Global ETD Search

1	The study and application of testis tissue xenografting Abbasi, Sepideh 30 June 2010 Testis tissue xenografting (TTX) provides a novel in vivo model for the study of testis function, and a previously-unavailable opportunity to produce spermatozoa in the grafts from immature donors of diverse species. The overall objectives of this thesis were to examine a number of factors that potentially affect the outcome of TTX, and to apply TTX using immature bison and deer donors as models for endangered ungulates. The objective of the first experiment was to examine the effects of recipient mouse strain, gender and gonadal status on the outcome of TTX. Eight small fragments of neonatal porcine testis tissue (~5 mg each) were grafted under the back skin of immunodeficient mice of different strains (SCID vs. nude), gender (male vs. female), and gonadal status (intact vs. gonadectomised), using a 2×2×2 factorial design (8 groups, n = 7 mice/group). The xenografts were recovered at 8 mo post-grafting and evaluated for gross and histological attributes. Gonadectomy of the recipients did not affect any of the measured outcomes of TTX (P > 0.05), and data were pooled into four groups based on recipient strain and gender. Overall, male recipient mice had grafts with higher mean (+SEM) recovery rate (97 ± 2.3% vs. 88 ± 2.4%, P = 0.004), weight (348 ± 26.3 vs. 104 ± 27.0 mg, P < 0.001), seminiferous tubular diameter (150 ± 3.3 vs. 108 ± 5.3 mg, P < 0.001), percentage of tubules containing spermatozoa (32 ± 3.2 vs. 6 ± 1.8%, P < 0.001), elongated spermatids (13 ± 1.4% vs. 4 ± 0.8%, P < 0.001), and round spermatids (10 ± 1.2% vs. 6 ± 1.1%, P = 0.006) than female mice. Overall, SCID mice had grafts with higher recovery rate (98 ± 2.4% vs. 87 ± 2.3%, P = 0.001), average weight (292 ± 27.0 vs. 160 ± 26.3 mg, P = 0.001), tubular density (44 ± 3.3 vs. 33 ± 2.1, P = 0.02), percentage of tubular cross-sections containing spermatocytes (27 ± 3.7% vs. 13 ± 2.3%, P = 0.003) than nude mice. Among the four groups of recipients, the grafts from male SCID mice had the highest weight (P < 0.05) and percentage of tubules containing spermatozoa (P < 0.05).<p> The objective of the second experiment was to evaluate the effect of using different numbers of donor testis tissue fragments on the outcome of TTX. Fragments of donor piglet testis tissue were grafted subcutaneously under the back skin of four groups of castrated male nude mice (n = 10/group). Each group of recipient mice received 2, 4, 8, or 16 fragments per mouse. Mice were sacrificed at 8 mo post-grafting, and xenografts were evaluated for physical growth and histological development. The relative weight of the vesicular gland (index) was also determined as a measure of bioactive androgen production by grafts in castrated recipient mice. The overall graft recovery rate was ~94% (range 86-98%) which did not differ among the groups (P > 0.05). The group of mice that received 16 testis tissue fragments had higher mean (+ SEM) graft weights (278 ± 39.4 vs. 106 ± 38.0, P = 0.02), total graft weight (2,443 ± 338.8 vs. 192 ± 76.2, P < 0.001), vesicular gland index (0.5 ± 0.06 vs. 0.1 ± 0.06, P = 0.007), and percentage of seminiferous tubules with round spermatids (11 ± 1.5 vs. 3 ± 1.3, P = 0.03) than the group of mice that received two testis tissue fragments. The objective of the third experiment was to assess the use to salvage testis tissue from neonatal/immature bison or deer donors using TTX into immunodeficient recipient mice as models for closely-related rare or endangered ungulates. Donor testis tissue fragments from two newborn bison calves (Bison bison bison) and a 2-mo-old white-tailed deer fawn (Odocoileus virginianus) were grafted under the back skin of gonadectomised nude mice (n = 15 and n = 7 for bison and deer groups, respectively, 8 testis fragments/mouse). To examine the potential effect of individual donors, we grafted four testis tissue fragments from one bison calf on one side of