Xenotransplantation of cryopreserved composite organs on the rabbit

Nowadays, It is easy to define optimal conditions (cryoprotective agent, speed and steps of freezing, speed of warming) for the cryopreservation of a homogeneous cell population or a one cell-layer tissue. Meanwhile, It is still hard to obtain cryopreservation of composite organs. Each tissue has its own requirements and its own reactivity to the cryopreservation process. The challenge consists of, on the one hand, to select the ideal combination of cryoprotective agents that can fit the needs of the different tissues, and the definition of adequate technical parameters, on the other hand. All the experimental trials have studied the survival rate of non-vascularized cryopreserved tissues. The aim of our experimental work is to demonstrate the feasibility of cryopreserving a composite organ with its nutrient vessels “artery and veins” in order after thawing to revitalize it by reestablishing the blood irrigation by microsurgical vascular anastomosis. We report our experimental results on the cryopreservation of composite organs - amputated digits - xenotransplanted in the rabbit. Digital segments were cryopreserved, then revitalized after warming using vascular microsurgical techniques. Preliminary results are encouraging and may pave the way in the future to the microvascular allotransplantation of cryopreserved composite organs.     

The cryopreservation of composite tissues

Cryopreservation of human cells and tissue has generated great interest in the scientific community since 1949, when the cryoprotective activity of glycerol was discovered. Nowadays, it is possible to reach the optimal conditions for the cryopreservation of a homogeneous cell population or a one cell-layer tissue with the preservation of a high pourcentage of the initial cells. Success is attained when there is a high recovery rate of cell structures and tissue components after thawing. It is more delicate to obtain cryopreservation of composite tissues and much more a whole organ. The present work deals with fundamental principles of the cryobiology of biological structures, with special attention to the transfer of liquids between intra and extracellular compartments and the initiation of the formation and aggregation of ice during freezing. The consequences of various physical and chemical reactions on biological tissue are described for different cryoprotective agents. Finally, we report a review of results on cyropreservation of various tissues, on the one hand, and various organs, on the other. We also report immunomodulation of antigenic responses to cryopreserved cells and organs.     

The cryopreservation of composite tissues: Principles and recent advancement on cryopreservation of different type of tissues

Cryopreservation of human cells and tissue has generated great interest in the scientific community since 1949, when the cryoprotective activity of glycerol was discovered. Nowadays, it is possible to reach the optimal conditions for the cryopreservation of a homogeneous cell population or a one cell-layer tissue with the preservation of a high pourcentage of the initial cells. Success is attained when there is a high recovery rate of cell structures and tissue components after thawing. It is more delicate to obtain cryopreservation of composite tissues and much more a whole organ. The present work deals with fundamental principles of the cryobiology of biological structures, with special attention to the transfer of liquids between intra and extracellular compartments and the initiation of the formation and aggregation of ice during freezing. The consequences of various physical and chemical reactions on biological tissue are described for different cryoprotective agents. Finally, we report a review of results on cyropreservation of various tissues, on the one hand, and various organs, on the other. We also report immunomodulation of antigenic responses to cryopreserved cells and organs.     

Perfusion bioreactor-based cryopreservation of 3D human mesenchymal stromal cell tissue grafts

The generation of an off-the-shelf in vitro engineered living tissue graft will likely require cryopreservation. However, the efficient addition and removal of cryoprotective agents (CPA) to cells throughout the volume of a three-dimensional (3D) tissue graft remains a significant challenge. In this work, we assessed whether a perfusion bioreactor-based method could be used to improve the viability of cryopreserved mesenchymal stromal cell- (MSC) based tissue constructs as compared to using conventional diffusion-based methods. The bioreactor was first used to saturate 3D constructs with CPA under perfused flow. Following cryopreservation, the bioreactor was then also used for the efficient removal of the CPA from the 3D tissues. We demonstrate that addition and removal of CPA under perfused flow significantly increased the viability of MSC within cryopreserved 3D tissue constructs as compared to conventional diffusion-based methods.     

