Global ETD Search

1	Glia und hämatopoetische Zellen im zentralen Nervensystem Priller, Josef 02 July 2002 (has links) Gentherapie und Zellersatz im zentralen Nervensystem (ZNS) werden durch die Blut-Hirn-Schranke behindert, die den Übertritt von Plasmabestandteilen und Zellen in das ZNS limitiert. Genetisch modifizierte Knochenmarkszellen können jedoch ungeachtet der intakten Blut-Hirn-Schranke in das ZNS einwandern und dort zu Mikroglia differenzieren. Neurone signalisieren eine Schädigung an benachbarte Glia und rekrutieren Zellen hämatopoetischen Ursprungs gezielt an den Ort der Läsion. Aus adulten Stammzellen des Knochenmarks können schliesslich Nervenzellen entstehen, die in die komplexe Architektur des ZNS integriert werden. Die Befunde liefern neue Ansätze für die Therapie von ZNS-Erkrankungen. / Gene therapy and cell replacement strategies in the central nervous system (CNS) are hindered by the presence of the blood-brain barrier, which restricts access of serum constituents and peripheral cells to the CNS. Genetically modified bone marrow-derived cells are capable of entering the CNS in spite of the blood-brain barrier and they differentiate into microglia. Neurons signal damage to neighbouring glia and recruit cells of hematopoietic origin specifically to the sites of damage. Finally, adult bone marrow stem cells may generate new neurons which are incorporated into the complex cytoarchitecture of the CNS. The results provide a new approach for the therapy of CNS disorders. Nervensystem Knochenmarkstransplantation GFP Gentransfer nervous system bone marrow transplantation GFP gene transfer 610 Medizin 33 Medizin YG 4300 ddc:610
2	Oral and Intravenous Itraconazole for Systemic Fungal Infections in Neutropenic Haematological Patients: Meeting Report Prentice, H. Grant, Caillot, Denis, Dupont, B., Menichetti, F., Schuler, Ulrich 18 March 2014 (has links) (PDF) Effective prevention, or treatment, of invasive fungal infection in the neutropenic patient has hitherto been unsatisfactory because of either an inadequate anti-fungal spectrum of the agent or important toxicity. Itraconazole is effective against a broad spectrum of the opportunistic pathogens seen in Europe and North America. Prior problems with absorption, e.g. in the marrow transplant recipient, have been overcome with the introduction of an oral solution and an i.v. preparation. The deliberations of an expert meeting held in June, 1998 include recommendations on which patient requires one of these new preparations based on clinical trials, the dose and route. Important drug interactions are also detailed. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. Neutropenie hämatologisch Bösartigkeit Knochenmarkstransplantation Pilzinfektion systemisch Stammzelltransplantation Bone marrow transplantation Fungal infection systemic Itraconazole Malignancy haematological Neutropenia ddc:570 ddc:610 rvk:WA 15000 rvk:XA 10000
3	Die Funktion der inflammatorischen CCR2+ Monozyten bei der postnatalen Mikrogliaentwicklung und bakteriellen Meningitis / The function of inflammatory CCR2+ monocytes in the postnatal microglia development and bacterial meningitis Mildner, Alexander 23 January 2008 (has links) No description available. 570 Biowissenschaften, Biologie MED341 Mathematics and Natural Science Mikroglia bakterielle Meningitis Monozyten Knochenmarkstransplantation Microglia bacterial meningitis monocytes bone marrow reconstitution 42.15 44.45
4	Immunogeneic Cell Populations of the Skin / Pattern of Dendritic Cells and T Cells in Healthy Skin and in Skin of Patients During Allogeneic Hematopoietic Stem Cell Transplantation Eger, Lars 17 June 2008 (has links) (PDF) Dendritic cells (DCs), a hematopoietic cell type belonging to the sub-group of cells called antigen presenting cells (APCs), inhabit a central role in innate and adaptive immunity. Although the DC family is very heterogeneous, all members share unique features. Most importantly, DCs can stimulate an immune response. This is due to the cells’ ability to capture and process antigens and to maturate in the presence of danger signals presented by pathogens. Maturation in turn results in the migration of DCs from the tissue they reside in to the draining lymph nodes, as well as in the subsequent presentation of the acquired antigens to T cells. In the skin, which is one of the most immunogeneic organs, DCs are present in sizable numbers in both the epidermis and the dermis. This study focused on two types of DCs: epidermal Langerhans cells (LCs) and dermal DCs (DDCs). While much is understood about LCs, far less is known about the role that DDCs play in skin immunity. Therefore one purpose of this study was to characterize DDCs and to compare their phenotype and functions to that of LCs. This study used two different methods to characterize human skin resident immune cells with regard to their number and distribution. First, a stable analytical immunohistochemistry-based method was developed and applied to a substantial number of healthy skin donors. This enabled a quantitative analysis of skin DC types and skin resident T cells at different anatomical locations in situ. A novel method to count dermal cell populations in situ was developed that resulted in the first published quantification of APCs, DDCs, as well as T cells in human dermis. Second, the traditional form of the emigration assay, which selectively enriches vital cells capable of ex vivo emigration from the skin, was upgraded toward a stable analytical method to separate epidermal LCs from DDCs. In this way, both skin