Intracephalic transplants of freeze‐Stored rat hippocampal tissue

Sørensen, Torben; Jensen, Sigmund; Møller, Anders Hauer; Zimmer, Jens

doi:10.1002/cne.902520404

Cited by 42 publications

(3 citation statements)

References 47 publications

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“…We can, however, conclude that, unlike nigral neurons, it may not be necessary to implant fully differentiated striatal neurons in order to replace the degenerating medium spiny projection neurons, but that either the environment may assist in determining an appropriate phenotype, or we will have to ‘prime’ our progenitors to reach a developmental stage where the cells can continue appropriate neuronal maturation. If the latter is true, then for striatal neuron phenotypes we may not have to convert progenitors into fully differentiated neurons prior to transplantation, both lessening the complexity of this task, and reducing the risk of lowered cell survival, migration and integration properties seen with transplants of later stage neurons (Boer et al ., 1985; Sorensen et al ., 1986; Grabowski et al ., 1994; Freeman et al ., 1995; Annett et al ., 1997; Watts et al ., 2000; Chekhonin et al ., 2002).…”

Section: Discussionmentioning

confidence: 99%

Striatal neurons in striatal grafts are derived from both post‐mitotic cells and dividing progenitors

Fricker-Gates

White

Gates

et al. 2004

Eur J of Neuroscience

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Transplants of embryonic striatal tissue are characteristically heterogeneous, containing patches (P-zones) of striatal medium spiny projection neurons. It is not yet known how this morphology develops, and whether the striatal neurons in the grafts are derived from post-mitotic neuroblasts in the embryonic brain or from striatal progenitors that continue to divide after transplantation. To address this question we labelled dividing cells in the transplants with bromodeoxyuridine (BrdU), either prior to or after transplantation into the adult lesioned rat striatum. Cells for transplantation were either pre-labelled in utero by intraperitoneal (i.p.) injections of BrdU, or post-labelled after transplantation by i.p. injections to the hosts. Either two or six months after transplantation the brains were processed using double immunohistochemical techniques to detect BrdU and calbindin-positive neurons in the transplants. In the transplants pre-labelled with BrdU, approximately 30% of calbindin-positive cells were heavily labelled with BrdU, suggesting these had undergone a final division prior to transplantation. In transplants where cells had been labelled post-transplantation, approximately 17% of calbindin cells were heavily BrdU labelled. These results suggest that whereas a proportion of striatal medium spiny neurons in the striatal grafts were post-mitotic at the time of transplantation, other striatal progenitor cells can continue to divide after transplantation, and then complete an appropriate neuronal maturation programme in the adult host brain environment.

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Section: Discussionmentioning

confidence: 99%

Striatal neurons in striatal grafts are derived from both post‐mitotic cells and dividing progenitors

Fricker-Gates

White

Gates

et al. 2004

Eur J of Neuroscience

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“…There are no data comparing the susceptibility of adult and fetal organs in pigs or in other animals. However, a report indicates significant variations in the survival rates of frozen rat fetal brain tissue depending on gestational age [27]. Lastly, in this experiment, the collected fetuses were transported to our laboratory, resulting in an ischemic time of approximately 5 h. The differentiation and expansion capacity of mouse fetal kidneys were maintained after refrigeration as whole fetuses, not as isolated organs, for less than 72 h [14].…”

Section: Discussionmentioning

confidence: 99%

Exploration of Preservation Methods for Utilizing Porcine Fetal-Organ-Derived Cells in Regenerative Medicine Research

Matsui,

Sekine,

Ishikawa

et al. 2024

Cells

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Human pluripotent stem cells have been employed in generating organoids, yet their immaturity compared to fetal organs and the limited induction of all constituent cell types remain challenges. Porcine fetal progenitor cells have emerged as promising candidates for co-culturing with human progenitor cells in regeneration and xenotransplantation research. This study focused on identifying proper preservation methods for porcine fetal kidneys, hearts, and livers, aiming to optimize their potential as cell sources. Extracted from fetal microminiature pigs, these organs were dissociated before and after cryopreservation–thawing, with subsequent cell quality evaluations. Kidney cells, dissociated and aggregated after vitrification in a whole-organ form, were successfully differentiated into glomeruli and tubules in vivo. In contrast, freezing hearts and livers before dissociation yielded suboptimal results. Heart cells, frozen after dissociation, exhibited pulsating heart muscle cells similar to non-frozen hearts. As for liver cells, we developed a direct tissue perfusion technique and successfully obtained highly viable liver parenchymal cells. Freezing dissociated liver cells, although inferior to their non-frozen counterparts, maintained the ability for colony formation. The findings of this study provide valuable insights into suitable preservation methods for porcine fetal cells from kidneys, hearts, and livers, contributing to the advancement of regeneration and xenotransplantation research.

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“…Other studies have shown that cryopreserved nerve tissue is more fragile than normal and tends to fragment (Jensen et al, 1984;Sörensen et al, 1986;Collier et al, 1987). There are several reasons for this.…”

Section: Influence Of Cryopreservationmentioning

confidence: 98%

Development of Retinal Transplants

Sharma

1998

Acta Ophthalmologica Scandinavica

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Intracephalic transplants of freeze‐Stored rat hippocampal tissue

Cited by 42 publications

References 47 publications

Striatal neurons in striatal grafts are derived from both post‐mitotic cells and dividing progenitors

Striatal neurons in striatal grafts are derived from both post‐mitotic cells and dividing progenitors

Exploration of Preservation Methods for Utilizing Porcine Fetal-Organ-Derived Cells in Regenerative Medicine Research

Development of Retinal Transplants

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