Improved functional recovery of human granulocytes after cryopreservation

Human peripheral blood phagocytes (90% neutrophils) were cryopreserved with either 5 or 10% dimethyl sulfoxide (DMSO) and stored in the liquid phase of liquid nitrogen. Modifications to the freezing method included the elimination of dextran from the freezing medium, addition of the bulk of the DMSO at −5 °C, elimination of heparin and centrifugation from all postreconstitution procedures, and the use of deoxyribonuclease to minimize post-thaw granulocyte agglutination.Substantial numbers of the cryopreserved phagocytes, as assayed by nitroblue tetrazolium and chemotactic activity, showed comparable functional activity to fresh cells. Post-thaw cell dialysis further improved functional capacity although probably not as a consequence of DMSO removal.     

Long-term cryopreservation of mouse sperm

The objective was to determine if mouse sperm can maintain their fertilizing ability after being frozen for >10 y and whether the offspring derived from these sperm had normal fertilizing ability and phenotype. We cryopreserved sperm from six strains of mice (C57BL/6J, DBA/2N, BALB/cA, C3H/HeJ, B6D2F1 and B6C3F1) in a solution containing 18% (w/v) raffinose and 3% (w/v) skim milk, and preserved them in liquid nitrogen for >10 y. To assess the normality and fertilizing ability of these sperms, they were thawed and used for in vitro fertilization of oocytes of the same strains. Fertilization rates for C57BL/6J, DBA/2N, BALB/cA, C3H/HeJ, B6D2F1 and B6C3F1 were 66.4, 92.3, 72.8, 32.9, 60.3 and 53.7%, respectively. Furthermore, 38.3, 15.0, 43.3, 26.1, 38.3 and 16.7% of the embryos transferred to pseudopregnant females developed and produced live offspring that had normal phenotype and fertility.     

Investigating the potential for cryopreservation of human granulocytes with concentrated glycerol

The purpose of this study was to investigate the potential for cryopreservation of granulocytes using 30% glycerol. Recently reported permeability data was used to design two different methods for addition and removal of glycerol: a fast method that is predicted to keep cell volumes between 80% and 150% of the isotonic volume and a slow method that is predicted to keep cell volumes between 80% and 115% of the isotonic volume. The fast method resulted in cell recoveries of 31% ± 9% and 11% ± 3% before and after freezing, respectively, whereas the slow method resulted in even lower cell recoveries of 5% ± 2% and 4% ± 2%. The reduced cell recovery for the slow method is consistent with an increase in damage as a result of glycerol toxicity. Our results suggest that cryopreservation of granulocytes in concentrated glycerol is not feasible.     

Long-term cryopreservation of sperm of Japanese eel

After cryopreservation in a diluent (D#5-D), containing 76·2 mM NaHCO3, 137·0 mM NaCl, 1·4% soya lecithin and 10% dimethyl sulphoxide, for 30–180 days, Japanese eel Anguilla japonica sperm was 61·4–70·6% motile compared with fresh sperm. Cryopreserved sperm was used for fertilizing three batches of eggs and hatchability ranged from 20·7 to 69·1%. These results indicate that D#5-D is an useful diluent for sperm cryopreservation in Japanese eel.     

Metabolic changes in dog kidney during cryopreservation

The degree of edema occurring in dog kidneys after perfusion with cryoprotector-containing electrolyte medium is illustrated by the reduction in cellular protein, DNA, and RNA concentration. Perfusion alone only slightly affects the metabolic activities. After slow cooling and preservation at −196 °C, the amino acid incorporation into the proteins of cortex and to a lesser degree of medulla, is considerably inhibited. In identical conditions the membrane transport functions seem to be more successfully protected. The thymidine incorporation into DNA can even be stimulated, but this may be a detrimental irritatory factor since it is accompanied by reduced protein synthesizing activity. By accelerating the cooling rate, cryoinjury increased alarmingly without affecting the incorporation of thymidine into DNA. It is concluded that even if vascular problems have prevented the successful cryopreservation of complex mammalian structures up to now, the degree to which metabolic activities can be protected is promising for further development.     

