Effect of cryoprotectant concentration, equilibration time and thawing procedure on survival and development of rapid frozen-thawed mature mouse oocytes

Experiments were conducted to develop a simple rapid-freezing protocol for mature mouse oocytes that would yield a high proportion of oocytes with developmental potential. The effects of concentration (3.5, 4.5 and 6.0 M dimethyl sulfoxide (DMSO) all with 0.5 M sucrose) and the duration of exposure (2.5 min vs 45 sec) of oocytes to the cryoprotectant and its extraction after thawing in 2, 3 or 4 steps of descending sucrose concentration were studied. The most effective of the rapid-freezing and thawing protocols (4.5 M DMSO; 45 sec exposure and 3-step thawing) was compared to slow freezing protocols using 1.5 M DMSO and 1.0 M 1,2 propanediol as cryoprotectants. The DMSO concentrations had an effect on survival, fertilization and embryo development using short (45 sec) but not long (2.5 min) exposure. The rate of morphological oocyte survival was significantly higher using 4.5 M DMSO than 3.5 or 6.0 M (92% vs 82 and 73%, respectively). The development of fertilized embryos to blastocysts was also significantly higher at 4.5 M than at 3.5 or 6.0 M (68% vs 42 and 53%, respectively). The extraction of cryoprotectant in 3 or 4 steps of descending sucrose concentration resulted in higher survival (P < 0.01) and fertilization than in 2 steps. The best survival, fertilization and development was achieved with the 3-step procedure. Optimal combinations of conditions were 4.5 M DMSO at 45 sec prefreeze exposure and 3-step extraction of the cryoprotectant. Oocytes frozen by conventional methods had a survival, fertilization and development to blastocyst rate significantly lower than those frozen under the optimal rapid conditions. Thus rapid freezing of mature mouse oocytes with 4.5 M DMSO + 0.5 M sucrose and short prefreeze exposure is effective and has the additional advantage of being less time-consuming than slow freezing methods.     

Effect of protective agents on amount and repair of sublethal freeze--thaw damage in mammalian cells.

Glycerol, DMSO, and HES are able to reduce by a factor of 2 the sublethal damage produced in mammalian cells after one freeze-thaw cycle. When sublethal freeze-thaw damage is already present, DMSO and HES are able to prevent about half of this damage from becoming lethal when a second freeze-thaw cycle is applied. Glycerol is only able to do this if dilution shock is avoided by thawing the cells into medium containing glycerol. The cells can repair 100% of this sublethal damage and do so in 2–3 hr at 37 °C in suspension. The data imply that the sites protected by DMSO, HES, and glycerol are the same as the sites repaired by the cells. The results also suggest that cells stop progressing in the cell cycle while repairing sublethal freeze-thaw damage.     

Frozen DON cells as a source for a cell cycle assay of antitumor agents

This study was intended to determine the feasibility of using frozen mitotic mammalian cells as a source of synchronous cultures to determine the cell cycle phase specificity of cytotoxic agents. We first found that the relative effectiveness of different additives in protecting cells during freezing was DMSO > glycerol of polyvinyl pyrolidone > sucrose > 50% serum. We also found that mitotic cells frozen in glycerol did not progress synchronously through the cell cycle when thawed. However, mitotic cells frozen in DMSO had approximately the same cell cycle time as non-frozen mitotic cells and therefore could be thawed and cultured to determine phase specific cytotoxicity of compounds. However, better results were obtained when cells frozen in different phases were used to determine phase specific toxicity of compounds. The pattern of sensitivity to cytotoxic agents of cells frozen in different phases was the same as that of the non-frozen controls.     

Cryopreservation of cell-containing poly(ethylene) glycol hydrogel microarrays

Here we describe the fabrication and preservation of mammalian cell-containing hydrogel microarrays that have potential applications in drug screening and pathogen detection. Hydrogel microstructures containing murine fibroblasts were fabricated on silicon substrates and subjected to a "stage-down" freezing process. The percent viability of both immortal and primary embryonic murine fibroblast cells within the gels was determined at various stages in the freezing process, showing that cells entrapped in hydrogel microstructures remained viable throughout the process. When compared to immortalized adherent cultures subjected to the same freezing process, cells within hydrogel structures had higher cell viabilities at all stages during preservation. Finally, the necessity of using a cryoprotectant, dimethyl sulfoxide (DMSO), was investigated. Cells in hydrogels were cryopreserved with and without DMSO. The addition of DMSO altered cell viability after the freeze-thaw process, enhancing viability in an immortalized cell line and decreasing viability in a primary cell line.     

