[Research progress on antibody-dependent enhancement in infectious diseases]

Antibody-dependent enhancement (ADE) refers to the process in which some virus-specific antibodies (generally non-neutralizing antibodies) bind to the virus and bind to some cells expressing FcR on the surface through their Fc segment, thereby mediating the endocytosis and replication of the virus and enhancing the infection of the virus. This review summarized experience of ADE in respiratory syncytial virus, dengue virus, influenza virus infection and explored the possible mechanism of COVID-19 high incidence and severity of the disease, which implied challenges in the process of vaccine development and provided some insights for COVID-19 pathogenesis.

Engineering a protein-based nanoplatform as an antibacterial agent for light activated dual-modal photothermal and photodynamic therapy of infection in both the NIR I and II windows

Ultra-small protein-based nanoparticles with absorption in both the NIR I and II biological windows were designed as new photoactivatable antibacterial agents.

Cryopreservation of human adipose tissues

Scientific studies on cryopreservation of adipose tissues have seldom been performed. The purpose of our present study is conducted both in vitro and in vivo to develop a novel cryopreservation method that can be used successfully for long-term preservation of human adipose tissues for possible future clinical application. In this study, samples of adipose aspirates were obtained from 36 adult white female patients after liposuction and collected from the middle layer after centrifugation. In the in vitro study, suitable cryoprotectant agents (CPAs) and their concentrations and possible combinations were selected from our preliminary experiment. A combination of dimethyl sulfoxide (Me(2)SO) and trehalose as CPA with the optimal concentration (0.5M Me(2)SO and 0.2M trehalose) was chosen and then used throughout the study. In addition, maximal recovery of adipose tissues was achieved after cryopreservation using slow cooling without seeding (1-2 degrees C/min to -30 degrees C, followed by plunging to -196 degrees C for storage) and fast warming (in 40 degrees C water bath, averaging 35 degrees C/min). Fresh adipose aspirates (Group 1), cryopreserved adipose aspirates without CPAs (Group 2), or cryopreserved adipose aspirates with CPAs (Group 3) were evaluated by integrated adipocyte counts and histology. In the in vivo study, fresh adipose aspirates (Group 1), cryopreserved adipose aspirates without CPAs (Group 2), or cryopreserved adipose aspirates with CPAs (Group 3) were injected into a nude mouse. The retained adipose aspirates (fat grafts) were harvested in each animal at 4 months and their weight, volume, and histology was assessed. In the in vitro study, significantly higher integrated viable adipocyte count (2.06+/-0.54 x 10(6)mL(-1) vs. 1.07+/-0.41 x 10(6)mL(-1), p<0.0011) of adipose aspirates was found in Group 3 compared with Group 2. Group 3 had only a marginally lower integrated viable adipocyte count compared with Group 1 (2.06+/-0.54 x 10(6)mL(-1) vs. 2.57+/-0.56 x 10(6)mL(-1), p=0.083). Histologically, more tissue shrinkage was evident in Group 2 compared with Group 3. In the in vivo study, various degrees of absorption of injected fat grafts were seen in all 3 groups. However, Group 3 had significantly more retained weight and volume of the injected fat grafts than Group 2 (both p<0.0001) but had significantly less retained weight and volume than Group 3 (weight, p=0.009178; volume, p=0.007836). Histologically, a large amount of tissue fibrosis was seen in Group 2, and reasonably well maintained fatty tissue with only a small amount of tissue fibrosis was seen in Group 3. The results from the present in vitro and in vivo studies, for the first time, demonstrate that our preferred cryopreservation method, the combination of 0.5M Me(2)SO and 0.2M trehalose as CPA in addition to the controlled slow cooling and fast rewarming protocol, appears to provide the maximum recovered results in cryopreservation of human adipose tissues and may become a real option after further refinements for cryopreservation of human adipose aspirates in a clinical setting.

Generation of annexin V-positive platelets and shedding of microparticles with stimulus-dependent procoagulant activity during storage of platelets at 4 degrees C

BACKGROUND

The ability of propyl gallate to activate platelet factor 3 has been determined through the activated partial thromboplastin time, but its effect on phosphatidylserine has not been established.

STUDY DESIGN AND METHODS

A novel platelet activator, propyl gallate, was introduced to a study of platelets stored at 4 degrees C. The effects of storage on platelet coagulation activity, on phosphatidylserine, and on the shedding of activated and activable membrane particles (microparticles) were examined by activated plasma clotting time, and the effect on annexin V binding was examined by gated flow cytometry. The ratios of annexin V binding and microparticle shedding in stored platelet samples were compared with those in fresh platelets stimulated with propyl gallate.