Long-term and transgenerational effects of cryopreservation on rabbit embryos

The short-term effects of cryopreservation and embryo transfer are well documented (reduced embryo viability, changes in pattern expression), but little is known about their long-term effects. We examined the possibility that embryo vitrification and transfer in rabbit could have an impact on the long-term reproductive physiology of the offspring and whether these phenotypes could be transferred to the progeny. Vitrified rabbit embryos were warmed and transferred to recipient females (F0). The offspring of the F0 generation were the F1 generation (cryopreserved animals). Females from F1 generation offspring were bred to F1 males to generate an F2 generation. In addition, two counterpart groups of noncryopreserved animals were bred and housed simultaneously to F1 and F2 generations (CF1 and CF2, respectively). The reproductive traits studied in all studied groups were litter size (LS), number born alive at birth (BA), and postnatal survival at Day 28 (number of weaned/number born alive expressed as percentage). The reproductive traits were analyzed using Bayesian methodology. Features of the estimated marginal posterior distributions of the differences between F1 and their counterparts (F1 − CF1) and between F2 and their counterparts (F2 − CF2) in reproductive characters found that vitrification and transfer procedures cause a consistent increase in LS and BA between F1 and CF1 females (more than 1.4 kits in LS and more than 1.3 BA) and also between F2 and CF2 females (0.96 kits in LS and 0.94 BA). We concluded that embryo cryopreservation and transfer procedures have long-term effects on derived female reproduction (F1 females) and transgenerational effects on female F1 offspring (F2 females).     

Long-term cryopreservation of sperm from Mandarin fish Siniperca chuatsi

In order to develop cryopreservation techniques for long-term preserving the sperm of Mandarin fish Siniperca chuatsi, we examined the effects of various extender and cryopreservation on post-thaw motility. We found the optimal freezing procedures for the Mandarin fish sperm is diluting the semen in D-15 extender, chilling it to 4 degrees C, adding ME2SO to a final concentration of 10% (v/v), then transferring the semen in cryotubes, holding the cryotubes for 10 min at 6 cm (about -180 degrees C) above the surface of liquid nitrogen, for 5 min on the surface of liquid nitrogen, and finally plunged into liquid nitrogen. After thawed at 37 degrees C for 60s, the sperm had the highest post-thaw motility (96.00+/-1.73%). The optimal fertilization procedures for the frozen sperm is mixing the eggs with sperm, then adding 1 ml of swimming medium (SM=45 mM NaCl+5 mM KCl+20mM Tris-HCl, pH 8.0) immediately. At the sperm/egg ratio of 100,000:1, the fertilization rate and the hatching rate of the frozen sperm cryopreserved for 1 week or 1 year in liquid nitrogen (66.01+/-5.14% and 54.76+/-4.40% & 62.97+/-14.28% and 52.58+/-11.17%) were similar to that of fresh sperm (69.42+/-8.11% and 59.82+/-5.27%) (p>0.05). This is the first report that the Mandarin fish (S. chuatsi) sperm can successfully fertilized eggs after long-term cryopreservation.     

Long-term maintenance of Pinus nigra embryogenic cultures through cryopreservation

Embryogenic tissues of Pinus nigra have been cryopreserved using a two step slow-freezing method. In the first experiment, 20 cell lines were included and the effect of the duration of cryostorage (1 h vs. 1 year) on regrowth was compared. After a short-term storage (1 h in liquid nitrogen, LN) out of 20 cell lines tested 15 showed regrowth (75%) with individual frequencies 10–100%. Long term storage (1 year in LN) resulted in regrowth of 14 cell lines (70%) while the individual frequencies reached 10–100%. One year storage had no negative influence on the fresh mass accumulation evaluated 2–3 months after thawing. Another 20 cell lines were included in the second experiment with the aim to study the correlation between cryotolerance and maturation capacity of cell lines. Between maturation capacity and cryotolerance expressed as regrowth frequencies of individual cell lines, no correlation has been found.     

Comparison between glycerol and ethylene glycol for dog semen cryopreservation

The aim of this study was to compare the effect of ethylene glycol versus glycerol for dog semen freezing, on post-thaw longevity, motility and motility parameters, and on plasma membrane functional integrity. Semen was diluted in two steps with an egg yolk TRIS extender containing a final concentration of either 5% glycerol or 5% ethylene glycol, and frozen in 0.5 ml straws, with 100 x 10(6) spermatozoa/ml, over nitrogen vapours. Semen motility was evaluated both under a light microscope and with a Computer Assisted Motility Analyser System, immediately after thawing and then hourly till 4h of incubation. Sperm membrane functional integrity was assessed with the hypoosmotic swelling test (60 mOsm fructose solution) applied at thawing and then hourly, for 4 h, on incubated samples. Motility (light microscope) and total and progressive motility (analyser) were significantly higher in ethylene glycol frozen samples at thawing (P < 0.01); from hour 1 onwards the effect of the cryoprotectant became not significant. Semen frozen with ethylene glycol showed higher path velocity and higher straight line velocity till 3 h after thawing; however, ethylene glycol semen samples also showed higher curvilinear velocity and higher lateral head displacement, which may indicate a capacitation-like condition affecting sperm membranes and possibly reducing post-thaw longevity. Functional integrity of plasma membrane was similar in glycerol and ethylene glycol samples till 3 h after thawing, then ethylene glycol samples showed a higher decline. The strong though short-lived positive effect of ethylene glycol is worth being evaluated further.     

