Your search keyword '"Christina Loh"' showing total 34 results

1. 126 Mapping neuro-oncological cellular landscape of human and mouse brain tumors using imaging mass cytometry

Author

Christina Loh, Qanber Raza, and Nick Zabinyakov

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2023

2. 119 Uncovering spatial biology of mouse tumor immune microenvironment using imaging mass cytometry

Author

Christina Loh, Qanber Raza, Liang Lim, and Thomas D Pfister

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2023

3. 914 A 47-marker immune profiling flow cytometry assay to enable automated and comprehensive antigen-specific immune analysis

Author

Michael Cohen, Christina Loh, Huihui Hao, Stephen Li, Lauren Tracey, and Connie Inlay

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2023

4. 958 Simplifying high-parameter phenotypic and functional characterization of cancer immune cells

Author

Christina Loh, Deeqa Mahamed, Geneve Awong, and Leslie Fung

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2023

5. Multiple tolerance defects contribute to the breach of B cell tolerance in New Zealand Black chromosome 1 congenic mice.

Author

Nan-Hua Chang, Kieran P Manion, Christina Loh, Evelyn Pau, Yuriy Baglaenko, and Joan E Wither

Subjects

Medicine, Science

Abstract

Lupus is characterized by a loss of B cell tolerance leading to autoantibody production. In this study, we explored the mechanisms underlying this loss of tolerance using B6 congenic mice with an interval from New Zealand Black chromosome 1 (denoted c1(96-100)) sufficient for anti-nuclear antibody production. Transgenes for soluble hen egg white lysozyme (sHEL) and anti-HEL immunoglobulin were crossed onto this background and various tolerance mechanisms examined. We found that c1(96-100) mice produced increased levels of IgM and IgG anti-HEL antibodies compared to B6 mice and had higher proportions of germinal center B cells and long-lived plasma cells, suggesting a germinal center-dependent breach of B cell anergy. Consistent with impaired anergy induction, c1(96-100) double transgenic B cells showed enhanced survival and CD86 upregulation. Hematopoietic chimeric sHEL mice with a mixture of B6 and c1(96-100) HEL transgenic B cells recapitulated these results, suggesting the presence of a B cell autonomous defect. Surprisingly, however, there was equivalent recruitment of B6 and c1(96-100) B cells into germinal centers and differentiation to splenic plasmablasts in these mice. In contrast, there were increased proportions of c1(96-100) T follicular helper cells and long-lived plasma cells as compared to their B6 counterparts, suggesting that both B and T cell defects are required to breach germinal center tolerance in this model. This possibility was further supported by experiments showing an enhanced breach of anergy in double transgenic mice with a longer chromosome 1 interval with additional T cell defects.

Published

2017

6. IL-10 Production Is Critical for Sustaining the Expansion of CD5+ B and NKT Cells and Restraining Autoantibody Production in Congenic Lupus-Prone Mice.

Author

Yuriy Baglaenko, Kieran P Manion, Nan-Hua Chang, Eric Gracey, Christina Loh, and Joan E Wither

Subjects

Medicine, Science

Abstract

The development and progression of systemic lupus erythematosus is mediated by the complex interaction of genetic and environmental factors. To decipher the genetics that contribute to pathogenesis and the production of pathogenic autoantibodies, our lab has focused on the generation of congenic lupus-prone mice derived from the New Zealand Black (NZB) strain. Previous work has shown that an NZB-derived chromosome 4 interval spanning 32 to 151 Mb led to expansion of CD5+ B and Natural Killer T (NKT) cells, and could suppress autoimmunity when crossed with a lupus-prone mouse strain. Subsequently, it was shown that CD5+ B cells but not NKT cells derived from these mice could suppress the development of pro-inflammatory T cells. In this paper, we aimed to further resolve the genetics that leads to expansion of these two innate-like populations through the creation of additional sub-congenic mice and to characterize the role of IL-10 in the suppression of autoimmunity through the generation of IL-10 knockout mice. We show that expansion of CD5+ B cells and NKT cells localizes to a chromosome 4 interval spanning 91 to 123 Mb, which is distinct from the region that mediates the majority of the suppressive phenotype. We also demonstrate that IL-10 is critical to restraining autoantibody production and surprisingly plays a vital role in supporting the expansion of innate-like populations.

Published

2016

7. microRNAs regulate cell-to-cell variability of endogenous target gene expression in developing mouse thymocytes.

