoglobin + an ideal, dilute solute + water, and (iii) bovine serum albumin + ovalbumin + water.

Storage of Porcine Articular Cartilage at High Subzero Temperatures

OBJECTIVE

Transplantation of osteochondral allograft tissue can treat large joint defects but is limited by tissue availability, surgical timing, and infectious disease transmission. Fresh allografts perform the best but requirements for infectious disease testing delay the procedure with subsequent decrease in cell viability and function. Hypothermic storage at lower temperatures can extend tissue banking time without loss of cell viability and, therefore, increase the supply of allograft tissue. This study investigated the effects of different cryoprotectant solutions on intact AC at various subzero temperatures.

DESIGN

10 mm porcine osteochondral dowels were immersed for 30 minutes in various combinations of solutions [(XVIVO, propylene glycol (51% w/w), sucrose (46% w/w)] cooled to various subzero temperatures (-10, -15, and -20 degrees C), and held for 30 min. After warming, 70 mum slices were stained with membrane integrity dyes, viewed under fluorescence microscopy and cell recovery calculated relative to fresh controls.

RESULTS

Results demonstrated excellent cell recovery (>75%) at -10 degrees C provided ice did not form. Excellent cell recovery (>70%) occurred at -15 degrees C in solutions containing 51% propylene glycol but formation of extra-matrix ice in other solutions resulted in significant cell loss. All groups had <6% cell recovery at -20 degrees C and propylene glycol did not provide a protective effect even though extra-matrix ice did not form

CONCLUSIONS

These results suggest that extra-matrix ice plays an important role in cell damage during cryopreservation. Excellent cell recovery can be obtained after storage at subzero temperatures if ice does not form. Hypothermic preservation at high subzero temperatures may extend AC storage time in tissue banks compared to current techniques.

Effect of dimethyl sulfoxide on post-thaw viability assessment of CD45+ and CD34+ cells of umbilical cord blood and mobilized peripheral blood

BACKGROUND

The effect of dimethyl sulfoxide (Me2SO) on enumeration of post-thaw CD45+ and CD34+ cells of umbilical cord blood (HPC-C) and mobilized peripheral blood (HPC-A) has not been systematically studied.

METHODS

Cells from leukapheresis products from multiple myeloma patients and umbilical cord blood cells were suspended in 1, 2, 5, or 10% Me2SO for 20 min at 22 degrees C. Cells suspended in Me2SO were then immediately assessed or assessed following removal of Me2SO. In other samples, cells were suspended in 10% Me2SO, cooled slowly to -60 degrees C, stored at -150 degrees C for 48 h, then thawed. The thawed cells in 10% Me2SO were diluted to 1, 2, 5, or 10% Me2SO, held for 20 min at 22 degrees C and then immediately assessed or assessed after the removal of Me2SO. CD34+ cell viability was determined using a single platform flow cytometric absolute CD34+ cell count technique incorporating 7-AAD.

RESULTS

The results indicate that after cryopreservation neither recovery of CD34+ cells nor viability of CD45+ and CD34+ cells from both post-thaw HPC-A and HPC-C were a function of the concentration of Me2SO. Without cryopreservation, when Me2SO is present recovery and viability of HPC-C CD34+ cells exposed to 10% Me2SO but not CD45+ cells were significantly decreased. Removing Me2SO by centrifugation significantly decreased the viability and recovery of CD34+ cells in both HPC-A and HPC-C before and after cryopreservation.

DISCUSSION

To reflect the actual number of CD45+ cells and CD34+ cells infused into a patient, these results indicate that removal of Me2SO for assessment of CD34+ cell viability should only be performed if the HPC are infused after washing to remove Me2SO.

Association of post-thaw viable CD34+ cells and CFU-GM with time to hematopoietic engraftment

In all, 78 peripheral hematopoietic progenitor cell collections from 52 patients were evaluated using our previously published validated post-thaw assays at the time of collection and following transplantation by assessment of viable CD34(+) cells, and granulocyte-macrophage colony-forming units (CFU-GM) cryopreserved in quality control vials. The median (range) post-thaw recovery of viable CD34(+) cells and CFU-GM was 66.4% (36.1-93.6%) and 63.0% (28.6-85.7%), respectively, which did not show significant correlation with the engraftment of either neutrophils (P=0.136 and 0.417, respectively) or platelets (P=0.88 and 0.126, respectively). However, the reinfused viable CD34(+) cells/kg of patient weight pre- or post-cryopreservation showed significant correlation to engraftment of neutrophils (P=0.0001 and 0.001, respectively) and platelets (P=0.023 and 0.010, respectively), whereas CFU-GM pre- or post-cryopreservation was significantly correlated to neutrophils (P=0.011 and 0.007, respectively) but not to platelets (P=0.112 and 0.100, respectively). The results show that post-cryopreservation assessment of viable CD34(+) cells or CFU-GM is as reliable a predictor of rapid engraftment as that of pre-cryopreservation measures. Therefore, the post-cryopreservation number of viable CD34(+) cells or CFU-GM should be used to eliminate the risks of unforeseen cell loss that could occur during cryopreservation or long-term storage.

Cryoprotectant equilibration in tissues

The first step in the cryopreservation of cells or tissues is often the movement of a permeating cryoprotectant into the cells or tissues from the solution into which they have been placed. The cryoprotectant enters the cells or tissues by thermodynamic equilibration with the surroundings. In the reverse case, thermodynamic equilibration also drives the removal of permeating cryoprotectants by a dilution solution at the end of the preservation process when the cells or tissues are being readied for use. There have been reports of tissues having equilibrium cryoprotectant concentrations lower than that of the surrounding carrier solution. For various tissues, the equilibrium concentration of cryoprotectant inside the tissue is either equal to, or lower than the cryoprotectant concentration of the surrounding solution. A simple thermodynamic treatment of the solution-tissue equilibrium shows that an equilibrium concentration difference can exist between a tissue and the surrounding solution if a pressure difference can be maintained.

The effect of cell size distribution on predicted osmotic responses of cells

An understanding of the kinetics of the osmotic response of cells is important in understanding permeability properties of cell membranes and predicting cell responses during exposure to anisotonic conditions. Traditionally, a mathematical model of cell osmotic response is obtained by applying mass transport and Boyle-vant Hoff equations using numerical methods. In the usual application of these equations, it is assumed that all cells are the same size equal to the mean or mode of the population. However, biological cells (even if they had identical membranes and hence identical permeability characteristics--which they do not) have a distribution in cell size and will therefore shrink or swell at different rates when exposed to anisotonic conditions. A population of cells may therefore exhibit a different average osmotic response than that of a single cell. In this study, a mathematical model using mass transport and Boyle-van't Hoff equations was applied to measured size distributions of cells. Chinese hamster fibroblast cells (V-79W) and Madin-Darby canine kidney cells (MDCK), were placed in hypertonic solutions and the kinetics of cell shrinkage were monitored. Consistent with the theoretical predictions, the size distributions of these cells were found to change over time, therefore the selection of the measure of central tendency for the population may affect the calculated osmotic parameters. After examining three different average volumes (mean, median, and mode) using four different theoretical cell size distributions, it was determined that, for the assumptions used in this study, the mean or median were the best measures of central tendency to describe osmotic volume changes in cell suspensions.

Cryoprotectant permeability parameters for cells used in a bioengineered human corneal equivalent and applications for cryopreservation

A human corneal equivalent is being developed with applications in pharmaceutical testing and biomedical research, but the distribution of this engineered tissue, depends on successful cryopreservation. Cryopreservation of tissues depends on the presence of cryoprotectants, their addition and removal, and exposure to conditions during freezing and thawing, all of which depend on cellular membrane permeabilities to water and cryoprotectant. This study defines the permeability properties that define the rate of water and cryoprotectant movement across the plasma membrane of isolated human corneal endothelial, keratocyte, and epithelial cells. Cells were transferred from isotonic conditions (300 mosm/kg) to 0.5, 1, or 2 M dimethyl sulfoxide and propylene glycol solutions at constant temperature, and cell volumes monitored using an electronic particle counter. Histograms describing cell volume changes over time after cryoprotectant exposure allowed calculation of hydraulic conductivity (Lp), cryoprotectant permeability (Ps), and the reflection coefficient (sigma). Experimental values for Lp and Ps at 4, 13, 22, and 37 degrees C were used to determine the Arrhenius activation energy (Ea). Defining the permeability parameters and temperature dependencies allows simulation of responses of human corneal cells to addition and removal of cryoprotectants and to freezing conditions, allowing amount of supercooling, intracellular electrolyte concentration, and intracellular cryoprotectant concentration to be calculated. Simulations also show that the constituent cells in the bioengineered cornea respond differently to addition and removal of cryoprotectants and to freezing. This study has defined the requirements during cryopreservation for the corneal cells; future work will define the matrix requirements which will allow the development of a cryopreservation protocol.