Long-term effects of cryopreservation on clinically prepared hematopoietic progenitor cell products

Background aimsThe question of how long hematopoietic progenitor cells (HPCs) destined for clinical applications withstand long-term cryopreservation remains unanswered. To increase our basic understanding about the stability of HPC products over time, this study focused on characterizing long-term effects of cryopreservation on clinically prepared HPC products.MethodsCryovials (n = 233) frozen for an average of 6.3 ± 14.2 years (range, 0.003–14.6 years) from HPC products (n = 170) representing 75 individual patients were thawed and evaluated for total nucleated cells (TNCs), cell viability, viable CD34+ (vCD34+) cells and colony-forming cells (CFCs). TNCs were determined by use of an automated cell counter, and cell viability was measured with the use of trypan blue exclusion. Viable CD34 analysis was performed by means of flow cytometry and function by a CFC assay.ResultsSignificant losses in TNCs, cell viability, vCD34+ cells and CFC occurred on cryopreservation. However, once frozen, viable TNCs, vCD34+ cells and CFC recoveries did not significantly change over time. The only parameter demonstrating a change over time was cell viability, which decreased as the length of time that an HPC product was stored frozen increased. A significant negative correlation (correlation coefficient = −0.165) was determined between pre-freeze percent granulocyte content and post-thaw percent viability (n = 170; P = 0.032). However, a significant positive correlation was observed between percent viability at thaw and pre-freeze lymphocyte concentration.ConclusionsOnce frozen, HPC products were stable for up to 14.6 years at <−150°C. Post-thaw viability was found to correlate negatively with pre-freeze granulocyte content and positively with pre-freeze lymphocyte content.     

Recovery,structure, and function of dog granulocytes after freeze-preservation with dimethylsulfoxide

The recovery, structure and function of dog granulocytes were determined before and after freeze-preservation. Leucocytes were isolated from defibrinated or anti-coagulated whole blood and subsequent erythrocyte sedimentation on a column of 2:1 dextran (6%)-isopaque (33.9%). Granulocytes isolated by these procedures were examined for changes in O₂ consumption associated with phagocytosis, in vitro directed migration (chemotaxis), bactericidal activity, and ultrastructure before and after freezing. Granulocytes were frozen in DMSO (7.5%) and autologous serum or HBSS-minus and 20% autologous serum at the rate of ?1 °C/min to ?80 °C and stored in liquid N₂ vapor.After freeze-preservation, O₂ consumption associated with phagocytosis was decreased by 54 and 64% for granulocytes isolated from defibrinated or from ACD-anticoagulated blood, respectively. Bactericidal activity is only slightly depressed in samples from either isolation method after freeze-preservation when compared to the prefreeze controls, but granulocytes isolated from defibrinated blood are significantly less effective in killing bacteria than those from ACD-anticoagulated blood. Chemotactic response after freeze-preservation was completely inhibited in granulocytes isolated from defibrinated blood. Exposure of granulocytes to ACD inhibited chemotaxis prior to freezing, but the granulocytes responded chemotactically after freeze-thaw and additional washing. The ultrastructure of granulocytes observed before and after freeze-thaw was similar for cells isolated by both methods. However, nuclear, cytoplasmic, and granular changes observed were slightly greater in granulocytes isolated from defibrinated blood. Dog granulocytes isolated by either method withstood freeze-preservation in DMSO to a degree not previously reported.It is concluded that dog granulocytes freeze-preserved by these methods are functional in vitro, but that phagocytic, directed migration, and bactericidal functions and ultrastructure are impaired to different degrees, according to the method of isolation and preparation for storage. These results indicate the need for continued investigation on the effects of storage variables on the preservation of granulocytes.     