Author

Rory Blevins, Ludovica Bruno, Thomas Carroll, James Elliott, Antoine Marcais, Christina Loh, Arnulf Hertweck, Azra Krek, Nikolaus Rajewsky, Chang-Zheng Chen, Amanda G Fisher, and Matthias Merkenschlager

Subjects

Genetics, QH426-470

Abstract

The development and homeostasis of multicellular organisms relies on gene regulation within individual constituent cells. Gene regulatory circuits that increase the robustness of gene expression frequently incorporate microRNAs as post-transcriptional regulators. Computational approaches, synthetic gene circuits and observations in model organisms predict that the co-regulation of microRNAs and their target mRNAs can reduce cell-to-cell variability in the expression of target genes. However, whether microRNAs directly regulate variability of endogenous gene expression remains to be tested in mammalian cells. Here we use quantitative flow cytometry to show that microRNAs impact on cell-to-cell variability of protein expression in developing mouse thymocytes. We find two distinct mechanisms that control variation in the activation-induced expression of the microRNA target CD69. First, the expression of miR-17 and miR-20a, two members of the miR-17-92 cluster, is co-regulated with the target mRNA Cd69 to form an activation-induced incoherent feed-forward loop. Another microRNA, miR-181a, acts at least in part upstream of the target mRNA Cd69 to modulate cellular responses to activation. The ability of microRNAs to render gene expression more uniform across mammalian cell populations may be important for normal development and for disease.

Published

2015

8. 104 Comprehensive single-cell immune profiling of lymphoid and peripheral tissues of aged mice using high-parameter flow cytometry by CyTOF technology

Author

Wenxi Xu, Stephen Li, Alexandre Bouzekri, Thomas Pfister, and Christina Loh

Published

2022

9. 49 Immuno-oncology imaging mass cytometry study of the structural and cellular composition of the tumor microenvironment in human cancers

Author

Thomas Pfister, Christina Loh, Sam Lim, Qanber Raza, Shaida Ouladan, and Nick Zabinyakov

Published

2022

10. An Open-Source AI Framework for the Analysis of Single Cells in Whole-Slide Images with a Note on CD276 in Glioblastoma

Author

Islam Alzoubi, Guoqing Bao, Rong Zhang, Christina Loh, Yuqi Zheng, Svetlana Cherepanoff, Gary Gracie, Maggie Lee, Michael Kuligowski, Kimberley L. Alexander, Michael E. Buckland, Xiuying Wang, and Manuel B. Graeber

Subjects

Cancer Research, Oncology, artificial intelligence, bifocal convolutional neural network (BCNN), CD276, image fusion, image segmentation, PathoFusion framework

Abstract

Routine examination of entire histological slides at cellular resolution poses a significant if not insurmountable challenge to human observers. However, high-resolution data such as the cellular distribution of proteins in tissues, e.g., those obtained following immunochemical staining, are highly desirable. Our present study extends the applicability of the PathoFusion framework to the cellular level. We illustrate our approach using the detection of CD276 immunoreactive cells in glioblastoma as an example. Following automatic identification by means of PathoFusion’s bifocal convolutional neural network (BCNN) model, individual cells are automatically profiled and counted. Only discriminable cells selected through data filtering and thresholding were segmented for cell-level analysis. Subsequently, we converted the detection signals into the corresponding heatmaps visualizing the distribution of the detected cells in entire whole-slide images of adjacent H&E-stained sections using the Discrete Wavelet Transform (DWT). Our results demonstrate that PathoFusion is capable of autonomously detecting and counting individual immunochemically labelled cells with a high prediction performance of 0.992 AUC and 97.7% accuracy. The data can be used for whole-slide cross-modality analyses, e.g., relationships between immunochemical signals and anaplastic histological features. PathoFusion has the potential to be applied to additional problems that seek to correlate heterogeneous data streams and to serve as a clinically applicable, weakly supervised system for histological image analyses in (neuro)pathology.

Published

2022

11. Abstract 676: Neuro-oncology imaging mass cytometry panels enable spatial investigation of brain tumor microenvironment

Author

Nick Zabinyakov, Qanber Raza, and Christina Loh

Subjects

Cancer Research, Oncology

Abstract

Brain neoplasms represent a complex form of cancer that is one of the most challenging to classify and treat. Over 120 different tumor subtypes originate from various parts of the central nervous system, which makes identifying the composition of the tumor microenvironment (TME) vital for early assessment of progression, treatment, and prevention. We developed high-plex proteomic analysis tools to thoroughly characterize the TME of both human and mouse brain tissues using Imaging Mass Cytometry™ (IMC™). IMC offers unprecedented insight into the TME by uncovering the spatial distribution of 40-plus distinct molecular markers without autofluorescence, facilitating the research of brain neoplasms. Here, we demonstrate the application of high-plex human and mouse neuro-oncology IMC panels on normal and tumor formalin-fixed paraffin-embedded brain tissues. A basic neurophenotyping panel was developed and used to customize the Maxpar® Human and Maxpar OnDemand™ Mouse Immuno-Oncology IMC Panel Kits. Human and mouse neuro-oncology panels provide deep phenotyping and characterization of brain TME composition. These neuro panels consist of cross-reactive clones and enable flexible panel design for brain-specific research goals, such as brain tumor classification, and assessment of neuronal inflammation, degeneration, and development. We applied the neuro-oncology panels on tissue microarrays (TMAs) containing a variety of human brain tumors and mouse glioblastoma and neuroblastoma tissues. Normal brain tissues were used for comparative analysis as controls. The Hyperion™ Imaging System was utilized to digitize images from the tissues followed by quantitative analysis to assess the cellular composition of normal and cancerous brain TME. We successfully identified major cell populations that make up human and mouse brain matter, such as neurons, astrocytes, microglia, and oligodendrocytes. Various tumor cell phenotypes, resident and infiltrating cells, and resting and activated microglia were detected in multiple tumor subtypes. Subsequent single-cell analysis provided a comprehensive and quantitative assessment of the brain TME in our samples. We classified the distinct states of neurons and quantified myeloid and lymphoid immune cell infiltration across normal, astrocytoma, and glioblastoma tissues. Empowered by high-plex neuro-oncology panels, IMC can accelerate brain tumor research and provide insights into the spatial complexity of neuronal neoplasms. Citation Format: Nick Zabinyakov, Qanber Raza, Christina Loh. Neuro-oncology imaging mass cytometry panels enable spatial investigation of brain tumor microenvironment [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 676.