Cryopreservation and transplantation of amputated finger

Every year tens of millions reconstruction surgeries were performed to repair tissue defects caused by trauma or malignant tumor. As the composite tissues are very difficult to be preserved for a long time in vitro, “organ bank” was proposed. In addition to immune rejection, tissue cryopreservation is the key step of the “Organ Bank”. In this study, two severed fingers were cryopreserved because the patients’ conditions were not allowed to undergo the replantation immediately. The fingers were perfused with the cryopreservation solution through the digital artery at a speed of 1 ml/min, they were frozen following a control rate freezing procedure and stored in the liquid nitrogen. One finger was cryopreserved for 10 days and the other for 30 days. Both fingers were successfully replanted when the patient get better. After 1 year follow-up, the replanted fingers achieved satisfactory appearance and function. Our result demonstrate small composite tissues such as severed fingers can be cryopreserved and replanted successfully, which will help the patients who cannot receive the replantation immediately. This method will have important application value in cryobiology and clinical medicine.     

Influence of cryopreservation on the pulpal tissue of immature third molars in vitro

The purpose of this study was to evaluate in vitro the viability of isolated and non-isolated pulpal tissue of immature third molars after cryopreservation. This study was divided in three different experiments. Experiment 1: Pulpal tissue isolated from 19 third molars was divided in horizontal segments. Each segment was cultured separately in order to evaluate whether differences in growth capacity within the tissue could be found. Experiment 2: Pulpal tissue isolated from 27 third molars was divided in a mesial and a distal part. One part was cryopreserved before culturing, the other part was cultured immediately. Growth capacity of cryopreserved and non-cryopreserved tissue was evaluated and compared. Experiment 3: 43 third molars were cryopreserved. After thawing, the dimension of the apical foramen was measured and the pulp was isolated and segmented horizontally. The different parts were cultured and growth capacity was evaluated and compared. Results of experiment 1 and 2 showed no significant difference in growth capacity between fibroblasts originating from different pulpal segments of the same tooth without cryopreservation and between fibroblasts originating from cryopreserved and non-cryopreserved isolated pulpal tissue. In experiment 3 it was demonstrated that the dimension of the apical foramen and pulpal viability after cryopreservation are positively correlated. A minimum dimension of 9.42 mm2 enables the cryoprotective agent to penetrate sufficiently and to protect the pulpal tissue from apex to crown. This study proved that cryopreservation of human pulpal tissue is possible if the cryoprotective agent can reach the entire pulp.     

Regrowth of embryogenic tissues of <Emphasis Type="Italic">Pinus nigra</Emphasis> following cryopreservation

Embryogenic tissues of a conifer species Pinus nigra Arn. have been cryopreserved by a slow-freezing method. The effect of cryoprotective compounds such as maltose, sucrose or sorbitol (each 0.5 M) combined with 7.5% (v/v) DMSO has been tested. After thawing, the following parameters have been investigated: tissue regrowth 6 weeks after thawing, and post-thaw growth evaluated as fresh mass accumulation as well as genetic stability in post-thaw period. The parameters mentioned have been compared in both cryopreserved and non-cryopreserved tissues. Out of eight cell lines used in experiments, seven survived cryopreservation (87.5% regrowth), although cell line and treatment effects were observed. In most cell lines, sucrose or maltose pretreatments were superior over sorbitol. In the regrown cell lines, the post-thaw growth as fresh mass accumulation was not negatively influenced by cryopreservation. No genetic variation was observed in cryopreserved tissues using a RAPD approach.     

Preliminary report of novel technique for cryopreservation--vacuum-assisted cryoprotectant infiltration

To date, cryopreservation of large soft tissues has not been successfully achieved because of limitation of cryoprotective agent (CPA) infiltration into the tissue. This study aimed to investigate the effects of a vacuum on the tissue-infiltration of a CPA. An instant pickle-maker was modified for use as a vacuum apparatus, and glycerol was selected as the CPA. Twenty-six rats were used, and their thighs were divided into three treatment groups. Group 1: fresh control; Group 2: cryopreserved control, i.e., immersed in the CPA for 1h under atmospheric pressure and cryopreserved; Group 3: vacuum-assisted CPA infiltration, i.e., immersed in the CPA under negative pressure (20, 40 and 60 cmHg, for durations of 10, 20 and 30 min at each) and cryopreserved. The Groups 2 and 3 specimens were thawed after 3 weeks of cryopreservation at -80 °C and histologically examined, in comparison with Group 1. Skin: in Groups 2 and 3, the skin was well preserved. Muscle: in Group 2, both extracellular and intracellular ice crystal formation was widely distributed throughout the muscle tissue. In Group 3, under an adequate vacuum, the muscle tissue was well preserved, with no ice crystal formation. However, when the treatment was conducted under excessive vacuum conditions, the muscle tissue showed focal necrosis. Blood vessels: in Group 3, both the arteries and veins were well preserved up to the tunica intima. The method described in this paper may be a useful technique for achieving cryopreservation of large soft tissues.     