DC types became accessible in sufficient numbers to allow for a comparison of phenotypes and functions in vitro. The resulting phenotypic observations clearly showed that both, LCs and DDCs are not fully mature after their emigration ex vivo and that both can be transformed into a phenotypically more mature state by treating them with inflammatory cytokines. What’s more, LCs are also functionally in an immature state after their emigration. They efficiently took up antigen, showed a low capacity to trans-migrate in response to chemokines, and demonstrated a low capacity to stimulate allogeneic T cells in a mixed leukocyte reaction (MLR). For the first time this study observed all these main APC functions not only for LCs but additionally for DDCs. As these observations were made in relation to LCs of the same donor, it could be concluded that DDCs are functionally more mature than LCs after emigration. DDCs showed a lower antigen uptake capacity than LCs but were superior in terms of their migratory and stimulatory capacity. However, treatment with cytokines could skew LC functions toward functional capacities observed for DDCs, i.e., it decreased LCs’ Ag uptake and increased their migratory and stimulatory capacity, whereas the cytokine treatment did not alter DDCs’ functional capacities. After improving immuno-histochemistry and the emigration assay using healthy skin samples, these newly developed techniques were implemented in clinical trials to observe the number, distribution and migratory capacity of skin DCs and T cells in patients undergoing allogeneic hematopoietic cell transplantation (aHSCT). Such a study is of importance because the turnover of DCs and T cells is closely associated with the occurrence of acute graft-versus-host disease (aGvHD), the major cause of morbidity and mortality after aHSCT. Due to the study design used, this study concisely demonstrate that at the onset of aGvHD, different DC types accumulate along with effector T cells in skin lesions of aGvHD but not in uninvolved skin of the same patient. These results suggest that in addition to donor T cells LCs and DDCs play a role during the early phase of cutaneous aGvHD directly within the site of inflammation. The view of many authors that DC depletion in the transplant recipient, especially in target organs, is a promising approach for aGvHD prophylaxis and therapy is further underscored by these results. One targeting strategy to inhibit GvHD by eliminating recipient DCs may be the use of DC specific monoclonal antibodies. Alemtuzumab (anti-CD52) is a monoclonal antibody and has proven effective in preventing aGvHD after aHSCT. It may, despite depleting donor T cells, also work by targeting recipient DCs. To determine whether the last mechanism of action is significant, a second clinical study investigated the effects of intravenous alemtuzumab on DCs by comparing the number of these cells in skin and blood of patients before and after a 4-week course of alemtuzumab treatment. The result was that although skin DCs weakly express the target antigen CD52 the number of these cells was not consistently reduced by alemtuzumab. In contrast, circulating blood DCs have a stronger CD52 expression and were significantly reduced by the treatment. In conclusion, this work provides new insights into the phenotypical and functional characteristics of human skin DCs, as well as into the fate of these cell types during aHSCT. The investigation of the APC system during aGvHD as carried out here will help to understand the process of aGvHD in more detail. All these efforts may hopefully support the development of new approaches for therapy and prevention of this major limitation of aHSCT and may help to improve this only curative therapy for several life-threatening diseases. dendritic cell Langerhans cell dermal dendritic cell bone marrow transplantation graft versus host disease allogeneic dendritsche Zelle Langerhans Zelle dermal dendritische Zelle Knochenmarkstransplantation Transplantat gegen Wirt Reaktion ddc:570 rvk:WF 9890
5	Oral and Intravenous Itraconazole for Systemic Fungal Infections in Neutropenic Haematological Patients: Meeting Report Prentice, H. Grant, Caillot, Denis, Dupont, B., Menichetti, F., Schuler, Ulrich January 1999 (has links) Effective prevention, or treatment, of invasive fungal infection in the neutropenic patient has hitherto been unsatisfactory because of either an inadequate anti-fungal spectrum of the agent or important toxicity. Itraconazole is effective against a broad spectrum of the opportunistic pathogens seen in Europe and North America. Prior problems with absorption, e.g. in the marrow transplant recipient, have been overcome with the introduction of an oral solution and an i.v. preparation. The deliberations of an expert meeting held in June, 1998 include recommendations on which patient requires one of these new preparations based on clinical trials, the dose and route. Important drug interactions are also detailed. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. info:eu-repo/classification/ddc/570 ddc:570 info:eu-repo/classification/ddc/610 ddc:610