Published

2023

12. Abstract 5640: Identifying pathophysiological features of mouse tumors using imaging mass cytometry

Author

Qanber Raza, Liang Lim, Thomas D. Pfister, Nick Zabinyakov, and Christina Loh

Subjects

Cancer Research, Oncology

Abstract

Mouse tumor models are widely utilized for cancer studies and preclinical drug development. An obstacle in predicting therapeutic drug efficacy is the ability to quantitatively evaluate the multi-parametric post-treatment response in the tumor microenvironment (TME). Identification of immuno-oncological processes that dictate tumor growth, metastasis, and immune response is essential for selecting promising drug candidates for further clinical evaluation. Imaging Mass Cytometry™ (IMC™) is a vital and proven high-plex imaging technology that enables deep characterization of the complexity and diversity of tumor tissue without disrupting spatial context. The Hyperion™ Imaging System utilizes IMC technology to simultaneously assess 40-plus individual structural and functional markers in tissues, providing unprecedented insight into the organization and function of the TME. We have previously demonstrated the application of IMC in combination with Maxpar® and Maxpar OnDemand™ antibodies to highlight cellular composition of normal mouse tissues. Here, we showcase the Maxpar OnDemand Mouse Immuno-Oncology IMC Panel Kit for application on a variety of mouse tumor tissues. We compiled the antibody panel to quantitatively assess IO-related processes and applied it to a tissue microarray (TMA) containing a large variety of mouse tumors. Antibodies in panel kits were selected from the Maxpar and Maxpar OnDemand catalogs. We digitized high-plex data from mouse tissues using the Hyperion Imaging System and generated images demonstrating the detailed layout of the TME. We further conducted single-cell analysis to identify specific populations of tumor and immune cells in the TME. The Mouse Immuno-Oncology IMC Panel Kit successfully identified pathophysiological processes such as immune cell infiltration and activation, signaling pathway activation, biomarkers of epithelial-to-mesenchymal transition (EMT), metabolic activity, growth, and the tissue architecture of the TME. Single-cell analysis of several highly relevant tumor types separated distinct cellular clusters representing tumor, immune, stromal, and vascular cells. Activation of cellular processes associated with signaling, growth, and metastasis were identified in tumor cells. In addition, cytotoxic and inflammatory activation in lymphoid and myeloid immune cell subtypes were detected. Application of IMC based multiparametric analysis successfully identified the spatial landscape of the TME at single-cell resolution. Quantitative analysis of tumor composition revealed critical insights regarding prognostic parameters such as metastatic and growth potential of tumors, and identification and activation of immune cell infiltrates. Overall, we demonstrate the power of IMC and provide evidence of its successful application in mouse tumor models. For Research Use Only. Not for use in diagnostic procedures. Citation Format: Qanber Raza, Liang Lim, Thomas D. Pfister, Nick Zabinyakov, Christina Loh. Identifying pathophysiological features of mouse tumors using imaging mass cytometry. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5640.

Published

2023

13. Abstract 5142: 50-parameter flow cytometry by CyTOF empowers comprehensive single-cell immune profiling of pulmonary immunosenescence in aged mice