RESULTS

Microparticle shedding by stored platelets compensated for the diminished procoagulant potential of intact platelets (shown as the total propyl gallate-dependent platelet factor 3 activity), which did not change during prolonged (20-day) storage, but levels of phosphatidylserine confined to microparticles increased dramatically as platelet counts fell. Both annexin V binding and microparticle shedding increased spontaneously with storage and artificially with propyl gallate stimulation. However, at the same level of annexin V binding, stored platelets shed more microparticles than did fresh platelets stimulated with propyl gallate.

CONCLUSION

Propyl gallate induces platelet procoagulant activity and annexin V binding. Stored platelets differ from fresh platelets in a lower reactivity to propyl gallate activation and a higher rate of microparticle shedding.

Equations for obtaining melting points for the ternary system ethylene glycol/sodium chloride/water and their application to cryopreservation

The present study describes the H(2)O-NaCl-ethylene glycol ternary system by using a differential scanning calorimeter to measure melting points (T(m)) of four different ratios (R) of ethylene glycol to NaCl and then devising equations to fit the experimental measurements. Ultimately an equation is derived which characterizes the liquidus surface above the eutectic for any R value in the system. This study focuses on ethylene glycol in part because of recent evidence indicating it may be less toxic to pancreatic islets than Me(2)SO, which is currently used routinely for islet cryopreservation. The resulting physical data and previously determined information regarding the osmotic characteristics of canine pancreatic islets are combined in a mathematical model to describe the volumetric response to equilibrium-rate freezing in varying initial concentrations of ethylene glycol.

Determination of human platelet membrane permeability coefficients using the Kedem-Katchalsky formalism: estimates from two- vs three-parameter fits

Attempts to cryopreserve human blood platelets have resulted in poor postthaw survival rates and have been inadequate for routine clinical application. As a result, most blood banks maintain platelets in nonfrozen solutions. Using this approach, platelets can be stored for only about 5 days and are then discarded. This situation greatly limits the use of platelet transfusion in clinical practice. Information regarding fundamental cryobiological characteristics can be applied to predict platelet response to cryoprotective agent (CPA) addition/removal and to cooling/warming. Methods can then be engineered to optimize cryopreservation procedures, thereby minimizing platelet damage and maximizing postthaw recovery. It was therefore the purpose of this study to determine some of the necessary biophysical parameters required for this process: (i) plasma membrane hydraulic conductivity (Lp), (ii) cryoprotectant solute permeability coefficient (Ps), (iii) the associated reflection coefficient (sigma), and (iv) their activation energies. The CPAs studied included dimethyl sulfoxide (Me2SO) and propylene glycol at 1.5 M concentration. Permeability was measured at 22, 10, and 4 degrees C using a modified Coulter counter in conjunction with a water-jacketed beaker system for temperature regulation. The Kedem-Katchalsky formalism was used to estimate the parameters using: (1) a three-parameter fit and (2) a two-parameter fit in which a noninteracting value of sigma was calculated. Two-parameter estimates were in closer agreement with previously published values, and these were used in a model to simulate addition and removal of 0.64 M (5%) and 1.0 M (7.8%) Me2SO, the most common CPA currently used in empirically determined platelet cryopreservation protocols.

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.

Hydraulic conductivity (Lp) and its activation energy (Ea), cryoprotectant agent permeability (Ps) and its Ea, and reflection coefficients (sigma) for golden hamster individual pancreatic islet cell membranes

Long-term cryopreservation of islets of Langerhans would be advantageous to a clinical islet transplantation program. Fundamental cryobiology utilizes knowledge of basic biophysical characteristics to increase the understanding of the preservation process and possibly increase survival rate. In this study several of these previously unreported characteristics have been determined for individual islet cells isolated from Golden hamster islets. Using an electronic particle counting device and a temperature control apparatus, dynamic volumetric response of individual islet cells to anisosmotic challenges of 1.5 M dimethyl sulfoxide (DMSO) and 1.5 M ethylene glycol (EG) were recorded at four temperatures (8, 22, 28, and 37 degreesC). The resulting curves were fitted using Kedem and Katchalsky equations which describe water flux and cryoprotectant agent (CPA) flux based on hydraulic conductivity (Lp), CPA permeability (Ps), and reflection coefficient (final sigma) for the membrane. For Golden hamster islet cells, Lp, Ps, and final sigma for DMSO at 22 degreesC were found to be 0.23 +/- 0.06 microm/min/atm, 0.79 +/- 0.32 x 10(-3) cm/min, and 0.55 +/- 0.37 (n = 11) (mean +/- SD), respectively. For EG at 22 degreesC, Lp equaled 0.23 +/- 0.06 microm/min/atm, Ps equaled 0.63 +/- 0.20 x 10(-3) cm/min, and final sigma was 0.75 +/- 0.17 (n = 9). Arrhenius plots (ln Lp or ln Ps versus 1/temperature (K)) were created by adding the data from the other three temperatures and the resulting linear regression yielded correlation coefficients (r) of 0.99 for all four plots (Lp and Ps for both CPAs). Activation energies (Ea) of Lp and Ps were calculated from the slopes of the regressions. The values for DMSO were found to be 12.43 and 18.34 kcal/mol for Lp and Ps (four temperatures, total n = 52), respectively. For EG, Ea of Lp was 11.69 kcal/mol and Ea of Ps was 20.35 kcal/mol (four temperatures, total n = 58).