Intramatrix events during cryopreservation of porcine articular cartilage using rapid cooling

Cryopreservation of articular cartilage may improve long-term transplantation results if cell and matrix integrity can be maintained. This study examined intramatrix events in intact porcine articular cartilage that occurred during a rapid-cooling technique with various concentrations of dimethyl sulfoxide (DMSO) (1, 3, 5, 6 and 7 M). Thermocouples were inserted into the solution and in the cartilage matrix to record the temperature during rapid cooling. In addition, scanning electron microscopy of freeze-substituted samples was performed and quantitatively evaluated for the areas representing ice in the matrix. The results of this study showed that low concentrations of DMSO resulted in the largest temperature gradient between the matrix and the surrounding solution, which occurred near the freezing point of the cryoprotectant solution. At higher concentrations of DMSO, the peak temperature gradient occurred near the glass transition temperature. The temperature measurements suggested that a significant amount of ice formed within the matrix at lower DMSO concentrations. At higher DMSO concentrations that resulted in vitrification of the external solution, there was evidence of some ice in the matrix. The scanning electron micrographs demonstrated significantly more matrix disruption (likely due to ice formation) (P<0.02) in the lower DMSO concentrations (1 and 5 M) while the 6 M DMSO concentration demonstrated minimal matrix disruption. Cryopreservation of articular cartilage with a rapid-cooling technique and high concentrations of DMSO resulted in partial vitrification of the matrix and significantly less matrix disruption. It appears that successful cryopreservation of viability and function in articular cartilage will require high concentrations of cryoprotectants and rapid cooling.

Effects of incubation temperature and time after thawing on viability assessment of peripheral hematopoietic progenitor cells cryopreserved for transplantation

Three widely used viability assessments were compared: (1) membrane integrity of nucleated cells using trypan blue (TB) exclusion and a fluorometric membrane integrity assay (SYTO 13 and propidium iodide), (2) enumeration of viable CD34+ cells, and (3) clonogenic assay (granulocyte-macrophage colony-forming units, CFU-GM). Post thaw peripheral hematopoietic progenitor cells (HPC) were incubated at 0, 22, and 37 degrees C for 20-min intervals before assessment. The recovery of viable nucleated cells assessed by TB and SYTO/PI decreased significantly with time at incubation temperatures of 22 and 37 degrees C (P<0.05), and correlated with the concentration of mononuclear cells (MNC) (r=0.936, P<0.05). The decrease in recovery of viable nucleated cells was slower when thawed cells were incubated at 0 degrees C compared with 22 degrees C or 37 degrees C. The recovery, measured by absolute viable CD34+ or CFU-GM, was not affected by 2 h post thaw incubation (P>0.05) at 0, 22, and 37 degrees C (P>0.05). There were no significant differences in the measured recovery of viable CD34+ cells and CFU-GM at all incubation times (P>0.05) and temperatures (P>0.05). Both CFU-GM and absolute CD34+ cells can be used as post thaw viability assays for HPC cryopreserved for transplantation.

Validation and reproducibility of computerised cell-viability analysis of tissue slices

BACKGROUND

The identification of live cells using membrane integrity dyes has become a frequently used technique, especially with articular cartilage and chondrocytes in situ where tissue slices are used to assess cell recovery as a function of location. The development of a reproducible computerised method of cell evaluation would eliminate many variables associated with manual counting and significantly reduce the amount of time required to evaluate experimental results.

METHODS

To validate a custom computerised counting program, intra-person and inter-person cell counts of nine human evaluators (three groups - unskilled, novice, and experienced) were compared with repeated pixel counts of the custom program on 15 digitised images (in triplicate) of chondrocytes in situ stained with fluorescent dyes.

RESULTS

Results indicated increased reproducibility with increased experience within evaluators [Intraclass Correlation Coefficient (ICC) range = 0.67 (unskilled) to 0.99 (experienced)] and between evaluators [ICC = 0.47 (unskilled), 0.85 (novice), 0.93 (experienced)]. The computer program had perfect reproducibility (ICC = 1.0). There was a significant relationship between the average of the experienced evaluators results and the custom program results (ICC = 0.77).

CONCLUSIONS

This study demonstrated that increased experience in cell counting resulted in increased reproducibility both within and between human evaluators but confirmed that the computer program was the most reproducible. There was a good correlation between the intact cell recovery determined by the computer program and the experienced human evaluators. The results of this study showed that the computer counting program was a reproducible tool to evaluate intact cell recovery after use of membrane integrity dyes on chondrocytes in situ. This and the significant decrease in the time used to count the cells by the computer program advocate its use in future studies because it has significant advantages.

Damage and protection of UC blood cells during cryopreservation

BACKGROUND

Current procedures for the cryopreservation of umbilical cord blood (UCB) progenitor cells, which are based on techniques used for BM, have had varying degrees of success (survival 9-118%). Improving the effectiveness of UCB cell therapies demands a more comprehensive understanding of freezing injury during cryopreservation.

METHODS

Leukocyte concentrates from UCB, with or without 10% DMSO were cooled at 1 degrees C/min to different subzero temperatures (-5 to -50 degrees C), then either thawed directly (thaw) or plunged into liquid nitrogen before thawing (plunge). Single-platform flow cytometry with 7-amino-actinomycin D was used to directly quantify survival of CD34(+) cells. Fluorescent microscopy was used to examine plasma membrane integrity of nucleated cells.

RESULTS

Without DMSO, recovery of nucleated cells was approximately 80% for both thaw and plunge. Survival was 9%, indicating damage to the plasma membrane. With 10% DMSO, nucleated cell recovery was also approximately 80%, indicating that DMSO does not improve recovery of nucleated cells. Survival, however, was much higher with DMSO, > 60% for nucleated cells thawed directly, and 30-55% for cells thawed from plunge, demonstrating cryoprotection conferred by DMSO. With DMSO, survival of CD34(+) cells was higher than that of nucleated cells, indicating that CD34(+) cells with 10% DMSO are more tolerant to cryopreservation than the total nucleated cell population.

DISCUSSION

This study provides the necessary data on the low temperature response of UCB progenitor cells that are critical for the development of standards for the cryopreservation of UCB.

Cryopreservation of intact human articular cartilage

Damaged articular cartilage (AC) impairs joint function and many treatment techniques are being investigated to determine their long term results. Successful cryopreservation of AC can provide a reliable source of intact matrix with viable chondrocytes to maintain the cartilage over long periods of time. This study investigated the application of an established cryopreservation protocol to determine the recovery of intact chondrocytes from human AC. Ten millimeter diameter osteochondral dowels were harvested from two human donors. The cryopreservation protocol was performed and the samples were rapidly warmed from varying experimental holding temperatures (-10, -20, -30, -40 degrees C), with and without plunging into liquid nitrogen, using 1 M dimethyl sulfoxide as cryoprotectant. The cartilage was stained with membrane integrity dyes and viewed under fluorescence microscopy. The percent of intact chondrocytes was compared to fresh controls. Low recovery of intact chondrocytes was recorded from all temperature levels with and without cryoprotectant. The results of this experiment demonstrated that the cryopreservation procedure used to achieve moderate success with intact sheep AC was not successful with intact human AC and further investigation is required.