Cryopreservation of keratinocytes in a monolayer.

The cryopreservation of cells in tissues is one of the major challenges in current cryobiology, especially with regard to the progressively increasing field of tissue engineering. It is very questionable whether protocols which were developed for the cryopreservation of isolated cells are also applicable for cells in more complex structures, such as tissues. As a starting point toward cryopreservation of these three-dimensional structures, the aim of this study was to find an optimum cryopreservation protocol for keratinocytes in a monolayer (two-dimensional structure). These epidermal cells can be transplanted as a monolayer grown on an appropriate matrix for the treatment of deep-dermal burns and leg ulcers. The successful cryopreservation of such transplants would offer the advantage of long-term storage and immediate availability of the transplant. In our study, the variables investigated were the cryoprotective solution and the cooling rate. In order to find a nontoxic cryoprotective agent (CPA) which could be transplanted without an additional washing step, we included hydroxyethyl starch (HES) as a possible CPA in our experimental protocol with the commonly used CPAs Me(2)SO, glycerol, and ethylene glycol. For the evaluation, the cell survival rate was determined by dye exclusion (trypan blue) and the cell metabolism was investigated by cell activity assay (alamarBlue). In conclusion, the cryopreservation protocol with 10 wt.-% HES resulted not only in the highest survival rate (72%) but also in the highest metabolic activity of the cells after thawing; comparable values for the other CPAs were: Me(2)SO, 48%; glycerol, 8%; and ethylene glycol, 10%.     

Viability of pulp stromal cells in cryopreserved deciduous teeth

The cryopreservation of exfoliated deciduous teeth and harvesting of stem cells from them as required would reduce the costs and efforts associated with banking stem cells from primary teeth. The aim of this study was determine whether the viability of pulp stromal cells from deciduous teeth was influenced by the cryopreservation process itself or the period of cryopreservation. In total, 126 deciduous teeth were divided into three groups: (1) fresh, (2) cryopreserved for <3 months (cryo<3), and (3) cryopreserved for 3–9 months (cryo3–9). The viability of the pulp tissues was compared among the three groups by evaluating the outgrowth from pulp tissues and cell activity within those pulp tissues. In addition, the terminal deoxynucleotidyl transferase-mediated dUTP–biotin nick end labeling (TUNEL) assay was performed to compare cell apoptosis within fresh pulp tissue and pulp tissue that had been cryopreserved for 4 months. The outgrowth from and cell activity within the pulp tissues did not differ significantly between the fresh and cryo<3 pulp tissues. However, these parameters were significantly reduced in the cryo3–9 pulp tissue. In TUNEL assay, 4-month cryopreserved pulp tissues has more apoptotic cells than fresh group. In conclusion, it is possible to acquire pulp stromal cells from cryopreserved deciduous teeth. However, as the period of cryopreservation becomes longer, it is difficult to get pulp cells due to reduced cell viability.     

Cryopreservation of composite tissues and transplantation: preliminary studies

Despite advances in cryobiology, the reliable cryopreservation of complex tissues has not yet been achieved. This study evaluates the viability of cryopreserved composite flaps and demonstrates the feasibility of their transplantation. Epigastric flaps were harvested from male Lewis rats. 1.5 M dimethyl sulfoxide (Me₂SO) was used as the initial cryoprotectant agent (CPA). Samples were frozen at controlled rate to −140 °C and transferred to liquid nitrogen for at least two weeks. Hematoxylin and eosin (H/E) staining, MTT tetrazolium salt assay, and factor VIII immunostaining were used to evaluate the overall histology, epithelial viability, and vascular endothelial integrity, respectively, of cryopreserved flaps. For the in vivo phase, flaps were isotransplanted to 35 recipient animals, divided into three groups: fresh (n = 10), perfused (n = 8), and cryopreserved (n = 17). Blood vessel patency was assessed via Doppler at 1, 7, and 60 days post-transplantation. For in vitro studies, cryopreserved samples (10/10) retained normal cell architecture and vascular endothelial integrity upon H/E and factor VIII staining. The viability index of cryopreserved composite flap skin (n = 10) was 11.17 ± 2.01, which was not significantly different from fresh controls (n = 10, 12.15 ± 1.32). All transplanted flaps in the fresh and perfusion groups survived with healthy color and hair growth at 60 days after operation. Survival in the cryopreserved group ranged from 2 to 60 days, with a mean of 12 days. These results demonstrate that the long term survival of cryopreserved composite tissue transplants is possible. Further studies are needed to refine protocols for the reliable cryopreservation of composite parts.     

