PL209210B1 - The manner of culture of mother cells obtained from growing antler - Google Patents

Description

Description of the invention

The present invention relates to a method of culturing stem cells derived from growing antlers of deer, especially red deer, in order to prepare a graft for the regeneration of cartilage and bone tissue.

In the European cultural circle, facial beauty requires the symmetry of its individual elements. Therefore, complete or partial absence as well as congenital and acquired deformities of the auricle and nose may constitute a serious cosmetic defect. In the case of these deformities, the therapeutic treatment of choice is complex, often multi-stage surgical procedures using available organic implants. The search for the perfect material for the reconstruction of the godfather of the auricles and the nose has over 100 years of history and is still intensively conducted. The host's own rib cartilage has been and is most often used as a reconstructive material in facial surgery. Unfortunately, the time needed to obtain the cartilage makes the procedure difficult, exposes the patient to postoperative discomfort, prolongs convalescence and increases the likelihood of later complications at the site of collection of the material. Furthermore, in children the amount of rib cage that can be recovered is often too small to recreate the scaffold of the auricle or nose, and in adults it may be ossified and unsuitable for molding. These inconveniences can be avoided by the use of allogeneic cartilage - compatible with species, as the treatment of choice for every patient who does not have enough own cartilage. In order to weaken the recipient's immune response, various methods of its preparation are then used. Popular methods include storing the cartilage in merthiolate for several weeks, repeated rinsing in concentrated salt solution (NaCl) or sterilization with gamma irradiation. Cartilage, which does not exhibit metabolic activity, then remains only a scaffold for the surrounding tissues and is slowly resorbed. The research by Vacanti et al., Started in the 1990s, may be considered the next stage in the search for the most suitable organic material for reconstruction. In pioneering experiments, a synthetic, biocompatible, biodegradable, porous polymer mesh was used, which was impregnated with isolated human chondrocytes. However, the number of chondrocytes obtainable by growing them outside the body is limited, and it is directly related to the efficiency of the regeneration process. The technology is very expensive, cumbersome, and requires specialized equipment. Many implants gradually lose their original shape.

In recent years, it has become more and more likely that different types of cells, derived from stem cells, will be able to treat many human diseases. The beginning of the 21st century is a period of dynamic development of research on their use for the regeneration and reconstruction of all types of tissues, including connective tissue. Stem cells, both in vivo and in vitro, are characterized by a very high proliferative potential, and the possibility of their transplantation is an opportunity for significant progress in transplantology. However, for most tissues, it is extremely difficult to obtain targeted cell lines. The collection of human stem cells is also often associated with ethical problems and the risk of transferring viral and neoplastic diseases. An alternative to human cells could be modified xenograft cells. Searching for their source, attention was drawn to the possible use of deer antlers, which are characterized by a specific, nowhere else, process of renewal and growth.

Extremely dynamic growth of antlers - two-centimeter daily increments over a period of three months - makes it one of the fastest growing organs in mammals. Cells of deer, regenerated annually, antlers, which are classified as adult somatic stem cells, have a very high proliferative potential. They produce a limited number of differentiated cell types, which are involved, among others, in the regeneration of damaged cartilage and bone. Since antiplerotic cells are poorly differentiated cells that induce poor immune response induction, the chance of their xenograft, i.e. xenograft, transplantation may be high.

The invention relates to a method of culturing stem cells derived from growing antlers of deer, especially red deer, based on primary culture, either directly from it or from cells previously frozen.

The essence of the invention is based on the fact that the primary culture is established from sterile collected fragments of growing deer antlers, which are crushed, cells are isolated and cultured, using the MEM culture medium with the addition of 10% fetal bovine serum and glutamine solution as a growth fluid.

And selected antibiotics, carried out in an atmosphere of 5% CO2 and a temperature of 37 ° C. After the fifth passage has been established, the cells are either frozen or grown under the conditions described above on an identical culture medium, and after obtaining the appropriate number of cells, at least 2 x 10 ⁶ , they are detached with trypsin with 0.02% ethylenediaminetetraacetic acid (EDTA). ) and centrifuged in complete culture medium. The obtained pellet is suspended in clean MEM medium and fragments of the scaffold are prepared, for which the pieces of Spongostan are used, with the dimensions required to fill the defect of cartilage or bone. It is placed in a sterile vial, a suspension of cells in an amount of at least 2 x 10 ^6/1 ml of liquid. The cells are deposited onto the Spongostan scaffold by centrifugation, and then decanting the supernatant.