Long-term cryopreservation of reaggregated pancreatic islets resulting in successful transplantation in rats

Preservation of pancreatic islets for long-term storage of islets used for transplantation or research has long been a goal. Unfortunately, few studies on long-term islet cryopreservation (1 month and longer) have reported positive outcomes in terms of islet yield, survival and function. In general, single cells have been shown to tolerate the cryopreservation procedure better than tissues/multicellular structures like islets. Thus, we optimized a method to cryopreserve single islet cells and, after thawing, reaggregated them into islet spheroids. Cryopreserved (CP) single human islet cells formed spheroids efficiently within 3–5 days after thawing. Approximately 79% of islet cells were recovered following the single-cell cryopreservation protocol. Viability after long-term cryopreservation (4 weeks or more) was significantly higher in the CP islet cell spheroids (97.4 ± 0.4%) compared to CP native islets (14.6 ± 0.4%). Moreover, CP islet cell spheroids had excellent viability even after weeks in culture (88.5 ± 1.6%). Metabolic activity was 4–5 times higher in CP islet cell spheroids than CP native islets at 24 and 48 h after thawing. Diabetic rats transplanted with CP islet cell spheroids were normoglycemic for 10 months, identical to diabetic rats transplanted with fresh islets. However, the animals receiving fresh islets required a higher volume of transplanted tissue to achieve normoglycemia compared to those transplanted with CP islet cell spheroids. By cryopreserving single cells instead of intact islets, we achieved highly viable and functional islets after thawing that required lower tissue volumes to reverse diabetes in rats.     

The influence of cryopreservation and seminal plasma on the chromatin structure of dog spermatozoa

It was the aim of the current study to investigate effects of seminal plasma on the chromatin structure of frozen-thawed canine (Canis lupus familiaris) spermatozoa. A total of 20 ejaculates were collected. Ejaculates were divided, and one half was centrifuged for removal of seminal plasma (c) while the other was left uncentrifuged (nc) before cryopreservation. This was performed according to the Uppsala system in a computerized freezing machine. Before freezing (bf) and after thawing (at), samples were investigated for motility (M), viability (CASA), and chromatin status (sperm chromatin structure assay; SCSA). Before freezing, the average DFI% and the SD-DFI from 20 nc ejaculates were 1.7 ± 4.0% and 18.6 ± 1.2, respectively. After thawing, all motility parameters decreased and were significantly lower in centrifuged than in noncentrifuged samples, whereas the percentage of morphologically abnormal spermatozoa (Morph) was significantly higher (nc: M bf, 84.1 ± 20.6%; M at, 51.9 ± 15%; c: M bf, 84.1 ± 20.6%; M at, 43.3 ± 22.2%; Morph nc: 28.3 ± 7.8% vs. c: 31.0 ± 9.8%). Furthermore, only in c samples did the DFI increase within 6 h after thawing (DFI c: bf, 41.8 ± 1.5%; 6 h at, 45.4 ± 6.6%; P < 0.01). The SD-DFI as well as the DFI% increased within 3 h of storage in both groups (SD-DFI nc: bf, 18.6 ± 1.2%; 3 h at, 25.8 ± 5.4%; DFI% nc: bf, 1.1 ± 4.0%; 3 h at, 6.1 ± 12.9%; P < 0.05). For both parameters, there was no significant difference between c and nc samples at any time investigated. In conclusion, centrifugation of semen samples before freezing decreased postthaw motility and increased the percentage of morphologically abnormal spermatozoa as well as the degree of sperm chromatin denaturation over time. Centrifugation of canine ejaculates before cryopreservation can therefore no longer be recommended.     

The influence of cryopreservation and seminal plasma on the chromatin structure of dog spermatozoa

It was the aim of the current study to investigate effects of seminal plasma on the chromatin structure of frozen-thawed canine (Canis lupus familiaris) spermatozoa. A total of 20 ejaculates were collected. Ejaculates were divided, and one half was centrifuged for removal of seminal plasma (c) while the other was left uncentrifuged (nc) before cryopreservation. This was performed according to the Uppsala system in a computerized freezing machine. Before freezing (bf) and after thawing (at), samples were investigated for motility (M), viability (CASA), and chromatin status (sperm chromatin structure assay; SCSA). Before freezing, the average DFI% and the SD-DFI from 20 nc ejaculates were 1.7 ± 4.0% and 18.6 ± 1.2, respectively. After thawing, all motility parameters decreased and were significantly lower in centrifuged than in noncentrifuged samples, whereas the percentage of morphologically abnormal spermatozoa (Morph) was significantly higher (nc: M bf, 84.1 ± 20.6%; M at, 51.9 ± 15%; c: M bf, 84.1 ± 20.6%; M at, 43.3 ± 22.2%; Morph nc: 28.3 ± 7.8% vs. c: 31.0 ± 9.8%). Furthermore, only in c samples did the DFI increase within 6 h after thawing (DFI c: bf, 41.8 ± 1.5%; 6 h at, 45.4 ± 6.6%; P < 0.01). The SD-DFI as well as the DFI% increased within 3 h of storage in both groups (SD-DFI nc: bf, 18.6 ± 1.2%; 3 h at, 25.8 ± 5.4%; DFI% nc: bf, 1.1 ± 4.0%; 3 h at, 6.1 ± 12.9%; P < 0.05). For both parameters, there was no significant difference between c and nc samples at any time investigated. In conclusion, centrifugation of semen samples before freezing decreased postthaw motility and increased the percentage of morphologically abnormal spermatozoa as well as the degree of sperm chromatin denaturation over time. Centrifugation of canine ejaculates before cryopreservation can therefore no longer be recommended.     