Osmotic parameters of cells from a bioengineered human corneal equivalent and consequences for cryopreservation

A human corneal equivalent is under development with potential applications in pharmaceutical testing, biomedical research, and transplantation, but the ability to distribute this engineered tissue, depends on successful cryopreservation. Tissue recovery after exposure to conditions during cryopreservation depends on the response of its constituent cells to the changing environment as ice forms and solutes concentrate. This study defines the osmotic properties that define the rate of water movement across the plasma membrane of isolated human corneal endothelial, stroma, and epithelial cells. Cells were transferred from an isotonic (300 mosm/kg) to an anisotonic (150-1500 mosm/kg) solution at constant temperature, and cell volumes monitored using an electronic particle counter. Histograms describing cell volume changes over time after anisosmotic exposure allowed calculation of hydraulic conductivity (L(p)) and osmotically inactive volume fraction (V(b)). Experimental values for L(p) at 4, 13, 22, and 37 degrees C were used to determine the Arrhenius activation energy (E(a)). The L(p) for endothelial, stroma, and epithelial cells at 37 degrees C was 1.98+/-0.32,1.50+/-0.30, and 1.19+/-0.14 microm/min/atm, and the V(b) was 0.28, 0.27, and 0.41, respectively. The E(a) for endothelial, stroma, and epithelial cells was 14.8, 12.0, and 14.1 kcal/mol, respectively, suggesting the absence of aqueous pores. These osmotic parameters and temperature dependencies allow simulation of osmotic responses of human corneal cells to cryopreservation conditions, allowing amount of supercooling to be calculated to indicate the likelihood of intracellular freezing. Simulations show that differences in the osmotic parameters for the constituent cells in the bioengineered cornea result in significant implications for cryopreservation of the engineered corneal equivalent.

The effect of temperature on membrane hydraulic conductivity

The objective of this study was to use the temperature dependence of water permeability to suggest the physical mechanisms of water transport across membranes of osmotically slowly responding cells and to demonstrate that insight into water transport mechanisms in these cells may be gained from easily performed experiments using an electronic particle counter. Osmotic responses of V-79W Chinese hamster fibroblast cells were measured in hypertonic solutions at various temperatures and the membrane hydraulic conductivity was determined. The results were fit with the general Arrhenius equation with two free parameters, and also fit with two specific membrane models each having only one free parameter. Data from the literature including that for human bone marrow stem cells, hamster pancreatic islets, and bovine articular cartilage chondrocytes were also examined. The results indicated that the membrane models could be used in conjunction with measured permeability data at different temperatures to investigate the method of water movement across various cell membranes. This approach for slower responding cells challenges the current concept that the presence of aqueous pores is always accompanied by an osmotic water permeability value, P(f)>0.01 cm/s. The possibility of water transport through aqueous pores in lower-permeability cells is proposed.

Chondrocyte recovery in cryopreserved porcine articular cartilage after bone carrier alteration

In order to investigate the consequences on the distribution of cell recovery through a cross-section of articular cartilage, the pathway for ice nucleation and diffusion of water and solutes in porcine osteochondral tissue was altered by drilling a 2mm diameter hole through the subchondral bone to the base of the cartilage. Samples equilibrated with 1M dimethyl sulfoxide were cooled at 1 C/min to -30 degrees C then stored in liquid nitrogen. A significant increase in chondrocyte recovery was documented when compared to samples cryopreserved without holes (48.3 percent vs 28.6 percent, P=0.003). The most significant change due to bone base modification was an increase in recovery in the middle section of the cartilage. These results provide insight into mechanisms of cryoinjury in tissue systems.

Osmotic and cryoprotectant permeation characteristics of islet cells isolated from the newborn pig pancreas

The development of effective protocols for the low-temperature banking of pancreatic islets is an important step in islet transplantation for the treatment of type I diabetes mellitus. We have been exploring the use of islets from the newborn pig as an alternative source of tissue for transplantation. Current cryopreservation protocols are empirically derived, but may be optimized by modeling osmotic responses during the cryopreservation process. This study determined the osmotic and cryoprotectant permeability parameters of cells isolated from the pancreas of newborn pigs. Key parameters are: the osmotically inactive fraction of cell volume, hydraulic conductivity, the permeability coefficients of dimethyl sulfoxide (DMSO) and ethylene glycol (EG) at varying temperatures, and the activation energies of these transport processes. Newborn pig islets were dispersed into single cells and kinetic and equilibrium cell volumes were recorded during osmotic excursions using an electronic particle counter interfaced to a computer. Data were fitted to theoretical descriptions of the osmotic responses of cells, based on the Kedem-Katchalsky approach. The hydraulic conductivity (Lp) in the absence of cryoprotectant was calculated as 0.050 +/- 0.005, 0.071 +/- 0.006, and 0.300 +/- 0.016 microm/min/atm at 4 degrees C, 10 degrees C, and 22 degrees C, respectively (mean +/- SEM, n = 7, 6, or 9). These values give an activation energy value of 16.69 kcal/mol when put into an Arrhenius plot. The solute permeability (Ps) values for 1 M DMSO were 0.89 +/- 0.12, 1.86 +/- 0.28, and 5.33 +/- 0.26 microm/min at 4 degrees C, 10 degrees C, and 22 degrees C, respectively (n = 11, 8, or 10) giving an activation energy of 15.98 kcal/mol. The Lp values for cells exposed to 1 M DMSO were 0.071 +/- 0.006, 0.084 +/- 0.008, and 0.185 +/- 0.014 microm/min/atm at 4 degrees C, 10 degrees C, and 22 degrees C, respectively. The activation energy for these values was 8.95 kcal/mol. The Ps values for 2 M DMSO were 1.11 +/- 0.13, 1.74 +/- 0.19, and 7.68 +/- 0.12 microm/min for the same temperatures, with a calculated activation energy of 17.89 kcal/mol. The Lp values in the presence of 2 M DMSO were 0.070 +/- 0.006, 0.085 +/- 0.008, and 0.192 +/- 0.009 microm/min/atm at 4 degrees C, 10 degrees C, and 22 degrees C, respectively, with an activation energy of 9.40 kcal/mol. Solutions of 1 M EG gave Ps values of 1.01 +/- 0.13, 1.45 +/- 0.25, and 4.90 +/- 0.48 microm/min at the three test temperatures. The resulting activation energy was 14.60 kcal/mol. The corresponding Lp values were 0.071 +/- 0.007, 0.068 +/- 0.006, and 0.219 +/- 0.012 microm/min/atm with an activation energy of 10.96 kcal/mol. The solute permeabilities in the presence of 2 M EG for newborn pig islet cells were 1.03 +/- 0.15, 1.42 +/- 0.23, and 5.56 +/- 0.22 microm/min; the activation energy was 15.70. The Lp values for cells in the presence of 2 M EG were 0.068 +/- 0.008, 0.071 +/- 0.006, and 0.225 +/- 0.010 microm/min/atm; the activation energy for these values was 11.49 kcal/mol. These key cryobiological parameters permit the mathematical modeling of osmotic responses of intact islets during the cryopreservation process, which may lead to further improvements in the low temperature storage of islets from newborn pigs.

Transplantation of articular cartilage following a step-cooling cryopreservation protocol

Using a step-cooling cryopreservation protocol that held the tissue 60 min at -4 degrees C, 30 min at -8 degrees C, and 10 min at -40 degrees C before plunging into liquid nitrogen, we were able to get a substantial improvement in the magnitude and pattern of chondrocyte recovery following cryopreservation, achieving postthaw recoveries of 62 +/- 13%. These results are consistent with the hypothesis that ice growth within articular cartilage is planar, but they provide no direct support for that hypothesis. Transplanting (step-cooled) cryopreserved osteochondral allografts into adult Suffolk/Romanoff crossbred sheep for periods of 3 months and 1 year further tested the efficacy of the cryopreservation protocol. Unfortunately, the cryoinjury sustained by the chondrocytes during cryopreservation, although apparently nonlethal immediately after thawing in many cases, was not innocuous in the long term. The presence of large clusters of chondrocytes at 1 year after transplantation illustrates that cryoinjury not detectable with a membrane integrity assay can still have far-reaching effects on transplanted tissue.

Intercellular ice propagation: experimental evidence for ice growth through membrane pores

Propagation of intracellular ice between cells significantly increases the prevalence of intracellular ice in confluent monolayers and tissues. It has been proposed that gap junctions facilitate ice propagation between cells. This study develops an equation for capillary freezing-point depression to determine the effect of temperature on the equilibrium radius of an ice crystal sufficiently small to grow through gap junctions. Convection cryomicroscopy and video image analysis were used to examine the incidence and pattern of intracellular ice formation (IIF) in the confluent monolayers of cell lines that do (MDCK) and do not (V-79W) form gap junctions. The effect of gap junctions on intracellular ice propagation was strongly temperature-dependent. For cells with gap junctions, IIF occurred in a directed wave-like pattern in 100% of the cells below -3 degrees C. At temperatures above -3 degrees C, there was a marked drop in the incidence of IIF, with isolated individual cells initially freezing randomly throughout the sample. This random pattern of IIF was also observed in the V-79W monolayers and in MDCK monolayers treated to prevent gap junction formation. The significant change in the low temperature behavior of confluent MDCK monolayers at -3 degrees C is likely the result of the inhibition of gap junction-facilitated ice propagation, and supports the theory that gap junctions facilitate ice nucleation between cells.