the recipient and four fragments from the second bison calf on the other side. Single grafts were surgically removed from representative recipient mice every 2 mo for up to 16- and 14 mo post-grafting, for bison and deer groups, respectively. The overall graft recovery rates were 69% and 63% for bison and deer groups, respectively. For bison grafts, a donor effect on efficiency of spermatogenesis was also observed. The weight of bison testis tissue xenografts increased (P < 0.02) ~4-fold by 2 mo and ~10-fold by 16 mo post-grafting, and gradual maturational changes were evident in the form of seminiferous tubule expansion starting at 2 mo, first appearance of spermatocytes at 6 mo, round spermatids at 12 mo, and elongated spermatids at 16 mo post-grafting. Testis tissue xenografts from donor white-tailed deer also showed a gradual development starting with tubular expansion by 2 mo and presence of spermatocytes by 6 mo post-grafting, round and elongated spermatids by 8 mo, followed by fully-formed spermatozoa by 12 mo post-grafting. The timing of complete spermatogenesis roughly corresponded to the reported timing of sexual maturation in these species.<p> Taken together, the findings in this thesis suggest that male SCID mice provide a more suitable recipient model for TTX with neonatal porcine testis tissue; recipient mice can be grafted with as many as 16 testis tissue fragments for optimal results; and that TTX is a feasible strategy for salvaging genetic materials from immature males of rare or endangered ungulates that die prematurely. Xenografting immunodeficient mice endangered animals Testis
2	The study and application of testis tissue xenografting Abbasi, Sepideh 30 June 2010 (has links) Testis tissue xenografting (TTX) provides a novel in vivo model for the study of testis function, and a previously-unavailable opportunity to produce spermatozoa in the grafts from immature donors of diverse species. The overall objectives of this thesis were to examine a number of factors that potentially affect the outcome of TTX, and to apply TTX using immature bison and deer donors as models for endangered ungulates. The objective of the first experiment was to examine the effects of recipient mouse strain, gender and gonadal status on the outcome of TTX. Eight small fragments of neonatal porcine testis tissue (~5 mg each) were grafted under the back skin of immunodeficient mice of different strains (SCID vs. nude), gender (male vs. female), and gonadal status (intact vs. gonadectomised), using a 2×2×2 factorial design (8 groups, n = 7 mice/group). The xenografts were recovered at 8 mo post-grafting and evaluated for gross and histological attributes. Gonadectomy of the recipients did not affect any of the measured outcomes of TTX (P > 0.05), and data were pooled into four groups based on recipient strain and gender. Overall, male recipient mice had grafts with higher mean (+SEM) recovery rate (97 ± 2.3% vs. 88 ± 2.4%, P = 0.004), weight (348 ± 26.3 vs. 104 ± 27.0 mg, P < 0.001), seminiferous tubular diameter (150 ± 3.3 vs. 108 ± 5.3 mg, P < 0.001), percentage of tubules containing spermatozoa (32 ± 3.2 vs. 6 ± 1.8%, P < 0.001), elongated spermatids (13 ± 1.4% vs. 4 ± 0.8%, P < 0.001), and round spermatids (10 ± 1.2% vs. 6 ± 1.1%, P = 0.006) than female mice. Overall, SCID mice had grafts with higher recovery rate (98 ± 2.4% vs. 87 ± 2.3%, P = 0.001), average weight (292 ± 27.0 vs. 160 ± 26.3 mg, P = 0.001), tubular density (44 ± 3.3 vs. 33 ± 2.1, P = 0.02), percentage of tubular cross-sections containing spermatocytes (27 ± 3.7% vs. 13 ± 2.3%, P = 0.003) than nude mice. Among the four groups of recipients, the grafts from male SCID mice had the highest weight (P < 0.05) and percentage of tubules containing spermatozoa (P < 0.05).