Author

Wenxi Xu, Stephen Li, Alexandre Bouzekri, Lauren Tracey, and Christina Loh

Subjects

Cancer Research, Oncology

Abstract

High-parameter flow cytometry is essential for human and mouse studies to discover novel immunological mechanisms of cancer, infections, and immunosenescence. It plays an increasingly important role in cancer research to ensure clinical therapeutic success but is limited by the large amount of cell samples needed for staining controls. CyTOF® technology has transformed flow cytometry by enabling 50-plus-marker analysis per tube of sample, with easy panel design and no need for single-stained or autofluorescence controls. Flow cytometry by CyTOF provides an efficient and unbiased approach to discovering novel subsets and unique functional states of immune cells, maximizing insights from precious samples. Immunosenescence perturbs lung cancer onset and development, yet the mechanisms remain largely unknown. To study the pulmonary immune populations in aged (75 weeks old) and young adult (6-8 weeks old) mice, we built a 50-parameter panel (2 for single live-cell identification, 6 for live-cell sample barcoding, and 42 for immune profiling). A core panel of 32 antibodies was selected from Standard BioTools™ catalogs to detect key cell lineage and functional surface markers. A complementary panel with 10 Maxpar® antibodies was added to further study functional cell states. Maxpar Pathsetter™ software was used to create an automated analytical model for high-dimensional analysis. The 50-parameter panel successfully identified over 30 lymphoid and myeloid cell subsets including but not limited to T cells, B cells, NK cells, alveolar macrophages (AMs), dendritic cells, and neutrophils. The panel enabled high-fidelity detection of over 15 functional markers mediating proliferation, activation, inhibition, migration, tissue residence, and cellular metabolism. Automated in-depth analysis by Maxpar Pathsetter efficiently identified many aging-associated alterations in cell frequencies and functional states such as the enrichment of PD-1+ T cells and CD27- γδ T cells that could potentially perturb anti-tumor immunity. Moreover, CyTOF technology is uniquely advanced in characterizing autofluorescent cells such as AMs. A pro-inflammatory state (higher expression of MHC-II, CD80, and PD-L1) was specifically defined for AMs in aged lungs. This study demonstrates comprehensive single-cell immune profiling of mouse tissues with the products and solutions provided by Standard BioTools. Both the 50-parameter panel and Maxpar Pathsetter analytical model can be customized for deep characterization of specific immune populations according to the requirements of various cancer studies in mice. By utilizing end-to-end solutions offered by Standard BioTools, flow cytometry by CyTOF can significantly facilitate the mechanistic studies of mouse models to expand the understanding of human cancers and accelerate therapeutic development. Citation Format: Wenxi Xu, Stephen Li, Alexandre Bouzekri, Lauren Tracey, Christina Loh. 50-parameter flow cytometry by CyTOF empowers comprehensive single-cell immune profiling of pulmonary immunosenescence in aged mice. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5142.

Published

2023

14. Abstract 677: Increasing plexity of imaging mass cytometry for tumor tissue analysis

Author

Thomas D. Pfister, Shaida Ouladan, Huihui Yao, Daniel Majonis, Christina Loh, and Nick Zabinyakov

Subjects

Cancer Research, Oncology

Abstract

Imaging Mass Cytometry™ (IMC™) is the leading platform for high-plex tissue imaging. IMC allows for detailed assessment of cell phenotype and function using 40-plus markers simultaneously at subcellular resolution on a single slide. A comprehensive IMC panel containing structural, functional, and immune markers enables us to reveal the complex heterogeneity of tumor tissues as well as the tumor microenvironment (TME). Driven by an increase in the number of antibody markers and the addition of mRNA markers, there is an increasing demand for larger panels. In addition, increasing the number of investigated target markers on a single tissue enriches spatial characterization that may facilitate a more accurate prediction of disease progression and preclinical outcome measures in clinical research projects using tumor biopsies or tissue microarrays (TMAs). Therefore, to increase the plexity of IMC panels, it is essential to expand the number of available metal channels. Here, we demonstrate the incorporation of conjugated antibodies with yttrium (89Y) and indium (115In), two low-mass metals, for IMC application. These metal tags have been previously tested as putative channels for IMC application. We performed IMC analysis of various tissue types stained with panels of conjugated antibodies including the novel 89Y- and 115In-conjugated antibodies. At least 3 different regions of interest (ROIs) were assessed for each of the investigated tissue types. We compared images for the 89Y- and 115In-conjugated antibodies with the images generated using Maxpar® catalog antibodies of the same clones, with a focus on marker specificity and background signal. Compared with the lanthanide-conjugated catalog antibodies, the 89Y- and 115In-conjugated antibodies showed equivalent specificity and staining quality. Our results open a new avenue to assign markers to 89Y and 115In, which enables a larger list of potential targets to be investigated in any IMC study. Expanding the number of markers to 40-plus in Imaging Mass Cytometry will improve the imaging results necessary to identify novel cell signatures (phenotype and interactions) in the TME. Citation Format: Thomas D. Pfister, Shaida Ouladan, Huihui Yao, Daniel Majonis, Christina Loh, Nick Zabinyakov. Increasing plexity of imaging mass cytometry for tumor tissue analysis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 677.