Evidence of chondrocyte repopulation in adult ovine articular cartilage following cryoinjury and long-term transplantation

OBJECTIVE

To characterize the response of articular chondrocytes to a specific cryoinjury that leads to cluster formation following long-term transplantation.

DESIGN

Osteochondral dowels from 20 adult sheep were cryopreserved to optimize the recovery of chondrocytes immediately after thawing. The dowels were transplanted as allografts and observed at 3 and 12 months. Chondrocyte distribution and viability was assessed using paravital dyes after transplantation. Chondrocyte phenotype was assessed by in situ hybridization and immunohistochemistry to detect type II collagen. An anticentrosome antibody was used to identify cells undergoing cell cycle progression towards mitosis.

RESULTS

All cryopreserved grafts showed the presence of spheroidal clusters of chondrocytes 1 year after transplantation while the host cartilage adjacent to the graft appeared morphologically normal. The average size of the clusters increased from four cells at 3 months to 12 cells at 1 year. The chondrocytes in the clusters displayed newly formed type II collagen protein and mRNA. Some cells within clusters were observed with two centrosomes, indicative of cells progressing through the S phase of the cell cycle.

CONCLUSION

Adult articular chondrocytes retain the ability to repopulate the matrix, an ability which is demonstrated with this specific cryoinjury. This may be an initial stage of cartilage regeneration.

Membrane damage occurs during the formation of intracellular ice

Current theories on both the formation of intracellular ice (IIF) and the mechanisms by which it damages cells all implicate the plasma membrane. While it has been well documented that following IIF post-thaw damage to the plasma membrane occurs, it is not known whether this damage occurs during freezing or thawing. By directly monitoring the diffusion of a membrane-impermeable fluorescent stain into V-79W fibroblasts, the integrity of the plasma membrane during freezing and thawing was correlated with the incidence of IIF. While this study presents evidence that membrane damage occurs during the formation of intracellular ice in cell suspensions, single attached cells and confluent monolayers, we cannot conclude whether IIF is the cause or result of membrane damage.

High-efficiency volume reduction of cord blood using pentastarch

Human umbilical cord blood (UCB) has been used successfully to treat a variety of genetic, hematological, and oncologic disorders. However, the low number of hematopoietic progenitor cells available in donated cord blood samples limits transplantation of cord blood to children and small adults. Reduction of the volume of umbilical cord blood is widely used in cord blood banking to reduce the storage requirements in large-scale UCB banks. Unfortunately, during the volume reduction process, up to 40% or more of the progenitor cells are lost using current reduction methods. This study describes a highly reproducible, double collection technique using Pentaspan to reduce UCB volume by red cell depletion. This results in the preservation of critical hematopoietic progenitor cells. The final volume of the leukocyte concentrates (LC) was 19.8 +/- 0.4 ml with 95% red cell depletion. The recovery of nucleated cells (NC), mononuclear cells (MNC), CD34(+) cells and colony-forming units (CFU) following double collection was 89%, 94%, 96%, and 106%, respectively. This is significantly higher than the recovery from single collections, where recovery was 74%, 77%, 84%, and 91% for NC, MNC, CD34(+) and CFU, respectively. The double collection technique provides an efficient and highly reproducible method for the preparation of UCB for long-term storage and transplantation.

Articular cartilage joint surface reconstruction techniques

There is renewed interest in joint surface reconstruction using a variety of new and evolving techniques for articular cartilage resurfacing. Neochondrogenesis and articular cartilage transplantation are gaining a prominent place in orthopaedic basic science research. The authors have published a reliable, repeatable, stable, and sensitive model utilizing osteochondral dowel core transplantation in an ovine model to assess various treatment and follow-up evaluation techniques for articular cartilage transplantation. As well, our laboratory has developed a handheld articular cartilage indentor for clinical assessment of biomechanical performance of joint surfaces. This article presents and reviews that model as well as a semiquantitative visual analog scale for documenting articular cartilage gross morphology. The results of magnetic resonance imaging of the osteochondral dowel transplants and the gross morphology grading are compared to the histological and histochemical grading and biochemical and biomechanical assessments to form the foundation for future work in this critical and important study area for clinical application.

Routine assessment of viability in split-thickness skin

Effective quality control of allograft skin that is cryopreserved for transplantation requires a simple, reproducible technique for the assessment of cell viability. Tetrazolium reduction assays and an oxygen consumption technique have been the two methods of choice to determine the metabolic function of allograft skin after it has been thawed. In this study, we investigated the use of a novel tetrazolium salt, WST-1 (4-[3-(4-iodophenyl)-2-(4-nitrophenyl)-2H-5-tetrazolio]-1,3-benzen e disulfonate), that is cleaved to a water-soluble formazan product. Porcine split-thickness skin in minimal essential medium without cryoprotectant was subjected to a graded freezing protocol to generate progressive amounts of cryoinjury. Recovery as determined with WST-1 was compared with measurements made with the use of the oxygen consumption technique. The similarity of the resulting recovery curves indicates that WST-1 is a simple, effective, and convenient technique for the assessment of metabolic function in porcine split-thickness skin. The WST-1 assay is applicable for the routine assessment of tissue viability in cryopreserved allograft skin.

Cryobiology of articular cartilage: ice morphology and recovery of chondrocytes

The cryopreservation of articular cartilage chondrocytes has been achieved with cells isolated from the cartilage matrix but has found only limited success when the tissue is left intact. Previous work with ovine cartilage has shown that cryopreservation of the chondrocytes of the superficial and deep zones is possible, but the cells of the intermediate zone have not been successfully cryopreserved. This finding led to the suggestion that there might be biological differences between chondrocytes of the different morphological zones that were responsible for this differential recovery. This study investigates the hypothesis that the cells of the intermediate zone are more sensitive to cryoinjury by introducing cuts in the cartilage so that cells of the intermediate zone have the same proximity to the outer surface of the tissue as the cells of the superficial zone. When this was done, it was found that cells of the intermediate zone could survive cryopreservation as well as the cells of the superficial zone when they were near a surface, but not when they were embedded deep within the tissue. Thus the hypothesis of a biological difference between the cells of the two zones being responsible for the differential recovery is disproved. It is further hypothesized that physical proximity to a surface leads to higher recovery as a result of planar ice growth into the cartilage.

Cell-cell contact affects membrane integrity after intracellular freezing

The response of cells to freezing depends critically on the presence of an intact cell membrane. During rapid cooling, the cell plasma membrane may no longer be an effective barrier to ice propagation and can be breached by extracellular ice resulting in the nucleation of the supercooled cytoplasm. In tissues, the formation of intracellular ice is compounded by the presence of cell-cell and cell-surface interactions. Three different hamster fibroblast model systems were used to simulate structures found in organized tissues. Samples were supercooled to an experimental temperature on a cryostage and ice nucleated at the constant temperature. A dual fluorescent staining technique was used for the quantitative assessment of the integrity of the cell plasma membrane. A novel technique using the fluorescent stain SYTO was used for the detection of intracellular ice formation (IIF) in cell monolayers. The cumulative incidence of cells with a loss of membrane integrity and the cumulative incidence of IIF were determined as a function of temperature. Cells in suspension and individual attached cells showed no significant difference in the number of cells that formed intracellular ice and those that lost membrane integrity. For cells in a monolayer, with cell-cell contact, intracellular ice formation did not result in the immediate disruption of the plasma membrane in the majority of cells. This introduces the potential for minimizing damage due to IIF and for developing strategies for the cryoprotection of tissues during rapid cooling.