<p> The objective of the second experiment was to evaluate the effect of using different numbers of donor testis tissue fragments on the outcome of TTX. Fragments of donor piglet testis tissue were grafted subcutaneously under the back skin of four groups of castrated male nude mice (n = 10/group). Each group of recipient mice received 2, 4, 8, or 16 fragments per mouse. Mice were sacrificed at 8 mo post-grafting, and xenografts were evaluated for physical growth and histological development. The relative weight of the vesicular gland (index) was also determined as a measure of bioactive androgen production by grafts in castrated recipient mice. The overall graft recovery rate was ~94% (range 86-98%) which did not differ among the groups (P > 0.05). The group of mice that received 16 testis tissue fragments had higher mean (+ SEM) graft weights (278 ± 39.4 vs. 106 ± 38.0, P = 0.02), total graft weight (2,443 ± 338.8 vs. 192 ± 76.2, P < 0.001), vesicular gland index (0.5 ± 0.06 vs. 0.1 ± 0.06, P = 0.007), and percentage of seminiferous tubules with round spermatids (11 ± 1.5 vs. 3 ± 1.3, P = 0.03) than the group of mice that received two testis tissue fragments. The objective of the third experiment was to assess the use to salvage testis tissue from neonatal/immature bison or deer donors using TTX into immunodeficient recipient mice as models for closely-related rare or endangered ungulates. Donor testis tissue fragments from two newborn bison calves (Bison bison bison) and a 2-mo-old white-tailed deer fawn (Odocoileus virginianus) were grafted under the back skin of gonadectomised nude mice (n = 15 and n = 7 for bison and deer groups, respectively, 8 testis fragments/mouse). To examine the potential effect of individual donors, we grafted four testis tissue fragments from one bison calf on one side of the recipient and four fragments from the second bison calf on the other side. Single grafts were surgically removed from representative recipient mice every 2 mo for up to 16- and 14 mo post-grafting, for bison and deer groups, respectively. The overall graft recovery rates were 69% and 63% for bison and deer groups, respectively. For bison grafts, a donor effect on efficiency of spermatogenesis was also observed. The weight of bison testis tissue xenografts increased (P < 0.02) ~4-fold by 2 mo and ~10-fold by 16 mo post-grafting, and gradual maturational changes were evident in the form of seminiferous tubule expansion starting at 2 mo, first appearance of spermatocytes at 6 mo, round spermatids at 12 mo, and elongated spermatids at 16 mo post-grafting. Testis tissue xenografts from donor white-tailed deer also showed a gradual development starting with tubular expansion by 2 mo and presence of spermatocytes by 6 mo post-grafting, round and elongated spermatids by 8 mo, followed by fully-formed spermatozoa by 12 mo post-grafting. The timing of complete spermatogenesis roughly corresponded to the reported timing of sexual maturation in these species.<p> Taken together, the findings in this thesis suggest that male SCID mice provide a more suitable recipient model for TTX with neonatal porcine testis tissue; recipient mice can be grafted with as many as 16 testis tissue fragments for optimal results; and that TTX is a feasible strategy for salvaging genetic materials from immature males of rare or endangered ungulates that die prematurely. Xenografting immunodeficient mice endangered animals Testis
3	Terapie nádorových onemocnění pomocí kotvených agonistů fagocytárních receptorů. Studium mechanismů pomocí imunodeficientních myší / Cancer therapy based on the use of the anchored agonists of phagocytic receptors. The study of mechanisms using immunodeficient mice WALDMANNOVÁ, Eva January 2014 (has links) The aim of this thesis was to study the mechanisms of innate imunity involved in the degradation of tumor cells on which the ligands of phagocytic receptors were installed. For this purpose both in vivo experiments using immunodeficient mice, and in vitro experiments based on monitoring the levels of inflammatory cytokines produced in the tumor tissue and on measuring the level of myeloperoxidase released during neutrophil degranulation were performed.