A method of isolating viable chondrocytes with proliferative capacity from cryopreserved human articular cartilage

This study aimed to optimise methods of cryopreserving human articular cartilage (AC) tissue for the isolation of late chondrocytes. Human AC specimens from osteoarthritis patients who had undergone total knee replacement were used to optimise the chondrocyte isolation process and the choice of cryoprotective agent (CPA). For AC tissue cryopreservation, intact cored cartilage discs (5 mm diameter) and diced cartilage (0.2–1 mm cubes) from the same sized discs were step cooled and stored in liquid nitrogen for up to 48 h before chondrocyte isolation and in vitro assay of cell viability and proliferative potential. The results showed that 10 % dimethyl sulphoxide in 90 % foetal bovine serum was a successful CPA for chondrocyte cryopreservation. Compared with intact cored discs, dicing of AC tissue into 0.2–1 mm cubes significantly increased the viability and proliferative capacity of surviving chondrocytes after cryopreservation. In situ cross-section imaging using focused ion beam microscopy revealed that dicing of cored AC discs into small cubes reduced the cryo-damage to cartilage tissue matrix. In conclusion, modification of appropriate factors, such as the size of the tissue, cryoprotective agent, and isolation protocol, can allow successful isolation of viable chondrocytes with high proliferative capacity from cryopreserved human articular cartilage tissue. Further studies are required to determine whether these cells may retain cartilage differentiation capacity and provide sufficient chondrocytes for use as implants in clinical applications.     

糖在猕猴精子低温冷冻保存过程中的作用

TTE或TEST防冻液在冻存猕猴精子时产生不同结果,其主要不同在于防冻液中糖成分的不同。本实验利用透射电镜技术检测这2种防冻液冻存的猕猴精子冷冻前后超微结构的变化,以说明糖在低温冻存过程中的作用。结果表明,冷冻复苏过程对精子结构产生了影响。TTE法低浊保存的猕猴精子的头部的质膜出现少许皱褶或泡化现象,但精子的顶体、核或是精子尾部的结构与鲜精的结构基本相似。猕猴精子经TEST法低温保存后,大部分精子结构则发生了明显的变化。精子膜、顶体和精子核明显泡化、损伤或破裂,精子尾部不能分辨出正常的超微结构。这提示,可能由于TTE防冻液中复杂的糖成分在降温／复苏过程对精子起到了较好的协同冷冻保护作用;而TEST防冻液中单一的糖成分不能完全保护精子避免低温损伤,低温保存过程破坏了精子的结构,并影响了复苏后精子体外存活能力与受精能力。     

Isochoric vitrification: An experimental study to establish proof of concept

Ice-free vitreous cryopreservation (vitrification) is regarded as the principal method for avoiding ice crystallization damage in cryopreserved tissues and organs. We previously established the fundamental thermodynamics of isochoric (constant volume) systems for cryopreservation, and now extend this novel approach to vitrification in an isochoric system. This was achieved by measuring pressure changes in a 2 ml isochoric chamber containing a variety of aqueous solutions of the ubiquitous cryoprotective additives (CPA), dimethyl sulfoxide (Me₂SO) and Propane-diol. The CPAs, ranging in concentrations from 0 to 49%(w/v), were prepared in a proprietary preservation solution (Unisol^®) in anticipation of future applications to tissue and organ banking. Pressures developed in the system were monitored as a function of CPA concentration and cooling rate when the isochoric chamber was cooled to cryogenic temperature (−160 °C). This study corroborated our previous findings that pressure increases in accordance with the thermodynamics of partially frozen systems of low concentrations of CPAs. A key finding of this study was that in an isochoric system of higher concentrations of CPA, which vitrifies, there is no increase in pressure. In fact, an increase in pressure is a measure of failure to vitrify and a measure of devitrification. Comparison with results from the literature show that the concentration of CPAs needed for vitrification in an isochoric chamber is substantially lower than that needed for vitrification in isobaric systems at 1 atm and hyperbaric systems at 1000 atm. In addition, isochoric chambers are much more effective in promoting vitrification than hyperbaric pressure chambers, and are less expensive, easier to design, and implement.     