Transplantation of cryopreserved osteochondral Dowel allografts for repair of focal articular defects in an ovine model

The purpose of this study was to test whether successful cryopreservation of osteochondral tissue is possible and whether, with the appropriate surgical procedure, it can be used for the successful repair of focal articular defects within joints. Fresh (nonfrozen) and snap-frozen (plunged in liquid nitrogen and thawed in a water bath at 37 degrees C, repeated three times) autografts were used as positive and negative controls, respectively. Snap-frozen, frozen (fresh tissue placed in a freezer at -80 degrees C), and cryopreserved (immersed in 10% dimethyl sulfoxide for 30 minutes and then frozen at 1 degrees C/min to -80 degrees C) allografts were transplanted into the knees of adult sheep. Outcomes were evaluated 3, 6, and 12 months after transplantation. The morphological, histological, biochemical, and biomechanical behaviors and characteristics of the graft cartilage, the host cartilage adjacent to the grafts, and the opposing tibial cartilage were assessed. Freezing protocols that yielded poor chondrocyte recovery after thawing (frozen and snap-frozen) resulted in poor overall graft outcome. The cryopreservation protocol, however, resulted in intermediate recovery (50%) of chondrocytes and in intermediate overall graft outcome compared with fresh autografts. The membrane integrity of the allograft chondrocytes immediately following cryopreservation was identified as the most reliable predictor of long-term outcome of the graft. Further improvements in cryopreservation technique may lead to an effective method of banking osteochondral tissue for successful transplantation for the repair of focal defects and larger joint reconstructions.

Intracellular ice formation is affected by cell interactions

Cell-to-cell and cell-to-surface interactions are important to the structure and function of tissues. These interactions are also important determinants of low-temperature responses in tissues. Four in vitro models using hamster fibroblast cells in tissue culture were used to investigate the influence of cell-cell and cell-surface interactions on intracellular ice formation in these systems. The four models were: (a) single cells in suspension; (b) cells individually attached to glass with only cell-to-surface adhesion; (c) colonies of cells attached to glass with both cell-cell and cell-surface interactions; and (d) multicellular spheroids with extensive cell-cell contacts. Cryomicroscopy was used to monitor the prevalence and kinetics of intracellular ice formation after ice nucleation in the extracellular solution. The temperature for intracellular freezing in 50% of the cells was significantly affected by both cell-cell and cell-surface interactions. There was also evidence of intercellular nucleation through cell-cell interactions. The results indicate that cell-cell and cell-surface interactions play a significant role in the low-temperature response of tissue systems.

[Experimental condition for WST-1 assay of skin viability]

OBJECTIVE

To investigate a new tetrazoliium salt assay (WST-1) of detecting tissue and cells of preserved skin.

METHODS

With WST-1, viability of porcine and human skin split were assessed. The experimental condition such as dosage of agents, thickness of skin split, time of reaction, area of skin split and weight of skin split were determined.

RESULTS

Optimal experimental condition of skin split should be 10 mm diameter and 0.3 mm thick, incubation for 3 hours at 37 degrees C, and reagent dosage of 20 microl.

CONCLUSIONS

As a reagent for detecting cell viability, WST-1 is successfully applied to the assessment of skin viability.

[Effect of various methods of tissue storage on split-skin viability at 4 degrees C]

OBJECTIVE

To study various tissues and organs storage solutions (liver, kidney and corneal) at 4 degrees C for the storage of skin and the viability of skins stored in these solutions at correspondent condition.

METHOD

Five experiment groups investigated for storing porcine split-skin at 4 degrees C were MEM, UW, MEM plus CS, UW-R and MEM-R. A new assay, WST-1, was applied to evaluate skin viability at 1, 3, 5, 7, 10 and 14 day during storage respectively.

RESULT

Skin viability can all be protected by these three solutions. The effect of UW solution was superior to MEM. UW-R and MEM-R were superior to MEM and UW.

CONCLUSION

The method of UW-R which replaces medium routinely may be an optimal method of storing skin at 4 degrees C.

Antral follicles develop in xenografted cryopreserved African elephant (Loxodonta africana) ovarian tissue

The preservation of germ plasm from endangered species could augment captive breeding programs aimed at maintaining genetic diversity. Mammalian female germ plasm (oocytes) is extremely difficult to collect and cryopreserve; however, a promising alternative is the cryopreservation of ovarian tissue. In the present study, athymic nude (nu/nu) Balb/C mice were used to evaluate in vivo viability of cryopreserved ovarian tissue from Institute of Cancer Research genotype (ICR) mice or elephants. Female mice were ovariectomized prior to transplant of cryopreserved-thawed ovarian tissue from ICR mice (n=4) or elephants (n=6). Control mice were sham operated (n=4) or ovariectomized (n=5). Transplants were in the ovarian bursa, enabling in vivo ovulation and pregnancies from allografts. Vaginal cytology was monitored daily, and the intervals between and duration of epithelial cells present in smears were evaluated. Appearance of epithelial cells in sham-operated and allografted mice were at intervals of 4.3+/-0.6 and 3.3+/-0.5 days, lasting for 1.4+/-0.1 and 1.6+/-0.2 days, respectively. Sporadic incidence of epithelial cells in ovariectomized animals occurred at longer intervals (8.6+/-3.8 days). Females with xenografted elephant ovarian tissue demonstrated epithelial cells in vaginal smears at intervals of 4.5+/-1.0 days, for 2.5+/-0.5 days duration, which was significantly longer than the other groups (P < 0.05). Histological evaluation of tissues at the time of epithelial cells in smears demonstrated well-developed antral follicles, although oocytes were of poor morphological appearance or only cumulus-like complexes were seen. The nude mouse model is effective for assessing cryopreserved ovarian tissue xenograft function which can support the development of antral follicles.

Fundamental cryobiology of selected African mammalian spermatozoa and its role in biodiversity preservation through the development of genome resource banking

Fundamental cryobiological characteristics of spermatozoa from threatened or endangered species must be determined for successful cryopreservation techniques to be established. In this study, spermatozoa from four diverse species, impala (Aepyceros melampus), wart hog (Phacochoerus aethiopicus), elephant (Loxodonta africana), and lion (Panthera leo), were collected by electroejaculation or epididymal aspiration. Spermatozoal plasma membrane permeability to water (hydraulic conductivity, Lp) and the osmotically inactive fraction of the sperm cell (Vb) were determined from each species. Changes in cell volume were measured over time using an electronic particle counter. A Kedem-Katchalsky membrane transport model was used to theoretically characterize the data to determine Lp and Vb for each species. In addition to determining plasma membrane characteristics, spermatozoa were also studied to determine their sensitivity to low temperatures and to permeating cryoprotectant solutes. Cells maintained at room temperature (20-22 degrees C) were slowly or rapidly exposed to cold temperatures (1-4 degrees C), and percent motility was estimated to determine the sensitivity of the cells to cooling. Spermatozoa were also in media containing 1 M glycerol, dimethyl sulfoxide or ethylene glycol, and percent motility was measured at 15, 30 and 60 min intervals to determine the sensitivity of the cells to the cryoprotectant agent over time. Results indicate that sperm motility is significantly effected by decreased temperatures and the presence of cryoprotectant agents.

Fundamental cryobiology of human hematopoietic progenitor cells. I: Osmotic characteristics and volume distribution

While methods for the cryopreservation of hematopoietic stem cells are well established, new sources of progenitor cells, such as umbilical cord blood, fetal tissue, and ex vivo expanded progenitor cells, may require refined protocols to achieve optimal recovery after freezing. To predict optimal protocols for cryopreservation of human hematopoietic progenitors, knowledge of fundamental cryobiological characteristics including cell osmotic characteristics, water and cryoprotectant permeability coefficients of cell membrane, and activation energies of these coefficients is required. In this study, we used CD34+CD33- cells isolated from human bone marrow as hematopoietic progenitor cell models/representatives to study the osmotic characteristics of the progenitor cells. Volume distribution and osmotic behavior of the CD34+CD33- cells were determined using two different methods: (a) a shape-independent electronic sizing technique and (b) a shape-dependent optical image analysis. The cell diameter was measured to be 8.2 +/- 1.1 microns (mean +/- SD, n = 1,091,475, the number of donors = 8) using the electronic sizing technique or 8.7 +/- 1.2 microns (mean +/- SD, n = 1508, the number of donors = 6) by image analysis at initial (isotonic) osmolality, 325 mosm/kg. The cell volume change was measured after the cells were exposed and equilibrated to different anisosmotic conditions. The cell volume was found to be a linear function of the reciprocal of the extracellular osmolality (Boyle van't Hoff plot) ranging from 163 to 1505 mosm/kg. The volume fraction of intracellular water which is osmotically active was determined to be 79.5% of the cell volume. It was concluded that human CD34+CD33- cells osmotically behave as ideal osmometers. This information coupled with cell water and cryoprotectant permeability coefficients as well as their activation energies (to be determined in the ongoing research projects) will be used to design optimum conditions for cryopreservation of human hematopoietic progenitor cells.