Cryopreservation of the SB-M photosynthetic soybean [Glycine max (L.) Merr.] suspension culture

Summary The photosynthetic cell suspension culture of soybean [Glycine max (L.) Merr. cv. Corsoy] (SB-M) was successfully cryopreserved in liquid nitrogen using a preculture and controlled freezing to −40° C (two-step) freezing method. The effective method included a preculture treatment with gradually increasing levels of sorbitol added to the 3% sucrose already present in the medium. The cells were then placed in a cryoprotectant solution [10% DMSO (dimethylsulfoxide) and 9.1% sorbitol, or 10% DMSO and 8% sucrose], incubated for 30 min at 0° C, cooled at a rate of 1° C/min to −40° C, held at −40° C for 1 h, and then immersed directly into liquid nitrogen. The cells were thawed at 40° C and then immediately placed in liquid culture medium. The cell viabilities immediately after thawing were 75% or higher in all cases where cell growth resumed. The original growth rate and chlorophyll level of the cells was recovered within 40 to 47 d. If the sorbitol level was not high enough or the preculture period too short, growing cultures could not be recovered. Likewise, survival was not attained with cryoprotectant mixtures consisting of 15% DMSO, 15% glycerol, and 9.1% sucrose or 15% glycerol and 8% sucrose. The successful method was reproducible, thus allowing long-term storage of this and certain other unique photosynthetic suspension cultures in liquid nitrogen.     

Effect of an interaction between haematocrit and cryoprotectant concentration on freeze-thaw haemolysis of bovine erythrocytes.

The effect of the haematocrit and cryoprotectant concentration on freeze-thaw haemolysis of bovine red cells was studied. Two-milliliter samples of bovine blood with an haematocrit of either 20 or 60% were diluted with 2 ml of either 5, 4, 3, 2, or 1 m glycerol or DMSO in PBS or with PBS alone. The degree of haemolysis after freezing to ?79 °C and thawing was least in blood diluted with 4m cryoprotectant. At the lower concentrations of cryoprotectant, haemolysis was greater in blood with the higher haematocrit, but this effect decreased as the cryoprotectant concentration was increased and was negligible at the optimal concentration.     

Protective effect of L-glutamine against freeze-thaw damage in mammalian cells

L-Glutamine at 18 mM protects mammalian cells against freeze-thaw (FT) damage by a factor of about 6, depending on FT conditions, in balanced salt solutions. While not nearly as effective a cryoprotectant as dimethyl sulfoxide (DMSO) or propylene glycol (PG), the mechanism of protection by glutamine appears to be independent from that of DMSO or PG; thus, 18 mM glutamine is effective at reducing FT damage in combination with these agents. These combinations allow lower concentrations of the more toxic agents DMSO and PG to be used in FT medium. There is no pre-FT or post-FT effect of glutamine when cells are exposed to a FT cycle in balanced salt solutions. Hence, protection is due to its presence during the FT-cycle. The presence of 2 mM L-glutamine in Eagle's basal medium is sufficient to account for cryoprotection by this medium.     

Ca2+ transport and permeability in inside-out red cell membrane vesicles after freezing

To evaluate the effects of freezing and thawing on Ca2+ transport and permeability, inside-out red cell membrane vesicles (IORCMV) are examined. Exposure to the cryoprotectant Me2SO as well as different cooling regimes on unprotected and cryoprotected vesicles do not affect the membrane Ca2+ transport. However, freezing and thawing increase the membrane permeability to sucrose.     

The cryoprotectant used, its concentration, and the equilibration time are critical for the successful cryopreservation of rabbit sperm: Dimethylacetamide versus dimethylsulfoxide