During the research, an answer was sought to the question whether the used xenograft cultured cells would survive and take up their life functions within foreign tissue. For this purpose, an attempt was made to use xenograft stem cells from the growing antlers of red deer to regenerate the cartilage defect in the rabbit's ear. For transplantation, cells from a culture obtained according to the invention were used on a scaffold for transplants, which was the Spongostan of Johnson & Johnson, Poland. 12 rabbits were used for the experiment, 6 as experimental group (E) and 6 as control (C), eight-month-old Californian white female rabbits weighing approximately 3.5-4.0 kg. Halfway up the auricle, on its outer surface, an operating field is prepared as standard. The skin surface was shaved and cleaned. Approximately 1 cm from the free edge of the auricle, on its dorsal surface, a medially pedunculated dermal-chondral flap, measuring 1 x 1 cm, was dissected. Then a 0.5 x 0.5 cm fragment of the exposed cartilage was dissected and removed. Small, bleeding vessels were closed with electro-coagulation. In 6 rabbits from group E, a Spongostan flap soaked with the cell suspension was placed on the right side of the prepared bed, i.e. in the peridural pocket, adjusted to the dimensions of the cartilage defect. In an identical manner, 6 rabbits from group C were implanted with Spongostan soaked in physiological saline. Dermal-chondral flaps were applied to the implant sites. Wounds were closed in one layer with surgical threads. They were then rinsed with hydrogen peroxide and left uncovered without applying any dressings. The procedures were performed in an antibiotic cover, with penicillin 50,000 IU / kg administered intramuscularly to all rabbits. Following clinical observations, both in groups E and C, at 4 and 9 weeks from the day of surgery, experimental material was collected from the operated sites, which were sections covering the entire thickness of the auricle, containing both the implant and the animal's own cartilage. The obtained material was fixed for immunohistochemical studies and in an electron microscope.

For immunocytochemical tests, the collected material was fixed in a 4% buffered formalin solution, abdomen and embedded in paraffin blocks. Sections for microscopic examination were stained with hematoxylin and eosin (M + E) and toluidine (T). Immunocytochemical reactions were performed on paraffin sections using anti-CX-CR4, anti-c-kit and anti-Thy-1 antibodies, detecting proteins characteristic of stem cells.

For electron microscopy studies, the material was fixed with 2.5% glutaraldehyde on a cocodyl buffer (0.1 M, pH 7.4), and then it was dehydrated and embedded in an Epona 812.

The electrophoretic tests of blood serum proteins were performed in the fourth week after the procedure, collecting 2 ml of blood from the marginal ear vein from each rabbit from the experimental group and from the control group. Blood was incubated in the standard manner at 37 ° C for 0.5 hours and then centrifuged for 5 minutes to obtain serum. Serum electrophoresis was performed on a buffered agarose gel by high voltage horizontal electrophoresis. The readings were made with a densitometer at a wavelength of 600 nm, obtaining individual protein fractions and the ratio of albumin to globulin was determined. The obtained results of electrophoretic tests were statistically analyzed using the Student's t-test. The differences where p <0.05 were taken as statistically significant. The calculations were performed with the use of the Statistica ver. 7.0 (Stat Soft, Kraków, Poland).

During clinical observations, carried out simultaneously after the experimental and control implants, the healing process was observed and compared. All 12 animals endured the applied surgical procedures well. Postoperative wounds healed properly by rapid growth. The sutures were removed 8 days after surgery. In places where somatic stem cells suspended on Spongostan were located introchondrially, their participation in regenerative processes was observed, without inflammation and graft rejection. The result of the intensive regeneration process was a clear increase in the thickness of the cartilage during the first period

Of the first 3 weeks of experiment. This process then gradually slowed down. In the 7th week of the experiment, the newly formed scaffold of the auricle with a slightly uneven surface, covered with unchanged skin, was about 15% thicker than the surrounding cartilage of the animal's own. For the next 2 weeks, no increase in the thickness of the auricle was observed. The Spongostan rabbits from the control group, soaked with saline solution, were absorbed without signs of necrosis or inflammation, and the areas where the cartilage was removed remained concave. After 9 weeks, these areas were still much thinner, covered with unchanged skin on both sides. No regenerative processes have been observed here, only the scarring process.

Based on the research, the following can be stated.

At week 4, a large number of proliferating, streaky, undifferentiated cells are observed around the periphery of the regeneration area. In some areas, small blood vessels appear between them. In the center of the transplant, the arrangement of cells becomes less frequent, and collagen fibers appear between them. Initially, they follow a regular streaked course, and then their arrangement becomes chaotic, often intertwined. Numerous fibroblasts are located between the collagen fibers, fibrocytes with a smaller number of chondrocytes, and sometimes local clusters of lymphocytes and eosinophils. The center of the regeneration area is occupied by a basic entity that organizes and remodels with numerous typical connective tissue cells such as fibroblasts, chondroblasts, osteoblasts and numerous dense matrix structures. Morphologically, these structures are similar to cartilage-bone and bone trabeculae in which active osteoclasts are present in the so-called erosive sinuses. After 9 weeks, a decreased cell number and an increase in collagen fibers are observed at the regeneration sites. In a more mineralized basal matter, numerous calcifications and individual foci of ossification are present.