Porcine heart valve,aorta and trachea cryopreservation and thawing using polydimethylsiloxane

The most common cryopreservation protocols of biological tissues suitable for their further implantation has some disadvantages and limited to one sample per procedure with no possible repeated freezing in case of clinical needs. This study is aimed to improve a biological tissues cryopreservation by adding a new heat transfer fluid – polydimethylsiloxane (PDMS). To evaluate its efficiency the porcine biological tissues (heart valves, aortic and trachea fragments) were cryopreserved and thawed in low-viscous PDMS. According to the computer simulation, the midsection cooling rate was up to 490 °C/min and the midsection thawing rate was up to 1140 °C/min with admissible temperature uniformity. Cryoprotectants and liquid nitrogen were not used. The quality of tissue cryopreservation was evaluated using a number of histological and immunohistochemical methods (Orcein, H&E, Anti-CD34, Anti-Vimentin, Anti-Actin staining). Cryopreserved tissues showed no significant morphological difference in comparison with control group both in case of immediate thawing, and after 2 months of low temperature storage. Computer simulation of heat transfer showed the thermal limitations of used approach for larger specimens. The use of PDMS is proposed for preservation of vascular tissue in order to implant it in the form of homotransplants or biobanking with the possible additional use of an internal hydrophilic coating to prevent hydrophobization.     

A Novel Approach for Ovine Primary Alveolar Epithelial Type II Cell Isolation and Culture from Fresh and Cryopreserved Tissue Obtained from Premature and Juvenile Animals

The in vivo ovine model provides a clinically relevant platform to study cardiopulmonary mechanisms and treatments of disease; however, a robust ovine primary alveolar epithelial type II (ATII) cell culture model is lacking. The objective of this study was to develop and optimize ovine lung tissue cryopreservation and primary ATII cell culture methodologies for the purposes of dissecting mechanisms at the cellular level to elucidate responses observed in vivo. To address this, we established in vitro submerged and air-liquid interface cultures of primary ovine ATII cells isolated from fresh or cryopreserved lung tissues obtained from mechanically ventilated sheep (128 days gestation—6 months of age). Presence, abundance, and mRNA expression of surfactant proteins was assessed by immunocytochemistry, Western Blot, and quantitative PCR respectively on the day of isolation, and throughout the 7 day cell culture study period. All biomarkers were significantly greater from cells isolated from fresh than cryopreserved tissue, and those cultured in air-liquid interface as compared to submerged culture conditions at all time points. Surfactant protein expression remained in the air-liquid interface culture system while that of cells cultured in the submerged system dissipated over time. Despite differences in biomarker magnitude between cells isolated from fresh and cryopreserved tissue, cells isolated from cryopreserved tissue remained metabolically active and demonstrated a similar response as cells from fresh tissue through 72 hr period of hyperoxia. These data demonstrate a cell culture methodology using fresh or cryopreserved tissue to support study of ovine primary ATII cell function and responses, to support expanded use of biobanked tissues, and to further understanding of mechanisms that contribute to in vivo function of the lung.     

Cryopreservation of ovarian tissues temporarily suppresses the proliferation of granulosa cells in mouse preantral follicles

Cryopreservation of ovarian tissue has been reported to delay the development of preantral follicles during in vitro culture, but the mechanism causing this impairment has not been brought to light. In order to elucidate the underlying mechanism of delayed follicular development, we evaluated the effects of cryopreservation on the proliferation of granulosa cells during culture of mouse preantral follicles, as a sufficient population of granulosa cells is critical for normal follicular development. Additionally the initial cell death of granulosa cells was estimated immediately after cryopreservation. The ovarian tissues obtained from 12-day-old female mice were cryopreservation by vitrification. The granulosa cell proliferation was evaluated by measuring the PCNA expression and the expression of cell cycle regulators such as cyclin D2, CDK4, cyclin E and CDK2 in preantral follicles isolated from fresh and cryopreserved ovarian tissues that were cultured for 48 h. The viability of granulosa cells was evaluated by measuring the proportion of necrotic areas. The granulosa cell proliferation of the cryopreserved preantral follicles was decreased significantly compared to that of the fresh controls at 0 and 24 h after culture (P < 0.05), and this was increased to the control levels after 48 h of culture. The expressions of cyclin D2, Cdk 4, cyclin E and Cdk2 were also decreased in the cryopreserved ovarian tissues at 0 and 24 h after culture (P < 0.05), but they were increased to the control levels after 48 h of culture. The proportion of the necrotic area was significantly higher in cryopreserved preantral follicles compared to that of the fresh preantral follicles (P < 0.05). This suggests that cryopreservation of ovarian tissues may delay the preantral follicle development by temporary suppressing the granulosa cell proliferation through the cell cycle regulators (cyclin D2, Cdk4, cyclin E and Cdk2) and by granulosa cell death immediately after warming.     