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.

Randomized, controlled trial of high-dose intravenous pyridoxine in the treatment of recurrent seizures in children

To determine the efficacy of pyridoxine in treating seizures, 90 infants and children with recurrent convulsions primarily due to acute infectious diseases were enrolled in the present study. Forty patients were treated with high-dose pyridoxine (30 or 50 mg/kg/day) by intravenous infusion, and 50 subjects served as controls. Antiepileptic drugs and other therapies were similar in the two groups except for pyridoxine. Clinical efficacy criteria were based on the frequency of convulsions per day and on the duration of individual seizures after therapy was initiated. The results indicated that total response rates in the pyridoxine group and control group were 92.5% and 64%, respectively (chi-square = 14.68, P < .001). After initiation of therapy, seizures resolved after 2.4 +/- 1.4 days in the pyridoxine group and after 3.7 +/- 2.0 days in the control group (t = 3.67, P < .001). No adverse effects of pyridoxine were apparent during the observation period. We conclude that pyridoxine is an effective, safe, well-tolerated, and relatively inexpensive adjunct to routine antiepileptic drugs for treatment of recurrent seizures in children.

Determination of optimal cryoprotectants and procedures for their addition and removal from human spermatozoa

The objective was to test the hypothesis that the optimal cryoprotective agent for cryopreservation of human spermatozoa would be a solute for which cells have the highest plasma membrane permeability, resulting in the least amount of volume excursion during its addition and removal. To test this hypothesis, theoretical simulations were performed using membrane permeability coefficients to predict optimal procedures for the addition and removal of a cryoprotectant. Simulations were performed using data from four different cryoprotectants: (i) glycerol, (ii) dimethyl sulphoxide, (iii) propylene glycol and (iv) ethylene glycol. Thermodynamic formulations were applied to determine approaches for the addition and removal of 1 M and 2 M final concentrations of cryoprotectant, allowing the spermatozoa to maintain a cell volume within their osmotic tolerance limits. Based on these data, ethylene glycol was predicted to be optimal for minimizing volume excursions among the solutes evaluated. These predictions were then experimentally tested using glycerol as the control cryoprotectant and ethylene glycol as the experimental cryoprotectant. The results indicate that there was a higher (P < 0.05) recovery of motile spermatozoa after cryopreservation when using 1 M ethylene glycol than with 1 M glycerol, supporting the hypothesis that use of the cryoprotectant for which the cell has the highest permeability will result in higher cell survival.

Development of a novel microperfusion chamber for determination of cell membrane transport properties

A novel microperfusion chamber was developed to measure kinetic cell volume changes under various extracellular conditions and to quantitatively determine cell membrane transport properties. This device eliminates modeling ambiguities and limitations inherent in the use of the microdiffusion chamber and the micropipette perfusion technique, both of which have been previously validated and are closely related optical technologies using light microscopy and image analysis. The resultant simplicity should prove to be especially valuable for study of the coupled transport of water and permeating solutes through cell membranes. Using the microperfusion chamber, water and dimethylsulfoxide (DMSO) permeability coefficients of mouse oocytes as well as the water permeability coefficient of golden hamster pancreatic islet cells were determined. In these experiments, the individual cells were held in the chamber and perfused at 22 degrees C with hyperosmotic media, with or without DMSO (1.5 M). The cell volume change was videotaped and quantified by image analysis. Based on the experimental data and irreversible thermodynamics theory for the coupled mass transfer across the cell membrane, the water permeability coefficient of the oocytes was determined to be 0.47 micron. min-1. atm-1 in the absence of DMSO and 0.65 microns. min-1. atm-1 in the presence of DMSO. The DMSO permeability coefficient of the oocyte membrane and associated membrane reflection coefficient to DMSO were determined to be 0.23 and 0.85 micron/s, respectively. These values are consistent with those determined using the micropipette perfusion and microdiffusion chamber techniques. The water permeability coefficient of the golden hamster pancreatic islet cells was determined to be 0.27 microns. min-1. atm-1, which agrees well with a value previously determined using an electronic sizing (Coulter counter) technique. The use of the microperfusion chamber has the following major advantages: 1) This method allows the extracellular condition(s) to be readily changed by perfusing a single cell or group of cells with a prepared medium (cells can be reperfused with a different medium to study the response of the same cell to different osmotic conditions). 2) The short mixing time of cells and perfusion medium allows for accurate control of the extracellular osmolality and ensures accuracy of the corresponding mathematical formulation (modeling). 3) This technique has wide applicability in studying the cell osmotic response and in determining cell membrane transport properties.