Published

2023

15. Customizing Maxpar Direct Immune Profiling Assay with Additional Surface Marker and Intracellular Cytokine Staining Workflows for Expanded Mass Cytometry Panels

Author

Carlene, Petes, Stephen K H, Li, Shariq, Mujib, Michelle M, Poulin, Noah, Saederup, Andrew A, Quong, and Christina, Loh

Subjects

Staining and Labeling, Intracellular Space, Leukocytes, Mononuclear, Cytokines, Humans, Flow Cytometry, Antibodies, Biomarkers, Immunophenotyping, Workflow

Abstract

Mass cytometry, or cytometry by time-of-flight (the basis for Fluidigm

Published

2021

16. Customizing Maxpar Direct Immune Profiling Assay with Additional Surface Marker and Intracellular Cytokine Staining Workflows for Expanded Mass Cytometry Panels

Author

Michelle M Poulin, Stephen K H Li, Shariq Mujib, Andrew A. Quong, Noah Saederup, Carlene Petes, and Christina Loh

Subjects

Immunophenotyping, Immune system, biology, Chemistry, biology.protein, Mass cytometry, Antibody, Peripheral blood mononuclear cell, Cytometry, Molecular biology, Intracellular, Staining

Abstract

Mass cytometry, or cytometry by time-of-flight (the basis for Fluidigm® CyTOF® technology), is a system for single-cell detection using antibodies tagged with metal probes. Without the need for compensation, the highly parametric Helios™ mass cytometer has a detection range of 135 distinct mass channels (75-209 Da). Optimized for mass cytometry, the Maxpar® Direct™ Immune Profiling Assay™ is a dry, metal-tagged antibody cocktail for immunophenotyping 37 immune cell populations found in human peripheral blood in a single tube. The Maxpar Direct Assay utilizes 31 mass channels for marker detection and live/dead viability staining, with at least 14 additional marker channels available from the Fluidigm catalog for flexible custom panel design. Here, we describe a workflow combining the assay with additional surface and intracellular cytokine antibodies for peripheral blood mononuclear cell (PBMC) staining using lanthanide-, bismuth-, and cadmium-tagged antibodies.

Published

2021

17. Emotional activation in a cognitive behavioral setting: extending the tradition with embodiment

Author

Gernot Hauke, Christina Lohr-Berger, and Tal Shafir

Subjects

embodiment, emotional activation, emotion regulation, CBT, bodily expressions of emotions, levels of emotional awareness, Psychology, BF1-990

Abstract

The neuroscience-based concept of “embodied cognition” or “embodiment” highlights that body and psyche are closely intertwined, i.e., effects of body and psyche are bidirectional and reciprocal. This represents the view that cognitive processes are not possible without the direct participation of the body. Traditional Cognitive Behavioral Therapy (CBT) addresses emotional processes on a conceptual level (dysfunctional thoughts, beliefs, attributions, etc.). However recent findings suggest that these processes already start at the level of bodily sensations. This opens up a way of working in therapy that includes the level of bodily sensations, where the development of emotional meaning is supported by bottom-up processes. Bidirectionality of embodiment can be effectively exploited by using body postures and movements associated with certain emotions, which we refer to as embodiment techniques, to deepen the physical experience of poorly felt emotions and support the valid construction of emotional meaning. This embodied approach offers several advantages: Prelinguistic or hard-to-grasp aspects can be identified more easily before being processed verbally. It is also easier to work with clients who have limited access to their emotions. Thus, in this paper we describe a new embodied CBT approach to working on the dysfunctional schema, which is based on three modules: body focus, emotional field, and interaction focus. In addition, using specific zones in the space of the therapy-room allows the embodiment of problematic interactions, as well as of power and powerlessness, closeness and distance, etc. Directly experiencing these processes on one’s own body in the protected space of therapy allows faster and deeper insights than would be possible with conversations alone. Finally, the vitalizing power of emotions is used to create coherent action plans and successful interactions. This working method is illustrated by means of a case from practice.

Published

2024

18. Abstract 3908: A streamlined and automated approach to high-content cytometric immunophenotyping with CyTOF XT

Author

Thiru Selvanantham, Stephen K.H. Li, Nick Zabinyakov, Alexandre Bouzekri, Raymond Jong, Michael Sullivan, Alexander Laboda, Daniel Majonis, and Christina Loh