Dispersed pancreatic graft cryopreservation in the dog: in vivo assessment of preservation protocols

Dispersed canine pancreatic grafts were cryopreserved and the in vivo function was studied following intrasplenic autotransplantation. Four protocols were employed, examining the effects of cooling and thawing rates and cryoprotectant (dimethylsulfoxide) concentration on graft survival. The degree of graft injury by each protocol was assessed by examining the requirement for exogenous insulin following transplantation. Cooling at 5 degrees C/min and thawing at 80 degrees C/min allowed three successful grafts from seven when thawed at 80 degrees C/min using 1.4 or 2 M Me2SO but only one success from eight when thawed at 8 degrees C/min. Of the seven experiments where successful preservation was achieved graft injury was estimated as less than 50% in four but for three it was probably greater than 50%. Each protocol exhibited considerable variability of islet survival. When sufficient islet mass was transplanted to restore fasting euglycaemia, graft function, as assessed by glucose-stimulated insulin release and intravenous glucose disposal, was identical to fresh grafts. Successful graft implantation, however, does not guarantee indefinite survival as six of seven grafts in this study became exhausted within 13 months of implantation.     

Liquid and cryopreservation effects on in vitro function of dog granulocyte concentrates prepared for transfusion

The effects of liquid and Cryopreservation on in vitro function of dog granulocyte concentrates prepared by continuous flow centrifugation leukapheresis and counterflow centrifugation elutriation are presented. These homogeneous granulocyte concentrates (97 ± 2% granulocytes, 99.4 ± 0.3% viable) were cryopreserved in 5% DMSO and 5% HES dissolved in 2 g% BSA, 20% autologous citrated plasma in a modified a minimal essential medium. The granulocyte recovery was 87.6 ± 2.4% relative to the number of intact and viable granulocytes in the washed suspension of cells. In vitro functions of chemotaxis, phagocytosis, bactericidal activity, and selected enzymes were not affected by 12–24 hr storage at 4–6 °C. Frozen, thawed, and washed granulocytes showed a significant decrease (P < 0.01) in chemotactic recognition and response but not chemokinetic response, although it was depressed. Phagocytosis of latex beads and associated burst of O₂ consumption also decreased significantly (P < 0.05) to approximately 50% of the original prefreezing value. However, the killing of live Escherichia coli was not depressed to the extent expected and suggested by loss of O₂ consumption and selected enzyme activity. The cryopreservation of viable homogeneous granulocyte concentrates in sufficient quantity for transfusion in the neutropenic and/or septicemic dog model is demonstrated in these results.     

Long-term cryopreservation of Greek fir embryogenic cell lines: recovery, maturation and genetic fidelity

In coniferous species, including Greek fir (Abies cephalonica Loud), the involvement of somatic embryo plants in breeding and reforestation programs is dependent on the success of long-term cryostorage of embryogenic cultures during clonal field testing. In the present study on Greek fir, we assayed the recovery, morphological characteristics and genetic fidelity of embryogenic cell lines 6 and 8 during proliferation and maturation after long-term cryostorage. Our results indicate successful recovery of both cell lines after 6 years in cryostorage. In the maturation phase, both cell lines were capable of producing somatic embryos although some differences were detected among experiments. However, these changes were more dependent on the differences in the components of the maturation media or in the experimental set-up than on the long-term cryostorage. During both proliferation and maturation phases, the morphological fidelity of the embryogenic cultures as well as of the somatic embryos were alike before and after cryopreservation. The genetic fidelity of the cryopreserved cell line 6 that was assayed by random amplified polymorphic DNA (i.e. RAPD) markers demonstrated some changes in the RAPD profiles. The results indicate possible genetic aberrations caused by long-term cryopreservation or somaclonal variation during the proliferation stage. However, in spite of these changes the embryogenic cultures did not lose their proliferation or maturation abilities.