This study was designed to identify a suitable freezing protocol for rabbit semen by comparing the effects of different concentrations and equilibration times of dimethylacetamide (DMA) and dimethylsulfoxide (DMSO) on the postthaw quality of the semen. After establishing the best protocols for each cryoprotectant, their efficacy was compared by examining the in vivo fertilizing capacity of the semen samples. Pooled semen samples diluted in freezing medium containing 4%, 6%, or 8% DMA or DMSO (all combined with 1% sucrose as a nonpermeating cryoprotectant) were loaded in straws and equilibrated for 5, 15, or 45 min before freezing in liquid nitrogen vapor. The variables assessed after thawing were sperm motility, viability, osmotic resistance, and acrosome and DNA integrity. Marked effects on these variables were shown by the cryoprotectant concentration and equilibration time, with best results obtained using DMA 6% or DMSO 8% and equilibration times of 45 min. These freezing protocols were selected to compare the two cryoprotectants in an insemination trial. Three groups of 114 rabbit does (28 nulliparous and 86 multiparous in each group) were inseminated with fresh semen or with semen frozen using the optimized DMA or DMSO protocols. Fertility rates and numbers of kids born were similar, respectively for the DMSO-frozen (79.8% and 7.7 ± 0.3 young per kindling) and fresh semen (81.6% and 8.6 ± 0.3) yet higher (P ≤ 0.05) than the rates returned using the DMA-frozen semen (47.4% and 6.7 ± 0.4). Moreover, the numbers of rabbits born alive when DMSO was used in the freezing protocol, despite being lower than those recorded using fresh semen, were higher than when DMA was used as the cryoprotectant (P < 0.05). The physiological status of the does (nulliparous or multiparous) had no influence on the fertility and prolificacy results. Our findings indicate that the cryosurvival of rabbit sperm frozen using DMSO or DMA as the cryoprotectant is highly influenced by the concentration of cryoprotectant used and the time the semen is exposed to the agent before freezing. According to our in vivo fertility and prolificacy data, DMSO emerged as more effective than DMA for the cryopreservation of rabbit sperm.     

Freeze-thaw effects on metabolic enzymes in wood frog organs.

To determine whether episodes of natural freezing and thawing altered the metabolic makeup of wood frog (Rana sylvatica) organs, the maximal activities of 28 enzymes of intermediary metabolism were assessed in six organs (brain, heart, kidney, liver, skeletal muscle, gut) of control (5 degrees C acclimated), frozen (24 h at -3 degrees C), and thawed (24 h back at 5 degrees C) frogs. The enzymes assessed represented pathways including glycolysis, gluconeo-genesis, amino acid metabolism, fatty acid metabolism, the TCA cycle, and adenylate metabolism. Organ-specific responses seen included (a) the number of enzymes affected by freeze-thaw (1 in gut ranging to 17 in heart), (b) the magnitude and direction of response (most often enzyme activities decreased during freezing and rebounded with thawing but, liver showed freeze-specific increases in several enzymes), and (c) the response to freezing versus thawing (enzyme activities in gut and kidney changed during freezing, whereas most enzymes in skeletal muscle responded to thawing). Overall, the data show that freeze-thaw implements selected changes to the maximal activities of various enzymes of intermediary metabolism and that these may aid organ-specific responses that alter fuel use during freeze-thaw, support cryoprotectant metabolism, and aid organ endurance of freeze-induced ischemia.     

Comparison of permeating and nonpermeating cryoprotectants for mouse sperm cryopreservation

Mouse sperm has proven to be more difficult to cryopreserve than sperm of other mammalian species. Published reports show that only three cryoprotectant agents (CPAs), alone or combined, have been studied: glycerol and dimethyl sulfoxide (DMSO), as permeating agents, and raffinose, as a nonpermeating agent. To date, the most consistent results for mouse sperm cryopreservation have been achieved by use of raffinose/skim milk as cryoprotectant with rapid cooling at 20 degrees C per minute. In this study, we compared the cryoprotection provided by permeating (glycerol, formamide, propanediol, DMSO, adonitol) or nonpermeating (lactose, raffinose, sucrose, trehalose, d-mannitol) compounds for freezing mouse sperm. Different solutions were made using 3% skim milk solution as the buffer or extender in which all different cryoprotectant agents were dissolved at a concentration of 0.3 M, with a final osmolality of approx. 400 mOsm. Sperm samples from CB6F1 (hybrid) and C57BL/6J (inbred) mice collected directly into each CPA were frozen/thawed under identical conditions. After thawing and CPA elimination (centrifugation) raffinose (59%), trehalose (61%), and sucrose (61%) sustained the best motility (P = < 0.1) of the nonpermeating agents, whereas the best of the permeating agents was DMSO (42%). Membrane integrity was analyzed and showed that the simple exposure (prefreeze) to sugars was less harmful than the exposure to glycols. Coincidentally, sperm frozen in trehalose (41%), raffinose (40.5%), and sucrose (37.5%) were the samples less injured among all different postthawed CPA tested. The in vitro fertilization results demonstrated that hybrid mouse spermatozoa frozen with sugars (lactose 80%, raffinose 80%, trehalose 79% of two-cell embryos production) were more fertile than those frozen with glycols (glycerol 11%).     