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.

Fracture phenomena in an isotonic salt solution during freezing and their elimination using glycerol

Thermal stress and consequent fracture in frozen organs or cell suspensions have been proposed to be two causes of cell cryoinjury. A specific device was developed to study the thermal stress and the fracture phenomena during a slow cooling process of isotonic NaCl solutions with different concentrations of glycerol (cryoprotectant) in a cylindrical tube. It was shown from the experimental results that glycerol significantly influenced the solidification process of the ternary solutions and reduced the thermal stress. The higher the initial glycerol concentration, the lower the thermal stress in the frozen solutions. Glycerol concentrations over 0.3 M were sufficient to eliminate the fracture of the frozen solutions under the present experimental conditions. To explain the action of glycerol in reducing the thermal stress and preventing the ice fracture, a further study on ice crystal formation and growth of ice in these solutions was undertaken using cryomicroscopy. It is known from previous studies that an increase of initial glycerol concentration reduced frozen fraction of water in the solution at any given low temperature due to colligative properties of solution, which reduced the total ice volume expansion during water solidification. The present cryomicroscopic investigation showed that under a fixed cooling condition the different initial glycerol concentrations induced the different microstructures of the frozen solutions at not only a given low temperature but also a given frozen fraction of water. It has been known that ice volume expansion during solidification is a major factor causing the thermal stress and the interior microstructure is critical for the mechanical strength of a solid. Therefore, functions of glycerol in reducing the total ice volume expansion during water solidification and in influencing interior microstructure of the ice may contribute to reduce the thermal stress and prevent the fracture in the frozen solutions.

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.

Membrane transport properties of mammalian oocytes: a micropipette perfusion technique

A perfusion technique using micropipette methodology was developed to determine quantitatively the membrane transport properties of mammalian oocytes. This method eliminates modelling ambiguities inherent in microdiffusion, a closely related technology, and should prove to be especially valuable for study of the coupled transport of water and cryoprotectant through mammalian oocytes and embryos. The method is described and evidence given for validity of the method for the simple case of uncoupled flow of water through the mouse oocyte membrane. The zona pellucida of a mouse oocyte was held by a micropipette with an 8-10 microns diameter tip opening and perfused by hyperosmotic media. The kinetic volume change of the cell was videotaped and quantified by image analysis. Experimental data and mathematical modelling were used to determine the hydraulic conductivity of the oocyte membrane (Lp) found to be 1.05, 0.45 and 0.26 microns min-1 atm-1 at 30 degrees C, 22 degrees C and 12 degrees C, respectively. The corresponding activation energy, Ea, for Lp was calculated to be 13.0 kcal mol-1. These values are in agreement with data obtained by other techniques. One of the major advantages of this technique is that the extracellular osmotic condition can be changed readily by perfusing a single cell with a prepared medium. To study the response of the same cell to different osmotic conditions, the old perfusion medium can be removed easily and the cell reperfused with a different medium.(ABSTRACT TRUNCATED AT 250 WORDS)

Determination of the osmotic characteristics of hamster pancreatic islets and isolated pancreatic islet cells

The ability to store pancreatic islets using cryopreservation methodology would greatly assist the application of clinical islet transplantation to Type 1 (insulin-dependent) diabetics. It is our working thesis that the illumination of fundamental biophysical characteristics of these cells will lead to increased cryosurvival rates through theoretically predicted and experimental testing of optimal freezing protocol; as has been found for cells and tissues such as mammalian and Drosophila embryos. Pancreatic islets were isolated from Golden hamsters and their osmometric behavior, including inactive cell volume (Vb), was determined for either whole islets or isolated individual islet cells. When islets or islet cells were exposed to various concentrations of NaCl, they were found to exhibit a "classic" "Boyle-Van't Hoff" osmometric response. The Boyle-Van't Hoff representation of the volume curve (relative cell volume vs. 1/osmolality) yields a linear response with r values of .99 for each curve. Extrapolations to the normalized osmotically inactive volumes (Vb) were .43 and .22 for whole islets and individual islet cells, respectively. These data regarding the fundamental cryobiological characteristics of islets and islet cells should provide the foundation upon which to further the investigation of osmotic parameters of these cells and eventually lead to the determination of optimal freezing protocols.