Osteochondral dowel transplantation for repair of focal defects in the knee: an outcome study using an ovine model

OBJECTIVE

A model system was developed to objectively assess the quality of articular cartilage after surgical reconstruction of focal defects in the median femoral condyle using osteochondral dowel grafts.

STUDY DESIGN

The surgical technique was developed and customized to reproducibly minimize surgical trauma and graft instability in order to improve the survival of the transplanted cartilage and the long-term integrity of the joint surfaces.

ANIMALS OR SAMPLE POPULATION

24 adult female Suffolk-Romanoff crossbred sheep.

METHODS

Biomechanical creep testing, paravital staining for chondrocyte viability, histological analysis, and gross morphological analysis were performed at 3, 6, and 12 months postoperatively to compare fresh autografted osteochondral dowels with allografts that had been subject to a freezing protocol known to kill chondrocytes. The latter was used to investigate the time course of cartilage degeneration after injury. These two groups were also compared with normal unoperated control tissue.

RESULTS

Biomechanical behavior, chondrocyte survival, and cartilage histology differed significantly between fresh grafts and those that had been frozen.

CONCLUSIONS

Indentation testing and paravital staining were able to identify degenerative changes earlier than other methods of assessment. The technique developed here reproducibly and reliably transplanted osteochondral dowel grafts while minimizing the confounding effects of surgical trauma and graft instability.

CLINICAL RELEVANCE

The technique provides both a promising surgical technique for the repair of focal defects of the medial femoral condyle and a sensitive model for the future study of cryopreservation strategies for articular cartilage.

Injury and protection in split-thickness skin after very rapid cooling and warming

The ability of low glycerol concentrations and high cooling and warming rates to optimize the survival of frozen/thawed split-thickness porcine skin was investigated. 1H nuclear magnetic resonance spectroscopy was used to measure the diffusion kinetics of glycerol in skin at 4, 12, and 22 degrees C. Equilibrium concentrations were 44 to 69% of the external bathing medium. Rate constants for glycerol diffusion (D/l2) were calculated from the uptake data using a plane sheet model and a least squares method and were independent of external glycerol concentrations: D/l2 = 3.84 x 10(-4) 8-1 at 4 degrees C with an activation energy of 11.2 +/- 4.3 kcal/mol. Skin was cooled rapidly (-5100 degrees C/min) after different times of glycerol permeation at 4 or 22 degrees C, and survival was assessed after warming (+5400 degrees C/min) by an oxygen consumption assay. Recovery of aerobic activity increased in a concentration-dependent manner, and reached 100% after a 10-min exposure to 2 M glycerol at 4 degrees C or 3 min at 22 degrees C, for an uptake of 1.1 M glycerol. Light micrographs of freeze-substituted skin showed a glycerol-dependent decrease in the nucleation and growth of ice in the dermis and epidermis after rapid cooling. A 5-mm exposure to 2 M glycerol at 22 degrees C resulted in the elimination of all observable epidermal ice, except for extremely small ice crystals (< or = 0.5 micron diameter) in the intercellular spaces and in few nuclei, and complete preservation of the fibrous structure of dermal collagen bundles. This cryoprotective mechanism has the potential to offer complete protection of both dermal and viable epidermal targets of freeze/thaw injury and may be applicable to other thin, membranous tissues.

Freezing injury of granulocytes during slow cooling: role of the granules

The granulocyte is an interesting model for studying the behavior of fragile cells at low temperature. A previous study suggested that during slow freezing the plasma membrane was not the primary site of injury and, as a corollary to this, we examined the damage occurring in the cytoplasmic compartment. The present study was designed to investigate the role of granules during cryoinjury of the granulocytes. Granulocytes were prepared from fresh blood and a population of granules was extracted by nitrogen cavitation. A graded freeze-thaw protocol was used to follow the release of beta-glucuronidase (beta-Glu), one of the hydrolytic enzymes present in granules. Granulocytes and granules were subjected to treatments simulating slow freezing conditions, and the release of beta-Glu was evaluated after exposure to increased hydrolytic enzymes and hypertonic salt concentration. It was found that, after thawing, granulocytes generally expressed more release than granules during graded freezing. The postthaw incubation period had no effect on enzyme release. Increase in salt concentration reduces beta-Glu activity. Direct exposure to hydrolytic enzymes produced similar injury on both granules and granulocytes, and salt combined with enzymes did not increase granule disruption. It is concluded that the effect of injured granules may be more apparent during rewarming when isotonicity is reestablished. Enzymes released extracellularly induce no extra injury to the granulocyte because of dilution effect; however, their release in the cytosol can cause a defect resulting in the loss of cell viability but no membrane disruption. Overall, the release of enzymes is seen as a secondary factor contributing to whole cell or membrane damage during slow freezing.

Mechanisms of cryoinjury and cryoprotection in split-thickness skin

Successful cryopreservation of tissues will ultimately require a more detailed understanding of how the in situ environment modifies cell responses during cooling and warming. Low-temperature responses of porcine split-thickness skin and isolated basal keratinocytes were compared after various cooling protocols and in the presence and absence of cryoprotectants. Recovery was assessed by measuring oxygen consumption kinetics in skin and tetrazolium reduction in isolated cells. Freeze substitution was used to visualize ice nucleation and growth in skin. The results indicated that the time required for diffusion of water in split-thickness skin delayed osmotic responses in the basal keratinocytes and resulted in increased intracellular and intercellular ice formation. Rapid cooling (-200 degrees C/min) in the presence of cryoprotectants resulted in a reduction in the number of cells containing ice and the size of the intercellular ice crystals and an increase in tissue recovery. These observations support other reports which suggest that cell-to-cell and cell-to-substrate interactions are sensitive sites for cryoinjury. A practical recommendation from this study is that high recovery of split-thickness skin may be achieved with protocols using high cooling rates.

Osmotic separation of pancreatic exocrine cells from crude islet cell preparations

A novel approach is introduced here to selectively lyse exocrine cells in an islet preparation by hypo-osmotic treatment. Time to hypotonic cell lysis required for the islet cells was much longer than that for the exocrine cells, which permits a possibility of selectively killing the exocrine cells by hypotonic treatment. The first set of experiments was designed to select an appropriate osmolality for the hypotonic treatment. Kinetic changes in cell volume in response to extracellular anisosmolalities (30 to 90 mOsm/kg) were recorded using an electronic particle counter. The results indicated that, when exposed to a 30 mOsm/kg solution, islet cells swelled slowly to reach volumetric equilibrium in approximately 3 min. There was no significant hypotonic cell lysis observed even at the end of 4 min (n = 4). In contrast, pancreatic exocrine cells, when exposed to the same solution, expanded rapidly to the lytic volume and burst within 30 s. Significant exocrine cell lysis was invariably achieved within 30 s when cells were exposed to the osmolalities below 60 mOsm/kg. For osmolalities between 70 to 80 mOsm/kg, exocrine cell lysis was highly variable. When cells were exposed to 80 to 90 mOsm/kg, no significant cell lysis was observed. Thus, an osmolality of 50 mOsm/kg is recommended for hypotonic treatment, as it maximizes the lysis of exocrine cells without unnecessarily stressing (osmotically) the islet cells. The second set of experiments (time-course experiments, 20 to 120 s) was designed to determine the length of exposure time for which the exocrine cells were irreversibly damaged but the islet cells had only swollen to such a degree that cell function is restored upon returning to an isotonic condition. Viability of the hypotonic treated cells was evaluated at two different levels: membrane integrity, measured by combined fluorescent dye staining with propidium iodide (PI) and carboxyfluorescein diacetate (CFDA), and mitochondrial function, measured by colorimetric MTT assay. The results showed that hypotonic treatment in a 50 mOsm/kg solution for 30 s resulted in over 85% loss of the membrane integrity for the exocrine cells. About 90% of these membrane lysed cells lost mitochondrial function (n = 3). By contrast, under the same treatment, less than 15% of the islet cells lost membrane integrity and mitochondrial function (n = 3). In conclusion, hypotonic treatment with a 50 mOsm/kg solution for 20 to 30 s at room temperature is sufficient to lyse the majority of the contaminating exocrine cells in an islet cell preparation, while maintaining function in the islet cells.