4	Measles Virotherapy in Adult T cell Leukemia Machado Parrula, Maria Cecilia January 2009 (has links) No description available. Oncology Virology HTLV-1 ATL measles immunodeficient mice type I interferon cotton rat
5	In Vivo Studies of the Foreign Body Reaction to Biomedical Polymers Yang, Jung Hoon 19 August 2013 (has links) No description available. Biomedical Engineering Foreign Body Reaction Foreign Body Giant Cell Formation Immunodeficient Mice siRNA Fibrous Capsule down regulation
6	Análise da função vascular de tumores gerados com linhagem de melanoma humano BRAFV600E em camundongos expostos a atividade física voluntária / Analysis of vascular function of tumors generated with BRAFV600E human melanoma cell line in mice exposed to voluntary physical activity Mororó, Janio da Silva 01 February 2019 (has links) A vasculatura tumoral é estrutural e funcionalmente anormal em relação à vasculatura de órgãos normais, resultando em regiões de heterogeneidade intratumoral para concentração de oxigênio, nutrientes e células inflamatórias. Com isso a vascularização disfuncional muitas vezes leva à administração ineficiente de drogas, comprometendo portanto a eficácia do tratamento. Recentemente, foi demonstrado que terapias antiangiogênicas e exercícios físicos poderiam \"normalizar\" a vasculatura tumoral, melhorando a sobrevida em pacientes com câncer. No entanto seria importante analisar se em melanomas portadores da mutação BRAFV600E, que são altamente resistentes a terapia, se o exercício promoveria a normalização vascular. Este trabalho teve como objetivo analisar o impacto do exercício físico voluntário na função vascular de melanomas humanos com mutação BRAFV600E em camundongos imunodeficientes (BALB/c Nude). Em relação ao crescimento tumoral, não observamos diferenças significativas entre os grupos dos animais exercitados e sedentários, tampouco diferença nos níveis de expressão de genes característicos de macrófagos M1 e M2 no microambiente tumoral desses animais. Por outro lado, a análise de expressão de genes nas células tumorais demonstrou que 8 genes foram diferencialmente expressos no Grupo exercitado ( < 4 km) em relação ao Grupo Sedentário, dentre os quais: FLOT2, STK4, STAT3, LATS1, PTEN, MCL1, PCNA e ACTA2. Em adição, não observamos diferenças significativas no percentual de área necrótica, hipóxica e vasos CD31 positivos. Desse modo, concluímos que o exercício físico induz um aumento nos níveis de expressão de genes envolvidos em modificações epigenéticas, apoptose, proliferação e sobrevivência, ciclo celular e motilidade célula / The tumor vasculature is structurally and functionally abnormal in relation to the vasculature of normal organs, resulting in regions of intratumoral heterogeneity for oxygen parcial pressure, nutrients and inflammatory cells. Thus dysfunctional vascularization often leads to inefficient drug delivery, thereby compromising the efficacy of treatment. Recently, it has been demonstrated that anti-angiogenic therapies and physical exercises could \"normalize\" tumor vasculature, improving survival in patients with cancer. However, it would be important to analyze in BRAFV600E melanoma tumors, which are highly resistant to therapy, whether exercise would promote vascular normalization. Based on this, this work aimed to analyze the impact of voluntary physical exercise on the vascular function of human melanomas with BRAFV600E mutation in immunodeficient mice (BALB / c Nude). In relation to the tumor growth, we did not observe significant differences between the groups of the exercised and sedentary animals, neither difference in the expression levels of genes characteristic of M1 and M2 macrophages in the tumor microenvironment of these animals. On the other hand, analysis of gene expression in tumor cells showed that 8 genes were differentially expressed in the exercised group ( < 4 km) in comparision to the Sedentary Group, among them: FLOT2, STK4, STAT3, LATS1, PTEN, MCL1, PCNA and ACTA2. In addition, we did not observe any significant differences in the percentage of necrotic, hypoxic area and CD31 positive vessels. Thus, we concluded that physical exercise induces an increase in the expression levels of genes involved in epigenetic modifications, apoptosis, proliferation and survival, cell cycle and cell motility Análise por Fluidgm BRAFV600E BRAFV600E Camundongo imunodeprimido Drug resistance Exercício Exercise Fluidigm analysis Human melanoma Immunodeficient mice Melanoma humano Normalização vascular Resistência a drogas Vascular normalization
7	Vývoj protektivní imunitní odpovědi v žaludečním epitelu myší infikovaných \kur{Cryptosporidium muris} a \kur{Cryptosporidium andersoni} / Development of protective immune response in gastric mucosa of mice infected with \kur{Cryptosporidium muris} and \kur{Cryptosporidium andersoni} JALOVECKÁ, Marie January 2011 (has links) The development of immune response accountable for the ability to control Cryptosporidium muris TS03 infection was studied using immunocompetent and various types of immunodeficient mouse models. Subsequently the immune response was characterized by analysis of leukocyte infiltration and cytokine production in gastric epithelium. Moreover, the potentiality of immunocompetent mice to develop effective immune response to C. andersoni LI03 infection with consequent protection to consequent infection of the same mice with C. muris TS03 was also studied by monitoring oocysts shedding, leukocyte infiltration of the gastric mucosa and cytokine production in ex vivo cultures of splenocytes.

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