Subjects

Cancer Research, Oncology

Abstract

High-parameter immune profiling is crucial in translational and clinical research to quantify changes in immune cell populations over time. CyTOF® mass cytometry is a high-plex, single-cell analysis platform that uses isotopically pure metal-labeled antibodies. The major advantage of CyTOF is its ability to resolve 40-plus markers in a single panel without compensation, making mass cytometry ideal for routine immunophenotyping. The autosampler module of CyTOF XT™ provides significant time savings by allowing automated sample acquisition. Tubes of pelleted stained samples are loaded into the Autosampler carousel, and the samples are resuspended with EQ™ Calibration Beads for acquisition. User input is only required during instrument startup, tuning, and batch setup. The added automation of CyTOF XT provides a streamlined workflow for suspension mass cytometry. Testing was performed to ensure that the data obtained on CyTOF XT was comparable to manual acquisition systems. The performance of CyTOF XT was tested in parallel with its predecessor, Helios™. Several workflows and applications for suspension mass cytometry including sample barcoding with the Cell-ID™ 20-Plex Pd Barcoding Kit, and surface, cytoplasmic, and nuclear staining and phosphostaining were evaluated on human PBMC. Manual gating analysis was performed to assess population frequencies and median intensities for each marker. Resolution index was calculated to assess how well positive and negative populations separated from each other. There was no significant difference between population frequencies analyzed between the two CyTOF systems. Moreover, samples acquired on CyTOF XT, on average, resulted in greater signal resolution between positive and negative populations compared to Helios. The Maxpar Direct Immune Profiling System was also compared on CyTOF XT and Helios using human whole blood and PBMC. The Maxpar® Direct™ Immune Profiling Assay™ and Maxpar Pathsetter™ software were developed as a sample-to-answer system for human immune profiling using CyTOF. The Maxpar Direct Immune Profiling Assay includes an optimized panel of 30 unique markers in a dry, single-tube format. Maxpar Pathsetter is an automated software used to report population statistics, stain assessments, and relevant data plots for the panel. The automated staining assessment in Maxpar Pathsetter was compared between files acquired on CyTOF XT and Helios. Comparable population frequencies were obtained between the two acquisition systems, and improved staining assessment was observed on CyTOF XT. Overall, these studies demonstrate that CyTOF XT generates better signal resolution as compared to Helios. The automated acquisition of CyTOF XT enables researchers to streamline immunophenotyping of human samples while accurately and reproducibly monitoring changes in immune cell subsets. For Research Use Only. Not for use in diagnostic procedures. Citation Format: Thiru Selvanantham, Stephen K.H. Li, Nick Zabinyakov, Alexandre Bouzekri, Raymond Jong, Michael Sullivan, Alexander Laboda, Daniel Majonis, Christina Loh. A streamlined and automated approach to high-content cytometric immunophenotyping with CyTOF XT [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3908.

Published

2022

19. Abstract 2035: Imaging mass cytometry identifies structural and cellular composition of the mouse tissue microenvironment

Author

Qanber Raza, Michael Cohen, Smriti Kala, Liang Lim, Geneve Awong, Andrew Quong, and Christina Loh

Subjects

Cancer Research, Oncology

Abstract

Imaging Mass Cytometry™ (IMC™) is a vital tool to deeply characterize the complexity and diversity of any tissue without disrupting spatial context. The Hyperion™ Imaging System utilizes IMC, based on CyTOF® technology, to simultaneously assess up to 40 individual structural and functional markers in tissues, providing unprecedented insight into the organization and function of tissue microenvironment. We have previously demonstrated the application of IMC in combination with Maxpar® panel kits to highlight cellular composition of human tissues. Here, we showcase the recently released Maxpar OnDemand Antibodies for IMC application on mouse tissue. We introduced 11 additional biomarkers to our existing mouse antibody catalog, providing the basis for the use of high-multiplex imaging in preclinical investigations. To demonstrate the IMC workflow on mouse tissue, we analyzed a normal mouse tissue microarray using IMC spatial proteomic analysis. Tissues were stained with a 20-marker panel designed to highlight tissue architecture and major immune lineage markers combined with our IMC Cell Segmentation Kit*. The IMC Cell Segmentation Kit facilitates identification of cellular borders using plasma membrane markers that lead to improved nucleus and plasma membrane demarcation. We generated a detailed spatial map of the heterogeneous tissue architecture and successfully identified immune, epithelial, and stromal cell populations in various mouse tissues. Additionally, we classified the activation state of immune cell populations, adhesion state of epithelial cells, and molecular composition of the extracellular matrix.Overall, this work demonstrates the capability of IMC to identify subcellular localization of cellular and structural markers in the mouse tissue microenvironment. Information gained from IMC studies will enable in-depth high-throughput phenotypic characterization of the tissue microenvironment in various mouse models of development and disease, and thus accelerate preclinical discoveries. *The IMC Cell Segmentation Kit is part of the Innovative Solutions menu of custom-made reagents and workflows developed and tested by Fluidigm scientists to give faster access to new cutting-edge solutions for high-multiplex single-cell analysis. Innovative Solutions are not part of the Maxpar catalog. For Research Use Only. Not for use in diagnostic procedures. Citation Format: Qanber Raza, Michael Cohen, Smriti Kala, Liang Lim, Geneve Awong, Andrew Quong, Christina Loh. Imaging mass cytometry identifies structural and cellular composition of the mouse tissue microenvironment [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2035.