Effect of cryoprotectant solutes on water permeability of human spermatozoa

Osmotic permeability characteristics and the effects of cryoprotectants are important determinants of recovery and function of spermatozoa after cryopreservation. The primary purpose of this study was to determine the osmotic permeability parameters of human spermatozoa in the presence of cryoprotectants. A series of experiments was done to: 1) validate the use of an electronic particle counter for determining both static and kinetic changes in sperm cell volume; 2) determine the permeability of the cells to various cryoprotectants; and 3) test the hypothesis that human sperm water permeability is affected by the presence of cryoprotectant solutes. The isosmotic volume of human sperm was 28.2 +/- 0.2 microns3 (mean +/- SEM), 29.0 +/- 0.3 microns3, and 28.2 +/- 0.4 microns3 at 22, 11, and 0 degrees C, respectively, measured at 285 mOsm/kg via an electronic particle counter. The osmotically inactive fraction of human sperm was determined from Boyle van't Hoff (BVH) plots of samples exposed to four different osmolalities (900, 600, 285, and 145 mOsm/kg). Over this range, cells behaved as linear osmometers with osmotically inactive cell percentages at 22, 11, and 0 degrees C of 50 +/- 1%, 41 +/- 2%, and 52 +/- 3%, respectively. Permeability of human sperm to water was determined from the kinetics of volume change in a hyposmotic solution (145 mOsm/kg) at the three experimental temperatures. The hydraulic conductivity (Lp) was 1.84 +/- 0.06 microns.min-1.atm-1, 1.45 +/- 0.04 microns.min-1.atm-1, and 1.14 +/- 0.07 microns.min-1.atm-1 at 22, 11, and 0 degrees C, respectively, yielding an Arrhenius activation energy (Ea) of 3.48 kcal/mol. These biophysical characteristics of human spermatozoa are consistent with findings in previous reports, validating the use of an electronic particle counter for determining osmotic permeability parameters of human sperm. This validated system was then used to investigate the permeability of human sperm to four different cryoprotectant solutes, i.e., glycerol (Gly), dimethylsulfoxide (DMSO), propylene glycol (PG), and ethylene glycol (EG), and their effects on water permeability. A preloaded, osmotically equilibrated cell suspension was returned to an isosmotic medium while cell volume was measured over time. A Kedem-Katchalsky model was used to determine the permeability of the cells to each solute and the resulting water permeability. The permeabilities of human sperm at 22 degrees C to Gly, DMSO, PG, and EG were 2.07 +/- 0.13 x 10(-3) cm/min, 0.80 +/- 0.02 x 10(-3) cm/min, 2.3 +/- 0.1 x 10(-3) cm/min, and 7.94 +/- 0.67 x 10(-3) cm/min, respectively. The resulting Lp values at 22 degrees C were reduced to 0.77 +/- 0.08 micron.min-1.atm-1, 0.84 +/- 0.07 micron.min-1.atm-1, 1.23 +/- 0.09 microns.min-1.atm-1, and 0.74 +/- 0.06 micron.min-1.atm-1, respectively. These data support the hypothesis that low-molecular-weight, nonionic cryoprotectant solutes affect (decrease) human sperm water permeability.

Water permeability and its activation energy for individual hamster pancreatic islet cells

Coupled with the rapid development of clinical pancreatic islet transplantation, there is an increasing requirement for cryopreservation of viable islets. Fundamental cryobiology requires determination of several cryobiophysical parameters to predict optimal cryopreservation procedures. These include water permeability or hydraulic conductivity (Lp) and its activation energy (Ea), the permeability of the cell plasma membrane to a cryoprotectant(s) (Ps) and its Ea, the osmotically inactive fraction of cell volume (Vb), and the intracellular ice formation temperature. For islet cells, these parameters have not previously been reported. In the present studies, the Lp, its Ea, and Vb were determined for isolated individual golden hamster pancreatic islet cells. The Lp and Vb parameters were also measured for corresponding exocrine cells. Both islet and the exocrine cells appeared to be ideal osmometers over the experimental range when examined by the Boyle Van't-Hoff relationship (linear regression, r = 0.99 for both types of cells). Extrapolation of these plots generated Vb values of 0.40 for the islet cells and 0.45 for the pancreatic exocrine cells. To determine the Lp, kinetic changes of cell volume over time (dv/dt) in response to anisoosmotic conditions (ranging from 145 mOsm/kg to 1.35 Osm/kg) were measured using an electronic particle counter. The experimental data were fitted to generate the Lp values by least-squares curve fitting to a differential equation describing osmotic water movement across the plasma membrane. For pancreatic islet cells, the Lp was determined to be 0.25 +/- 0.03 microns/min/atm (mean +/- SD, n = 14) at 22 degrees C, 0.54 +/- 0.07 (n = 10), 0.06 +/- 0.008 (n = 9), and 0.01 +/- 0.001 (n = 9) at 37, 8 and 0 degrees C, respectively. The Ea for Lp was calculated from the slope of the Arrhenius plot based upon the mean Lp values at the four different temperatures. The Ea was 16.21 Kcal/mol between 0 and 37 degrees C. Based upon these values, an optimal cooling rate for cryopreserving pancreatic islet cells is predicted to be approximately 0.5 degrees C min. The Lp for the individual exocrine cells was determined to be 3.73 +/- 1.75 microns/min/atm (n = 13) at 22 degrees C, which was approximately 10 times the Lp value of the corresponding islet cells.

Prevention of osmotic injury to human spermatozoa during addition and removal of glycerol

Use of a cryoprotective agent is indispensable to prevent injury to human spermatozoa during the cryopreservation process. However, addition of cryoprotective agents to spermatozoa before cooling and their removal after warming may create severe osmotic stress for the cells, resulting in injury. The objective of this study was to test the hypothesis that the degree (or magnitude) of human sperm volume excursion can be used as an independent indicator to evaluate and predict possible osmotic injury to spermatozoa during the addition and removal of cryoprotective agents. Glycerol was used as a model cryoprotective agent in the present study. To test this hypothesis, first the tolerance limits of spermatozoa to swelling in hypo-osmotic solutions (iso-osmotic medium diluted with water) and to shrinkage in hyperosmotic solutions (iso-osmotic medium with sucrose) were determined. Sperm plasma membrane integrity was measured by fluorescent staining, and sperm motility was assessed by computer-assisted semen analysis before, during and after the anisosomotic exposure. The result indicate firstly that motility was much more sensitive to anisosmotic conditions than membrane integrity, and secondly that motility was substantially more sensitive to hypotonic than to hypertonic conditions. Based on the experimental data, osmotic injury as a function of sperm volume excursion (swelling or shrinking) was determined. The second step, using these sperm volume excursion limits and previously measured glycerol and water permeability coefficients of human spermatozoa, was to predict, by computer simulation, the cell osmotic injury caused by different procedures for the addition and removal of glycerol. The predicted sperm injury was confirmed by experiment. Based on this study, an analytical methodology has been developed for predicting optimal protocols to reduce osmotic injury associated with the addition and removal of hypertonic concentrations of glycerol in human spermatozoa.