6	Immunogeneic Cell Populations of the Skin: Pattern of Dendritic Cells and T Cells in Healthy Skin and in Skin of Patients During Allogeneic Hematopoietic Stem Cell Transplantation Eger, Lars 29 April 2008 (has links) Dendritic cells (DCs), a hematopoietic cell type belonging to the sub-group of cells called antigen presenting cells (APCs), inhabit a central role in innate and adaptive immunity. Although the DC family is very heterogeneous, all members share unique features. Most importantly, DCs can stimulate an immune response. This is due to the cells’ ability to capture and process antigens and to maturate in the presence of danger signals presented by pathogens. Maturation in turn results in the migration of DCs from the tissue they reside in to the draining lymph nodes, as well as in the subsequent presentation of the acquired antigens to T cells. In the skin, which is one of the most immunogeneic organs, DCs are present in sizable numbers in both the epidermis and the dermis. This study focused on two types of DCs: epidermal Langerhans cells (LCs) and dermal DCs (DDCs). While much is understood about LCs, far less is known about the role that DDCs play in skin immunity. Therefore one purpose of this study was to characterize DDCs and to compare their phenotype and functions to that of LCs. This study used two different methods to characterize human skin resident immune cells with regard to their number and distribution. First, a stable analytical immunohistochemistry-based method was developed and applied to a substantial number of healthy skin donors. This enabled a quantitative analysis of skin DC types and skin resident T cells at different anatomical locations in situ. A novel method to count dermal cell populations in situ was developed that resulted in the first published quantification of APCs, DDCs, as well as T cells in human dermis. Second, the traditional form of the emigration assay, which selectively enriches vital cells capable of ex vivo emigration from the skin, was upgraded toward a stable analytical method to separate epidermal LCs from DDCs. In this way, both skin DC types became accessible in sufficient numbers to allow for a comparison of phenotypes and functions in vitro. The resulting phenotypic observations clearly showed that both, LCs and DDCs are not fully mature after their emigration ex vivo and that both can be transformed into a phenotypically more mature state by treating them with inflammatory cytokines. What’s more, LCs are also functionally in an immature state after their emigration. They efficiently took up antigen, showed a low capacity to trans-migrate in response to chemokines, and demonstrated a low capacity to stimulate allogeneic T cells in a mixed leukocyte reaction (MLR). For the first time this study observed all these main APC functions not only for LCs but additionally for DDCs. As these observations were made in relation to LCs of the same donor, it could be concluded that DDCs are functionally more mature than LCs after emigration. DDCs showed a lower antigen uptake capacity than LCs but were superior in terms of their migratory and stimulatory capacity. However, treatment with cytokines could skew LC functions toward functional capacities observed for DDCs, i.e., it decreased LCs’ Ag uptake and increased their migratory and stimulatory capacity, whereas the cytokine treatment did not alter DDCs’ functional capacities. After improving immuno-histochemistry and the emigration assay using healthy skin samples, these newly developed techniques were implemented in clinical trials to observe the number, distribution and migratory capacity of skin DCs and T cells in patients undergoing allogeneic hematopoietic cell transplantation (aHSCT). Such a study is of importance because the turnover of DCs and T cells is closely associated with the occurrence of acute graft-versus-host disease (aGvHD), the major cause of morbidity and mortality after aHSCT. Due to the study design used, this study concisely demonstrate that at the onset of aGvHD, different DC types accumulate along with effector T cells in skin lesions of aGvHD but not in uninvolved skin of the same patient. These results suggest that in addition to donor T cells LCs and DDCs play a role during the early phase of cutaneous aGvHD directly within the site of inflammation. The view of many authors that DC depletion in the transplant recipient, especially in target organs, is a promising approach for aGvHD prophylaxis and therapy is further underscored by these results. One targeting strategy to inhibit GvHD by eliminating recipient DCs may be the use of DC specific monoclonal antibodies. Alemtuzumab (anti-CD52) is a monoclonal antibody and has proven effective in preventing aGvHD after aHSCT. It may, despite depleting donor T cells, also work by targeting recipient DCs. To determine whether the last mechanism of action is significant, a second clinical study investigated the effects of intravenous alemtuzumab on DCs by comparing the number of these cells in skin and blood of patients before and after a 4-week course of alemtuzumab treatment. The result was that although skin DCs weakly express the target antigen CD52 the number of these cells was not consistently reduced by alemtuzumab. In contrast, circulating blood DCs have a stronger CD52 expression and were significantly reduced by the treatment. In conclusion, this work provides new insights into the phenotypical and functional characteristics of human skin DCs, as well as into the fate of these cell types during aHSCT. The investigation of the APC system during aGvHD as carried out here will help to understand the process of aGvHD in more detail. All these efforts may hopefully support the development of new approaches for therapy and prevention of this major limitation of aHSCT and may help to improve this only curative therapy for several life-threatening diseases. info:eu-repo/classification/ddc/570 ddc:570

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