Development of cell line preservation method for research and industry producing useful metabolites by plant cell culture

The cell culture ofAngelica gigas Nakai producing decursin derivatives and immunostimulating polysaccharides was preserved in liquid nitrogen after pre-freezing in a deep freezer at −70°C for 480 min. The effects of the cryoprotectant and pretreatment before cooling were investigated to obtain the optimal procedure for cyropreservation. When compared to mannitol, sorbitol, or NaCl with a similar osmotic pressure, 0.7M sucrose was found to be the best osmoticum for the cryopreservation ofA. gigias cells. In the pre-culture medium, the cells in the exponential growth phase showed the best post-freezing survival after cryopre-servation. A mixture of sucrose, glycerol, and DMSO was found to be an effective cryoprotectant and a higher concentration of the cryoprotectant provided better cell viability. When compared with the vitrification, the optimum cryopreservation method proposed in this study would seem to be more effective for the long-term storage of suspension cells. The highest relative cell viability established with the optimal procedure was 89%.     

Manifestations of cell damage after freezing and thawing

The nature of the primary lesions suffered by cells during freezing and thawing is unclear, although the plasma membrane is often considered the primary site for freezing injury. This study was designed to investigate the nature of damage immediately after thawing, by monitoring several functional tests of the cell and the plasma membrane. Hamster fibroblasts, human lymphocytes, and human granulocytes were subjected to a graded freeze-thaw stress in the absence of cryoprotective compound by cooling at -1 degree C/min to a temperature between -10 and -40 degrees C, and then were either warmed directly in water at 37 degrees C or cooled rapidly to -196 degrees C before rapid warming. Mitochondrial function in the cells was then assessed using 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyl-tetrazolium bromide (MTT), fluorescein diacetate (FDA), colony growth, and osmometric response in a hypertonic solution. Cells behaved as osmometers after cooling at -1 degree C/min to low temperatures at which there were no responses measured by other assays, indicating that the plasma membrane is not a primary site for injury sustained during slow cooling. These results also indicate that the FDA test does not measure membrane integrity, but reflects the permeability of the channels through which fluorescein leaves the cells. Fewer cells could respond osmotically after cooling under conditions where intracellular freezing was likely, implying that the plasma membrane is directly damaged by the conditions leading to intracellular freezing. A general model of freezing injury to nucleated mammalian cells is proposed in which disruption of the lysosomes constitutes the primary lesion in cells cooled under conditions where the cells are dehydrated at low temperatures.     

Freezing of isolated thylakoid membranes in complex media. VIII. Differential cryoprotection by sucrose, proline and glycerol

The cryoprotective efficiency of sucrose, proline and glycerol for chloroplast membranes isolated from spinach leaves ( Spinacia oleracea L. cv. Monatol) was determined after freeze-thaw treatment in media containing the predominant inorganic electrolytes of the chloroplast stroma. In most cases, the protective capacity of equimolar concentrations of the cryoprotectants followed the order sucrose > proline > glycerol. The lower the freezing temperature the less cryoprotectant was necessary for comparable preservation of the capacity of photosynthetic electron transport. Likewise, the cryoprotective efficiency of sucrose for cyclic photophosphorylation and light-induced proton gradient increased with decreasing freezing temperature. In contrast, while proline effectively stabilized these membrane reactions at mild and moderate freezing temperatures, it was much less efficient at more severe freezing stress. Cryoprotection of photophosphorylation and proton gradient formation at given initial concentrations of glycerol was largely independent of the freezing temperature. While dissociation of the peripheral part of chloroplast coupling factor (CF₁) during freeze-thaw treatment cannot be prevented in the presence of lower initial concentrations of proline and glycerol and. at mild freezing temperatures, of sucrose, the latter may stabilize this protein complex at least under more severe freezing conditions. The differences in the cryoprotective efficiency of the solutes are discussed relative to their non-ideal activity-concentration profiles, solution properties and penetration behaviour across the thylakoid membrane.     