Hyperosmotic tolerance of human spermatozoa: separate effects of glycerol, sodium chloride, and sucrose on spermolysis

Hyperosmotic stress, which cells experience during the freezing process, and its release during the warming process are both related to cryoinjury. To define optimal cooling or warming rates and prevent osmotic injury to human sperm, information is required regarding the osmotic tolerance of the cells as a function of 1) time, 2) temperature, 3) type of solute, and 4) solute concentration. Human sperm samples were divided into three aliquots. The aliquots were equilibrated at 0, 8, and 22 degrees C, respectively. Different hyperosmotic solutions were prepared by addition of either a permeating cryoprotective agent (glycerol) or nonpermeating solutes (sucrose, non-ionic; or NaCl, ionic) to isotonic Mann's Ringer solution. Aliquots of the prepared solutions were equilibrated at 0, 8, and 22 degrees C, respectively. A small volume (2.5 microliters) of each sperm aliquot was quickly mixed with 50 microliters of each hyperosmotic solution at the corresponding temperature. After times ranging from 5 s to 5 min, 10 microliters of each hyperosmotic cell suspension was abruptly returned to an isosmotic environment by mixing with 500 microliters of Mann's Ringer solution at the corresponding temperature. The plasma membrane integrity of cells after exposure to hyperosmotic stress and after return to isosmotic conditions was measured by a dual staining (carboxyfluoroscein diacetate and propidium iodide) technique and flow cytometry. The morphology of the treated cells was observed by scanning electron microscopy of freeze-substituted sperm. The results indicate that human spermatozoa exhibited a significant posthypertonic lysis/injury, i.e., loss of membrane integrity, when returned to isosmotic conditions after exposure to hyperosmotic solutions of NaCl or sucrose. The higher the hyperosmolality, the more serious the cell injury. The majority of the cells (> 50%) lost membrane integrity when the osmolality was > or = 2000 mOsm. In contrast, if the sperm were not returned to isosmotic conditions, the majority of the sperm in the hyperosmotic solutions appeared to maintain membrane integrity. For a given higher hyperosmolality (> 1000 mOsm), posthypertonic spermolysis was reduced with a decrease of temperature. Cell survival was also affected by time of cell exposure to hyperosmotic environments before cells were returned to the isotonic condition. The shorter the time, the higher the cell survival. When exposed to hyperosmotic glycerol solutions that were isotonic with respect to electrolytes, few cells lost their membrane integrity if the osmolality of glycerol was < 3000 mOsm. For a fixed high osmolality (> 3000 mOsm), the lower the temperature, the higher the percentage spermolysis.(ABSTRACT TRUNCATED AT 400 WORDS)

Glycerol permeability of human spermatozoa and its activation energy

Glycerol has commonly been employed as a cryoprotectant in cryopreservation of human spermatozoa. However, the addition of glycerol into the sperm before freezing and the removal of glycerol from the sperm after freezing and thawing result in anisotonic environments to the cells, which can cause cell injury. To define optimal procedures for the addition/removal of glycerol and to minimize the cell injury, one needs to know the kinetics of glycerol permeation across the sperm plasma membrane at different temperatures. For this, one has to determine the permeability coefficient of glycerol (Pg) and its activation energy (Ea). Values of Pg at different temperatures and at different glycerol concentrations were determined by measuring the time required for 50% spermolysis in hyperosmotic glycerol solutions which were hypotonic with respect to electrolytes. Value of the Ea was determined assuming an Arrhenius type temperature dependence of Pg. A dual fluorescent staining technique (propidium iodide and 6-carboxyfluoroscein diacetate) and flow cytometry were used to measure the spermolysis. The values of Pg in 0.5, 1.0, 1.5, and 2.0 M glycerol at 22 degrees C are 1.62, 1.88, 1.68, and 1.54 x 10(-3) cm/min, respectively. The values of Pg in 1 M glycerol at 0, 8, 22, and 30 degrees C are 0.33, 0.54, 1.88, and 2.60 x 10(-3) cm/min, respectively. The value of Ea is 11.76 kcal/mol.

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.