Published

2022

20. An automated approach to high-plex cytometric immunophenotyping with CyTOF XT

Author

Stephen K.H. Li, Nick Zabinyakov, Alexandre Bouzekri, Rita Straus, Raymond Jong, Michael Sullivan, Alexander Loboda, Daniel Majonis, and Christina Loh

Subjects

Immunology, Immunology and Allergy

Abstract

CyTOF® mass cytometry is a single-cell analysis platform that uses isotope-tagged antibodies to resolve 50-plus markers in a single tube without signal compensation, making CyTOF ideal for routine immunophenotyping. CyTOF XT™, the latest CyTOF system, features automated sample acquisition. Stained samples were acquired in parallel using the automated CyTOF XT system and manually, using the Helios™ system, to assess performance of the automated system. Multiple suspension mass cytometry staining workflows were evaluated. Population frequencies and resolution indices for markers were assessed by manual gating. There was no significant difference between population frequencies analyzed between the two CyTOF systems. On average, samples acquired on CyTOF XT resulted in greater resolution between positive and negative populations compared to Helios. The Maxpar® Direct™ Immune Profiling System, which comprises the Maxpar® Direct™ Immune Profiling Assay™ and Maxpar Pathsetter™ software, was also compared on the CyTOF XT and Helios systems. The Maxpar Direct Immune Profiling Assay includes a 30-marker panel in a dry, single-tube format for staining human whole blood or PBMC. Maxpar Pathsetter automates reporting of population statistics and stain assessments for the panel. Maxpar Pathsetter showed comparable population frequencies between the two CyTOF systems and improved staining assessment on CyTOF XT. Overall, these studies find that the CyTOF XT system generates better signal resolution than the Helios system. Automated acquisition by CyTOF XT enables researchers to accurately and reproducibly streamline human immunophenotyping. For Research Use Only. Not for use in diagnostic procedures.

Published

2022

21. Extending the capabilities of a high-parameter immunophenotyping assay with cytoplasmic staining applications for mass cytometry

Author

Clare E. Rogers, Huihui Yao, Michael Cohen, and Christina Loh

Subjects

Immunology, Immunology and Allergy

Abstract

Maxpar® Direct™ Immune Profiling Assay™ (Cat. No. 201325) is a 30-marker panel for suspension mass cytometry. This panel provides an unprecedented sample-to-answer solution for detecting and analyzing 30 surface markers in a single experiment. The 18 open mass channels in the Maxpar Direct Assay facilitate panel expansion and enable flexibility for higher multiplexity and applications. Among the potential complementary applications, intracellular cytokine staining (ICS) is of particular interest as it may be used to assess infiltrating immune cell phenotypes in the tumor microenvironment. However, for the purpose of assessing cell viability in this workflow, the effectiveness of the Cell-ID™ Intercalator-Rh (103Rh, Cat. No. 201103) included in the Maxpar Direct Assay is in question, as cell permeabilization during ICS can potentially damage the DNA-intercalator bond. In this study, we investigated the compatibility of 103Rh with intracellular staining. We stained either human peripheral blood mononuclear cell or whole blood samples with the Maxpar Direct Assay followed by intracellular staining for the detection of expressed cytokines. We demonstrate that 103Rh provides equivalent functionality as a cell viability indicator during intracellular staining for cytoplasmic proteins compared to the benchmark Cell-ID Cisplatin-194Pt (Cat. No. 201194). This work was designed to support use of the Maxpar Direct Immune Profiling Assay in combination with additional intracellular markers. Overall, these findings expand the applicability of Cell-ID Intercalator-Rh (103Rh) to processes that involve cytoplasmic staining. For Research Use Only. Not for use in diagnostic procedures.

Published

2022

22. Imaging Mass Cytometry identifies structural and cellular composition of the mouse tissue microenvironment

Author

Kerry Lowrie, Qanber Raza, Michael Cohen, Smriti Kala, Geneve Awong, Andrew Quong, and Christina Loh

Subjects

Immunology, Immunology and Allergy

Abstract

Imaging Mass Cytometry™ (IMC™) is a vital tool to deeply characterize the complexity and diversity of any tissue without disrupting spatial context. The Hyperion™ Imaging System utilizes IMC, based on CyTOF® technology, to assess up to 40 individual structural and functional markers in tissues, providing unprecedented insight into the organization and function of tissue microenvironment. We have previously demonstrated the application of IMC in combination with Maxpar® panel kits on human tissues. Here, we showcase Maxpar OnDemand Antibodies for IMC application including 11 new highly relevant markers to construe cellular and molecular composition of mouse tissues. We analyzed a normal mouse tissue microarray using IMC spatial proteomic analysis. Tissues were stained with a 20-marker panel designed to highlight tissue architecture and major immune lineage markers. We generated a detailed spatial map of the diverse tissue architecture and successfully identified immune, epithelial, and stromal cell populations in various mouse tissues. Additionally, we classified the activation state of immune cell populations, adhesion state of epithelial cells, and molecular composition of the extracellular matrix. This work demonstrates the capability of IMC to identify subcellular localization of cellular and structural markers in the mouse tissue microenvironment. Future studies utilizing IMC in combination with Maxpar OnDemand Antibodies will enable in-depth phenotypic characterization of the tissue microenvironment in various mouse models of development and disease, and thus provide the basis for the use of high-multiplex imaging in preclinical investigations. For Research Use Only. Not for use in diagnostic procedures.