Changes in the erythrocyte membrane-cytoskeleton complex induced by dimethyl sulfoxide, polyethylene glycol, and low temperature

The effect of the cryoprotectants DMSO and PEG-1500 as well as freezing-thawing on the proteins of the canine erythrocyte membrane-cytoskeleton complex was studied using the cross-linking agent diamide. It was shown that the intensity of disturbances in the protein network structure correlated with the increased SH-group accessibility for oxidative bridging by this compound and accordingly, enhanced formation of high-molecular-weight protein aggregates. The maximum level of diamide-induced aggregability was revealed upon freezing of erythrocytes in liquid nitrogen without cryoprotectant. Electrophoretic analysis of the ghosts of erythrocytes incubated with cryoprotectants showed a significant increase in the aggregation level only for the cells in the polymer solution. After the freezing-thawing cycle, the diamide-induced protein aggregability in erythrocytes cryopreserved with PEG-1500 strongly increased; when DMSO was used for cell protection, the aggregation was much less pronounced than in the unprotected cells. One can suppose that the exocellular cryoprotectant PEG-1500, as distinct from the endocellular cryoprotectant DMSO, is unable to provide for preservation of the structure of the membrane-cytoskeleton protein complex at a level necessary for the maintenance of cell integrity after the return to physiological conditions.     

The use of TTC reduction assay for assessment of Gentiana spp. cell suspension viability after cryopreservation

This study was aimed at improving the 2,3,5-triphenyl-tetrazoliumchloride (TTC) reduction test for initial assessment of cell survival after cryopreservation. Experiments were carried out on three embryogenic cell suspensions of different ages: 9-year-old Gentiana tibetica (King ex Hook. F.), 2-year-old G. kurroo (Royle), and 1-year-old G. cruciata (L.). The suspensions were maintained in MS medium supplemented with 1.0 mg 1⁻¹ 3,6-dichloro-o-anisic acid, 0.1 mg 1⁻¹ naphthaleneacetic acid, 2.0 mg l⁻¹ 6-benzylaminopurine, 80.0 mg 1⁻¹ adenine sulphate and 0.09 M sucrose. Four weeks before freezing, part of the tissue was subcultured to the same medium with sucrose concentrations elevated from 0.09 M (3%sMS) to 0.175 M (6%sMS) or 0.26 M (9%sMS). In freezing treatments without cryoprotection, tissue was plunged directly into liquid nitrogen (LN) or cooled gradually. In freezing treatments with cryoprotection, the cells were pretreated with 1 M sucrose, or with 0.4 M sorbitol + 0.25 M proline or + 0.08 M DMSO, or with vitrification solution (PVS2). Encapsulation was another variant. TTC reduction activity was spectrophotometrically assessed immediately, 1, 3, 5, 24 and 48 h after thawing. Cells without cryoprotection were lethally damaged, but TTC reduction activity in those cells ranged from 6.5% (tissue from 3%sMS) to 73 % (tissue from 9%sMS) directly after thawing. Formazan production was reduced to zero after 24 h. The TTC test showed 50% formazan content immediately after thawing of DMSO-protected G. tibetica tissue, but only 22.47% after 24 h and 2.9% after 48 h. Ultrastructural analysis of those cells showed lethal damage in many of them. For the PVS2 treatment, the formazan content was similar in samples analyzed directly after thawing and 24 h later. Cells treated with PVS2 did not show structural disturbances. Encapsulated cell aggregates of G. cruciata treated with concentrations of sucrose increasing up to 1 M produced 2.6 times more formazan. When applied at least 48 h after thawing, the TTC test can reflect cell viability and can be used to compare the effectiveness of cryoprotectant performance and freezing protocols, but it must be carefully evaluated, with appropriate controls.     