The performed immunocytochemical reactions allowed to locate cells showing the presence of the Thy-1 and CX-CR4 proteins characteristic for stem cells within the area of the implant. The labeled cells were located next to and within the blood vessels and in the zone of intensively proliferating, undifferentiated cells on the border of the implant and the auricle cartilage, as well as in the reconstruction sites of the osteochondral trabeculae.

Based on electron microscopy, the following can be stated.

In most of the electronograms from the regeneration sites, both in the 4th and 9th week of the experiment, relatively numerous cells and a large number of collagen fibers were observed. Most of the cells observed are fibroblasts, chondroblasts and osteoblasts. After 3 weeks of regeneration, their cytoplasm contains large amounts of a rough endoplasmic reticulum with often distended channels, numerous mitochondria with the presence of a homogeneous matrix and indistinct contours of mitochondrial crests, as well as aquatic warblers and vacuoles. The nuclei of these cells contain large amounts of loose chromatin. There are also small, obstructed fragments of the cytoplasm that detach from the cells and become part of the intercellular substance involved in its mineralization. In the 9th week of the experiment, the number of cells is smaller and the amount of collagen increases. In many cells, both the cell membrane and the nuclear envelope show invagination and nuclear chromatin condenses. Many cells undergo apoptosis and contain nuclei, characteristic of apoptotic cells, in which nuclear chromatin is condensed and their cytoplasm is fragmented. After 3 weeks, the increase in the thickness of the cartilage slowed down significantly, while after 9 weeks of the experiment, the defect of the auricle's godfather was completely rebuilt. Numerous apoptotic cells were observed on the electronograms. Active apoptotic processes are responsible for the morphogenesis of the growing antlers. They are also one of the mechanisms influencing the regulation of the regeneration process, including limiting excessive cell growth. Similar regulatory processes take place during skeletal development, bone growth, and bone remodeling

However, as a result of electrophoretic separation of serum, protein fractions such as albumin, α1, α2, β1, β2 globulins and gamma globulins were obtained. Single fractions were determined in relative and absolute values, and the albumin to globulin ratio was determined. The electrophoretic separation of serum proteins illustrates the behavior of a broad spectrum of fractions, including acute phase proteins and immunoglobulins. Albumin is a negatively reacting fraction, and proteins contained in the α1, α2, β1, β2 globulin fractions react to a different degree and positively with different dynamics. In our opinion, the role of the surgical trauma and the violation of tissue continuity as an inducing factor of the acute phase response could be omitted, as all animals from groups E and C underwent a technically identical surgical procedure. When comparing the proteinograms of the experimental and control groups in animals,

Only a slight, at the border of statistical significance, increase in the fraction of β2 globulins was observed in the presence of antiperspirant cells. This correlated with the weak inflammatory reaction to xenograft cells observed simultaneously in microscopic studies. Moderate angiogenesis and massive collagen synthesis, in the absence of neutrophilic infiltration triggering proteolytic processes, support the regenerative effect of antlerogenic cells. The immune response in the operated animals was therefore poorly expressed and was not accompanied by a graft rejection reaction.

The table below presents the electrophoretic separation of serum proteins from the control and experimental rabbits.

Group C. N 6 Group E N 6 Total protein g / l 60.9 ± 14.7 57.4 11.3 Albumin g / l 41.7 ± 3.6 37.6 ± 7.2 % 67.2 ± 4.83 65.8 ± 4.68 Alpha 1 g / l 2.8 ± 1.6 1.7 ± 0.8 % 4.22 ± 2.05 2.98 ± 1.27 Alpha 2 g / l 3.8 ± 1.2 2.6 ± 0.7 % 5.95 1.36 5.28 ± 1.06 Globulins Beta 1 g / l 5.3 ± 1.4 4.9 ± 1.7 % 8.57 ± 2.07 11.01 ± 4.6 Beta 2 g / l 2.03 ± 0.75 2.4 ± 0.62 % 3.3 7 ± 1.26 4.18 ± 1.16 Gamma g / l 6.35 ± 1.73 7.03 ± 1.89 % 10.38 ± 2.83 12.42 ± 2.79 Albumin / Globulins 2.04 ± 0.61 1.97 ± 0.42

Based on the results of the research carried out, it can be concluded that it is possible to obtain stem cell implants derived from the method according to the invention in order to rebuild cartilage and bone tissue in species other than deer. Antiperspirant cells were not rejected by a representative group of animals, such as rabbits, and, on the contrary, they participated in the regeneration of cartilage with the participation of host tissues tolerating their presence. This allows the conclusion that there is a real prospect of using the stem cells thus obtained also in humans. The implants produced by the method according to the invention allow to avoid a number of difficulties in the regeneration of connective tissue in humans by known methods, which carry the risk of transferring viral, cancer or genetic diseases, and, which is extremely important, to get rid of the ethical problems associated with obtaining human stem cells for this purpose.