High water permeability of human spermatozoa is mercury-resistant and not mediated by CHIP28

A novel integral membrane protein with an apparent molecular mass of 28 kDa (CHIP28) was first isolated from human erythrocytes and is now recognized as a water channel protein. The expression of this protein has been found in several other cell types that all require high water permeability for their functions. Recent studies have shown that the water permeability (Lp) of human spermatozoa is among the highest reported for mammalian cells. Together with the low activation energy of human spermatozoa for Lp, this suggests that CHIP28 water channel may be present in the plasma membrane of human spermatozoa. However, our current studies do not support this hypothesis. Results from Western blot analysis on human sperm plasma membrane proteins, performed through use of an antibody against human erythrocyte CHIP28 protein, indicated that human spermatozoa do not express CHIP28 protein on their cell surface (n = 10). Consistent with the Western blot finding, mercuric chloride (HgCl2), a known water channel blocker, failed to reduce the osmotic water permeability of human spermatozoa. The calculated Lp values were 1.30 +/- 0.29 micron/min/atm (n = 16; mean +/- SEM) for the control group and 1.31 +/- 0.29 (n = 9; mean +/- SEM), 1.04 +/- 0.27 (n = 11; mean +/- SEM), and 1.34 +/- 0.19 (n = 6; mean +/- SEM), respectively, for the 10 microM, 30 microM, and 50 microM HgCl2-treated groups. These Lp values are not different (p > 0.05). In contrast, the same concentration of HgCl2 significantly blocked the osmotic water transport across the membrane of human erythrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization of freezing injury in articular cartilage

In order to improve techniques for cryopreservation of articular cartilage, a study has been carried out to assess localization of cryoinjury in intact articular cartilage. Osteochondral dowels taken from the femoral condyles of sheep were subjected to graded freezing in the presence and absence of a cryoprotectant (10% DMSO). The graded freezing technique involves slow cooling (1 degree C/min) to various subzero temperatures before either rapid warming or rapid cooling by plunging in liquid nitrogen. This protocol allows assessment of the separate effects of rapid and slow freezing which damage cells in different ways, and the effects of cryoprotectants on the different types of damage. To assay damage, thin slices of cartilage were cut with a vibratome, which allows viable cells within the matrix to be observed microscopically. Injury was assessed by staining with fluorescent dyes to indicate damage to the plasma membrane. In general, tissue response was similar to that of cell suspensions, showing at least two mechanisms of injury acting on the cells: one at slow cooling rates and another at rapid cooling rates. The primary effect of DMSO was to reduce injury due to slow cooling. When the location of injury within the tissue was examined, it was found that chondrocytes of the intermediate layer were injured more extensively than those of either the deep or superficial layers.

The osmotic rupture hypothesis of intracellular freezing injury

A hypothesis of the nature of intracellular ice formation is proposed in which the osmotically driven water efflux that occurs in cells during freezing (caused by the increased osmotic pressure of the extracellular solution in the presence of ice) is viewed as the agent responsible for producing a rupture of the plasma membrane, thus allowing extracellular ice to propagate into the cytoplasm. This hypothesis is developed into a mathematical framework and the forces that are present during freezing are compared to the forces which are required to rupture membranes in circumstances unrelated to low temperatures. The theory is then applied to systems which have been previously studied to test implications of the theory on the nature of intracellular ice formation. The pressure that develops during freezing due to water flux is found to be sufficient to cause a rupture of the plasma membrane and the theory gives an accurate description of the phenomenology of intracellular ice formation.

Metabolic activity of bovine articular cartilage during refrigerated storage

The ability of the chondrocytes in intact bovine articular cartilage (AC) to synthesize glycosaminoglycans (GAG) during short-term refrigerated storage was examined. Closed and exposed bovine carpometacarpal joints were stored in a refrigerator for 4 hours, 1 day, 3 days, 5 days, or 7 days after the death of the animal. Full-thickness 6 mm diameter cartilage disks were obtained from each joint, incubated in Na2(35)SO4, digested and assayed for GAG production. Similarly incubated cartilage samples were processed for autoradiography as a qualitative determination of 35S uptake by chondrocytes. All refrigerated samples of AC showed signs of some cellular metabolic activity. Only at 7 days did chondrocytes demonstrate a significant decline in activity. For all five storage periods, AC from joints exposed to nutrient media synthesized more GAG than cartilage from matched closed joints. These results suggest that some chondrocytes in AC destined for osteoarticular allografting retain the ability to synthesize GAG for as long as 5 days of refrigerated storage and that this synthesis is stimulated by storage of the joint surfaces in a sterile nutrient solution. While the implications of the chondrocytes' survival and metabolism for osteochondral allograft transplantation are unknown, these data indicate that intact bovine AC retains some metabolic activity for several days under the conditions described and would carry on this activity if transplanted within that period of time.

A simple, effective system for assessing viability in split-thickness skin with the use of oxygen consumption

To address the recognized need for better viability-assessment techniques in the banking of allograft skin, we have developed a simple, effective, and easily constructed system for measuring the aerobic activity in small skin samples. The system consists of a microcomputer interfaced to a Clark-type polarographic oxygen electrode to measure oxygen concentrations in discs (5 mm diameter) of split-thickness skin. The system allows simultaneous data acquisition and an on-screen display of oxygen readings on a linear or logarithmic scale. The computer program quantifies the rate of oxygen consumption by calculating a linear regression of oxygen measurements between 100 and 600 seconds. Data are stored in a standard format for easy transfer to commercial software packages for further analysis. The kinetics of oxygen consumption by porcine split-thickness skin stored at 4 degrees C for up to 21 days was assessed with this technique and showed a gradual decline in rate as function of storage time, reaching 50% recovery after 6 days. This assay is a simple and inexpensive method to establish and perform, thus making it suitable as a routine assay for use in the banking of skin and other tissues.

Ultrastructural changes of articular cartilage chondrocytes associated with freeze-thawing

In an attempt to justify the use of cryopreserved versus fresh articular cartilage (AC) allografts, we used transmission electron microscopy (TEM) to study the ultrastructure of fresh versus frozen-thawed AC with or without a dimethyl sulfoxide (DMSO) treatment. AC explants were cut aseptically from the femoral condyles of healthy, mature rabbits when they were killed. Half of all explants were incubated in Ham's F-12 medium, supplemented with antibiotics and with or without 7.5% DMSO, frozen to -80 degrees C, stored for 24 h, and thawed rapidly. These, and the control explants, were fixed with glutaraldehyde, paraformaldehyde, and acrolein in cacodylate buffer. Sections were stained for acid phosphatase (APase), postfixed with osmium, embedded, and examined under TEM. The typical organization of the matrix and the cells was noted in control sections. The chondrocytes contained intact nuclei, organelles, and discrete plasma membrane. Although some endoplasmic reticula and nuclear membrane appeared intact, distinct ultrastructural changes were observed in frozen-thawed samples treated with DMSO. These changes included condensation of chromatin, large lipid droplets, partly disrupted plasma membrane, and pericellular precipitation of APase-positive crystalites. In sections not treated with DMSO, the cytoplasm was extensively vacuolated and no distinct organelles could be detected in the chondrocytes. Little difference was noted between the matrix organization of fresh or frozen-thawed samples. Our results suggest that distinct ultrastructural changes occur in the chondrocytes following freeze-thawing of intact AC and that DMSO pretreatment may contribute to improvement in the cryopreservation of AC.

Improvement of Longevity and Viability of Sperm Cells Isolated from Pollen of Zea mays L

Our previous studies showed that the common maize (Zea mays L.) sperm isolation medium (Brewbaker and Kwack salts in 0.44 m sucrose without buffering) caused cell lysis in vitro. In an attempt to remedy this situation, 6 sugars, 10 buffers, 5 pH values, and 3 membrane protective agents were screened to improve longevity and viability of isolated Zea mays sperm cells as estimated by hemacytometry and flow cytometry. Use of 0.55 m galactose in the isolation solution increased sperm yield by 2.5-fold compared with sucrose, and suspension of isolated sperm cells in the galactose solution gave the best longevity among the six sugars. Buffering the galactose solution with 2 mm 2-(N-morpholino)ethanesulfonic acid significantly improved longevity, whereas other buffers had no effect or decreased the longevity and/or viability. Among the five pH values tested (5.0, 6.0, 6.7, 7.0, and 8.0), pH 6.7 appeared to be optimal for maintenance of both longevity and viability. Screening of membrane protectants showed that cysteine caused a rapid decrease in cell viability and increased lysis, whereas dithiothreitol increased the cell numbers but lowered their viability. Addition of 0.1% bovine serum albumin increased cell numbers and viability, and about 70% of the cells remained viable after 72 h of suspension. Cell longevity and viability were also improved in 0.44 m sucrose when the solution was conditioned with 2-(N-morpholino)ethanesulfonic acid and bovine serum albumin. Use of 2-(N-morpholino)ethanesulfonic acid and bovine serum albumin inthe isolation and suspension medium significantly improved the viability and longevity of sperm cells isolated from Zea mays pollen.