Inge M. Ambros
YOU?
Author Swipe
View article: International neuroblastoma risk group consortium: a model of networking for rare cancers
International neuroblastoma risk group consortium: a model of networking for rare cancers Open
It is critical to share knowledge and harmonize approaches to optimize progress in rare cancers. The International Neuroblastoma Risk Group (INRG) Task Force was formed by the 4 major neuroblastoma cooperative groups in 2004 to achieve thi…
View article: Data from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Data from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Purpose: Tumor relapse is the most frequent cause of death in stage 4 neuroblastomas. Since genomic information on the relapse precursor cells could guide targeted therapy, our aim was to find the most appropriate tissue for identifying re…
View article: Supplementary Table S1 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S1 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S1. Tumor cell content of samples of the single neuroblastoma patient
View article: Supplementary Table S5 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S5 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S5. Presence of 1q, 19q, and ATRX deletions in samples of patients with these aberrations
View article: Supplementary Table S7 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S7 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S7. Effect of low expression of some genes located at 1q or 19q on survival of neuroblastoma patients according to different datasets in R2 database
View article: Supplementary Table S7 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S7 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S7. Effect of low expression of some genes located at 1q or 19q on survival of neuroblastoma patients according to different datasets in R2 database
View article: Supplementary Table S2 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S2 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S2. Samples' information and clinical information of stage 4 neuroblastoma patients included in the cohort
View article: Supplementary Table S6 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S6 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S6. Genes in the SROs of 1q and 19 deletions
View article: Supplementary Table S4 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S4 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S4. Focal copy number aberrations detected in the relapse samples
View article: Supplementary Table S5 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S5 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S5. Presence of 1q, 19q, and ATRX deletions in samples of patients with these aberrations
View article: Supplementary Table S3 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S3 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S3. Chromosomal aberrations and corresponding breakpoints and their subclonal frequencies in various samples of the single neuroblastoma patient
View article: Supplementary Table S4 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S4 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S4. Focal copy number aberrations detected in the relapse samples
View article: Supplementary Figures S1-S8 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Figures S1-S8 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Fig. S1: Stepwise accumulation of segmental chromosomal aberrations (SCAs) in chromosome 7 of the case study. Supplementary Fig. S2: Whole genome views of 10 different samples of a single stage 4 neuroblastoma patient. Supple…
View article: Supplementary Figures S1-S8 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Figures S1-S8 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Fig. S1: Stepwise accumulation of segmental chromosomal aberrations (SCAs) in chromosome 7 of the case study. Supplementary Fig. S2: Whole genome views of 10 different samples of a single stage 4 neuroblastoma patient. Supple…
View article: Supplementary Table S2 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S2 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S2. Samples' information and clinical information of stage 4 neuroblastoma patients included in the cohort
View article: Supplementary Table S1 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S1 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S1. Tumor cell content of samples of the single neuroblastoma patient
View article: Supplementary Table S6 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S6 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S6. Genes in the SROs of 1q and 19 deletions
View article: Supplementary Table S3 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Supplementary Table S3 from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Supplementary Table S3. Chromosomal aberrations and corresponding breakpoints and their subclonal frequencies in various samples of the single neuroblastoma patient
View article: Data from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone
Data from Impact of Disseminated Neuroblastoma Cells on the Identification of the Relapse-Seeding Clone Open
Purpose: Tumor relapse is the most frequent cause of death in stage 4 neuroblastomas. Since genomic information on the relapse precursor cells could guide targeted therapy, our aim was to find the most appropriate tissue for identifying re…
View article: Human repair‐related Schwann cells adopt functions of antigen‐presenting cells in vitro
Human repair‐related Schwann cells adopt functions of antigen‐presenting cells in vitro Open
The plastic potential of Schwann cells (SCs) is increasingly recognized to play a role after nerve injury and in diseases of the peripheral nervous system. Reports on the interaction between immune cells and SCs indicate their involvement …
View article: Amplification of CDK4 and MDM2: a detailed study of a high-risk neuroblastoma subgroup
Amplification of CDK4 and MDM2: a detailed study of a high-risk neuroblastoma subgroup Open
In neuroblastoma, MYCN amplification and 11q-deletion are important, although incomplete, markers of high-risk disease. It is therefore relevant to characterize additional alterations that can function as prognostic and/or predictive marke…
View article: Human repair-related Schwann cells adopt functions of antigen-presenting cells <i>in vitro</i>
Human repair-related Schwann cells adopt functions of antigen-presenting cells <i>in vitro</i> Open
The plastic potential of Schwann cells (SCs) is increasingly recognized to play a role after nerve injury and in diseases of the peripheral nervous system. In addition, reports on the interaction between SCs and immune cells indicate their…
View article: VP2: Schwann Cells Regulate Neuronal Differentiation by Epidermal Growth Factor-Like Protein 8
VP2: Schwann Cells Regulate Neuronal Differentiation by Epidermal Growth Factor-Like Protein 8 Open
INTRODUCTION: The remarkable plasticity of adult Schwann cells (SCs) allows them to adopt an alternative phenotype with repair-specific functions essential for the regeneration of injured peripheral nerves. However, SC plasticity is also m…
View article: Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging
Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging Open
While the bone marrow attracts tumor cells in many solid cancers leading to poor outcome in affected patients, comprehensive analyses of bone marrow metastases have not been performed on a single-cell level. We here set out to capture tumo…
View article: Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging
Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging Open
MELC (Multi-epitope ligand cartography) multiplex imaging data of our neuroblastoma cohort supporting the publication " Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging". Th…
View article: Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging
Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging Open
MELC (Multi-epitope ligand cartography) multiplex imaging data of our neuroblastoma cohort supporting the publication " Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging". Th…
View article: Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging
Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging Open
MELC (Multi-epitope ligand cartography) multiplex imaging data of our neuroblastoma cohort supporting the publication " Landscape of Bone Marrow Metastasis in Human Neuroblastoma Unraveled by Transcriptomics and Deep Multiplex Imaging". Th…