The subject of the invention is presented in an exemplary embodiment.

Example: A piece of tissue of the growing antler in the form of a disc 1.5 cm in diameter and 0.2 mm thick is collected in a sterile manner while the animal is anesthetized. The collected tissue fragment is divided into four parts. One part intended for cell culture is placed in a test tube by immersing it in 10 ml of the culture medium - MEM by Cambrex with the addition of penicillin 100 U.l / ml and streptomycin 0.1 mg / ml. In laboratory conditions, the sample is learned several times with the medium with the addition of the above-mentioned antibiotics. Then, it is mechanically crushed into small pieces of 0.5-1 mm. From such a fragmented antler fragment, proliferating cells are isolated using the phenomenon of their spontaneous migration. After isolation, cells are suspended in complete culture medium in an amount of at least 20% of the culture chamber volume, with the addition of 10% fetal bovine serum, penicillin 100 UI / ml, streptomycin 0.1 mg / ml, L-Glutamine 1 mM / ml and it carries

PL 209 210 B1 for breeding bottles with an area of 25 cm ² . The cultivation is carried out in a Kendro incubator under standard conditions, i.e. at a temperature of + 37 ° C, in an atmosphere with 5% CO2. After the monolayer is complete, the cells are detached from the substrate of the culture bottles using the enzyme 0.05% trypsin with 0.02% ethylenediaminetetraacetic acid (EDTA) and transferred to subsequent culture bottles. From the primary line thus obtained, a solid line is drawn through successive passages, and after the fifth passage has been obtained, the cells are frozen with 10% dimethylsulfoxide (DMSO) and stored in liquid nitrogen at -176 ° C.

To prepare the cells for implantation, the fifth passage is thawed by exposing the cells to further culture using the identical complete culture medium. After obtaining the appropriate number of 5 x 10 ⁶ cells, they are detached from the base of the culture bottles using trypsin and EDTA, then centrifuged in the complete culture medium, using the fact that the serum contained in the medium inactivates the action of the trypsin enzyme, and the obtained pellet is suspended in a clean medium MEM without serum

L-Glutamine, and antibiotics. The cells are counted in a Biirker chamber and 2 x 10 ⁶ cells are suspended into one implant, preparing them for scaffolding. For this purpose, fragments of Spongostan, i.e. a Johnson & Johnson gelatin sponge are used, used in surgery, e.g. in staunching bleeding, and here as a carrier for the cultivation of adherent cells. They are placed in sterile plastic ampoules, a cell suspension is added in the amount of 2 x 10 ⁶ cells / 1 ml of pure MEM fluid without additives, then it is centrifuged, and the cells at this time settle on Spongostan. Centrifugation is carried out in a Hereus centrifuge for 10 minutes at approximately 700 rpm. The centrifuged fluid - the supernatant - is decanted to obtain implant-ready cells suspended on Spongostan.

Claims (1)

Patent claim A method of culturing stem cells derived from growing antlers of deer, especially red deer, based on a primary culture, carried out in an atmosphere of 5% CO2 and a temperature of 37 ° C, directly from it or from cells previously frozen, characterized in that the primary culture is assumed from sterile collected fragments of growing deer antlers, which are crushed, cells are isolated and cultured, using MEM culture medium with the addition of 10% fetal bovine serum, glutamine solution and selected antibiotics as the growth fluid, and after the fifth passage, the cells are frozen or continued cultivation under the conditions described above, on an identical culture medium and after obtaining the number of cells at least 2 x 10 ⁶ , they are detached with trypsin with 0.02% ethylenediaminetetraacetic acid (EDTA), centrifuged in complete culture medium, while the obtained pellet is suspended in a clean MEM medium and prepares fragments of the scaffolding to which the It uses pieces of Spongostanu as required to replenish cartilage or bone dimensions, and placed in a sterile vial, a suspension of cells in an amount of at least 2 x 10 ^6/1 ml of fluid and the cells deposited on the scaffold with Spongostanu by centrifugation, and then decant the supernatant.