Ultrastructure-function correlative studies for cardiac cryopreservation. V. Absence of a correlation between electrolyte toxicity and cryoinjury in the slowly frozen,cryoprotected rat heart

Hearts were frozen to ?17 °C in the initial presence of 2.1 m DMSO. Attempts were made to prevent or minimize the consequences of an osmotic shock based on Lovelock's classical hypothesis of freezing injury. Substitution of mannitol or potassium for NaCl before freezing did not improve the results, nor did perfusion of thawed hearts with hyperosmotic perfusate. It was found that freezing and thawing resulted in a significant attenuation of coronary flow and that, as a result of this, DMSO was apparently retained within the heart after thawing. DMSO was also difficult to remove at 30 °C in the absence of prior freezing and caused a significant drop in coronary flow upon institution of DMSO washout with balanced salt solution. The blanching of freezing and thawing was also seen, in milder form, in nonfrozen hearts. For both frozen-thawed and nonfrozen hearts, the blanching was associated with DMSO washout with balanced salt solution. Flow was improved by perfusion with hyperosmotic perfusate in both nonfrozen and in frozen-thawed hearts, but the improvement was largely temporary. Evidence from earlier studies indicates that electrolyte concentrations during freezing cannot be correlated with cardiac cryoinjury, in support of the present findings. It is suggested instead that cryoprotectant toxicity may be the chief agent of injury under the conditions studied.     

Hemolysis of human red blood cells by freezing and thawing in solutions containing sucrose: relationship with posthypertonic hemolysis and solute movements

Human red blood cells were frozen at temperatures down to ?9 °C in solutions containing sucrose, and the hemolysis on thawing was measured. This was compared with the hemolysis caused by exposing the cells to high concentrations of sucrose and then resuspending them in more dilute solutions at 4 °C. The effects of the hypertonic solutions of sucrose on potassium, sodium, and sucrose movements were also investigated. It was found that sucrose does not prevent damage to the cells by very hypertonic solutions (whether during freezing and thawing or at 4 °C) but it does reduce hemolysis of cells previously exposed to these solutions if present in the resuspension (or thawing) solution. Evidence is presented that the damaging effects of the hypertonic solutions of sucrose occurring during freezing are associated with changes in cell membrane permeability but that posthypertonic hemolysis is not primarily associated with a “loading” of the cells with extracellular solutes in the hypertonic phase. It is concluded that sucrose may reduce hemolysis of red blood cells by slow freezing and thawing by reducing colloid osmotic swelling of cells with abnormally permeable membranes.     

A non-BRICHOS surfactant protein c mutation disrupts epithelial cell function and intercellular signaling

Background

Cryopreservation is the only widely applicable method of storing vital cells for nearly unlimited periods of time. Successful cryopreservation is essential for reproductive medicine, stem cell research, cord blood storage and related biomedical areas. The methods currently used to retrieve a specific cell or a group of individual cells with specific biological properties after cryopreservation are quite complicated and inefficient.

Results

The present study suggests a new approach in cryopreservation, utilizing the Individual Cell-based Cryo-Chip (i3C). The i3C is made of materials having appropriate durability for cryopreservation conditions. The core of this approach is an array of picowells, each picowell designed to maintain an individual cell during the severe conditions of the freezing - thawing cycle and accompanying treatments. More than 97% of cells were found to retain their position in the picowells throughout the entire freezing - thawing cycle and medium exchange. Thus the comparison between pre-freezing and post-thawing data can be achieved at an individual cell resolution. The intactness of cells undergoing slow freezing and thawing, while residing in the i3C, was found to be similar to that obtained with micro-vials. However, in a fast freezing protocol, the i3C was found to be far superior.

Conclusions

The results of the present study offer new opportunities for cryopreservation. Using the present methodology, the cryopreservation of individual identifiable cells, and their observation and retrieval, at an individual cell resolution become possible for the first time. This approach facilitates the correlation between cell characteristics before and after the freezing - thawing cycle. Thus, it is expected to significantly enhance current cryopreservation procedures for successful regenerative and reproductive medicine.     

Ultrastructural changes of Trichomonas vaginalis prior and after cryopreservation

Fine structural changes of Trichomonas vaginalis are described prior and after the freezing process in liquid nitrogen. Dimethyl sulfoxide (DMSO) used as the cryoprotectant caused distinct alterations of the cytoplasm when trichomonads were equilibrated with 5% DMSO under various experimental conditions. Changes were bubble-like protrusions, fissuration and/or vacuolation of the cytoplasm, doubling and removal or/and rupture of the cell membrane. Apart from these findings cryopreservation caused marked alterations on the hydrogenosomes, such as condensation and flocculence of the usually homogeneous contents; in addition numerous hydrogenosomes fused while loosing membrane at the site of fusion. However, several parasites revealed normal hydrogenosomes after the freezing process. It is assumed that these organisms survived freezing and thawing as demonstrated by successful cultivation of recovered trichomonads.