Effect of glycerol addition time on the cryopreserved Korean native brindle cattle (Chikso) sperm quality

Although cryopreservation is an efficient method for maintaining the biological and genetic resources of sperm, the sperm damage during the cryopreservation process cannot be ignored. It should be possible to obtain the most effective cryopreservation performance by accurately grasping the effects of various factors on the cryopreservation of sperm. The previous study demonstrated that a suitable standard protocol for cryopreservation of Korean native brindled cattle (Chikso) does not exist, based on the methods for semen cryopreservation of Chikso differ in each research center. The most obvious difference between most of protocols is the addition of glycerol before and after cooling during the Chikso cryopreserved semen process. Therefore we focused on the effects of glycerol addition time on the quality of cryopreserved Chikso sperm. In the present study, 27 individual Chikso samples were collected by transrectal massage and divided into two parts: the “cryopreservation method A” group (adding glycerol before cooling) and the “cryopreservation method B” group (adding glycerol after cooling). Meanwhile, the values of various sperm parameters were derived from each group, including sperm motility, kinematics, capacitation status, cell viability, and intracellular ATP levels, which we used to compare and evaluate sperm function. The results of this study indicated that during the semen cryopreservation process of the Chikso, the addition of glycerol after cooling yielded superior results in a variety of sperm parameters, such as sperm motility, progressive motility, rapid motility, VCL, VSL, VAP, ALH, capacitation status, viability, and intracellular ATP level after freezing and thawing. Our study is suggested that the glycerol addition time during the cryopreservation process for Chikso should be considered. In addition, our results may be provided reference to develop suitable the cryopreservation procedure of the Chikso sperm.     

Cell Lineages and the Logic of Proliferative Control

It is widely accepted that the growth and regeneration of tissues and organs is tightly controlled. Although experimental studies are beginning to reveal molecular mechanisms underlying such control, there is still very little known about the control strategies themselves. Here, we consider how secreted negative feedback factors (“chalones”) may be used to control the output of multistage cell lineages, as exemplified by the actions of GDF11 and activin in a self-renewing neural tissue, the mammalian olfactory epithelium (OE). We begin by specifying performance objectives—what, precisely, is being controlled, and to what degree—and go on to calculate how well different types of feedback configurations, feedback sensitivities, and tissue architectures achieve control. Ultimately, we show that many features of the OE—the number of feedback loops, the cellular processes targeted by feedback, even the location of progenitor cells within the tissue—fit with expectations for the best possible control. In so doing, we also show that certain distinctions that are commonly drawn among cells and molecules—such as whether a cell is a stem cell or transit-amplifying cell, or whether a molecule is a growth inhibitor or stimulator—may be the consequences of control, and not a reflection of intrinsic differences in cellular or molecular character.     

Optimizing methods for human testicular tissue cryopreservation and spermatogonial stem cell isolation

Cryopreservation of testicular tissue before cancer therapy for fertility preservation in prepubertal boys with cancer is of great interest in reproductive medicine. Isolation of spermatogonial stem cells (SSCs) from cryopreserved tissues would be a suitable cell source to re-establish spermatogenesis after cancer therapy. We herein establish optimized protocols for cryopreservation of human testicular tissue and isolation of SSCs from cryopreserved tissue. We developed a freezing protocol that provided high testicular cell viability and supported structural integrity and tubular epithelium coherence similar to fresh tissue. Then, we established a protocol that allowed efficient isolation of functional SSCs from cryopreserved tissues. Isolated cells were found on the testicular basement membrane after xenotransplantation. Our results demonstrated the preservation of testicular tissue structure and high cell viability with efficient isolation of SSCs after testicular cryopreservation, which is promising for future therapeutic applications in fertility preservation.