Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Our poster describes the verification process to development specific pre-clinical mouse specific multiplexed immunofluorescence (mIF) assays. The use of pre-clinical mouse tumor models is widely used to demonstrate efficacy of novel immunotherapies, however a more comprehensive view of their tumor-immune compositions and their relevance to human tumors is needed. The use of specific mouse tissue phenotyping and mIF assays offer the unique advantage of preserving the architectural features of the tumor and revealing the spatial relationships between tumor cells and immune cells.

Description Overview highlighting the use of the InSituPlex® (ISP) a novel, robust mIF assay technology reliant on conjugating DNA barcodes to antibodies and using sequence-specific DNA-DNA hybridization tolabel antibodies for spatial profiling of immuno-oncology targets in FFPE tumor tissue