Published

2022

23. Abstract 1676: A comprehensive whole blood CyTOF immune monitoring panel with expanded surface and intracellular markers using the Maxpar Direct Immune Profiling Assay

Author

Nick Zabinyakov, Christina Loh, Stephen K H Li, and Shariq Mujib

Subjects

Cancer Research, Myeloid, medicine.medical_treatment, T cell, Immunotherapy, Biology, medicine.anatomical_structure, Immune system, Oncology, Immunology, medicine, biology.protein, Multiplex, Mass cytometry, Antibody, Whole blood

Abstract

In-depth monitoring of the immune response to cancer and infection is vital to ascertain disease status and to assess immunotherapeutic options. Time-of-flight technology, the basis of CyTOF® mass cytometry, enables multiplex proteomic cellular phenotyping with 50 or more markers, making it ideal for comprehensive immune profiling. Unlike fluorescence-dependent approaches, which require signal compensation that makes the development of larger panels more challenging, CyTOF utilizes monoisotopic metal-tagged antibodies that exhibit minimal background signal, enabling the highest-resolution multiparametric landscape of a single cell. The Maxpar® Direct™ Immune Profiling Assay™ is a pre-titrated dried-down 30-antibody cocktail preparation for immune profiling of human whole blood or PBMC. This assay is used with Maxpar Pathsetter™ software, which resolves whole blood into 37 immune populations comprising major lineage populations and their subsets, such as CD4 Th subsets and B and T cell memory cells, as well as stratifications of myeloid populations. The resulting system is a simple sample-to-answer solution for immune monitoring studies. Here, we expanded the 30-marker assay with 14 additional antibodies comprising pertinent targets of immunotherapy, including the exhaustion markers PD-1, PD-L1, Tim-3 and CTLA-4, and co-stimulation markers 4-1BB and ICOS. We also demonstrated the compatibility of the assay with downstream intracellular staining for cytoplasmic markers IFN-γ, TNF-α, IL-2, perforin and granzyme B for assessment of cellular function in 4h PMA/ionomycin-stimulated whole blood cultures. Next, we modified the existing Pathsetter model to automate the analysis of whole blood stained with the expanded panel to generate reports on key immune cell populations, percentages of exhausted cells and cell subsets producing cytokines. Last, to demonstrate the ability of this expanded panel to identify antigen-specific T cell subsets accompanied by their in-depth phenotypic assessment, we tested this panel against CMV peptide-stimulated whole blood samples. We demonstrated the flexibility of the Maxpar Direct Immune Profiling Assay in panel customization and a streamlined workflow for automated analysis to enable comprehensive immune profiling of human whole blood. For Research Use Only. Not for use in diagnostic procedures. Citation Format: Shariq Mujib, Stephen K. Li, Nick Zabinyakov, Christina Loh. A comprehensive whole blood CyTOF immune monitoring panel with expanded surface and intracellular markers using the Maxpar Direct Immune Profiling Assay [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 1676.

Published

2021

24. A single-tube, 44-marker CyTOF assay to assess antigen-specific immunity in whole blood human samples with data analysis solution

Author

Shariq Mujib, Stephen Li, Nick Zabinyakov, and Christina Loh

Subjects

Immunology, Immunology and Allergy

Abstract

Monitoring the immune response in the setting of infectious disease and cancer is critical to assess disease status and targets of immune therapy. CyTOF® mass cytometry enables multiplex cellular phenotyping with more than 50 markers, making it ideal for comprehensive immune profiling. CyTOF technology utilizes antibodies tagged with unique monoisotopic metals, resulting in distinct signals that provide a high-resolution multiparametric landscape of a single cell. The Maxpar® Direct™ Immune Profiling Assay™ is a pre-titrated, dried-down, 30-marker antibody cocktail for immune profiling of human whole blood and PBMC by CyTOF. Paired with Maxpar Pathsetter™ software, stained samples are automatically resolved into 37 immune populations including major lineages and their subsets. In this study, we expanded the 30-marker assay to a 44-marker panel including exhaustion markers such as PD-1 and CTLA-4, co-stimulation markers 4-1BB and ICOS, and intracellular cytoplasmic markers IFN-γ, TNF-α, IL-2, perforin and granzyme B to assess cellular function in PMA/ionomycin-stimulated whole blood cultures. We modified the existing Maxpar Pathsetter model to automate the analysis of the expanded panel and report on additional functional parameters such as T cell exhaustion and cytokine production. Next, we applied this panel to whole blood stimulated with CMV peptides to investigate antigen-specific immune responses in a viral infection model in concert with in-depth phenotypic assessment. Collectively, we demonstrate the flexibility of the Maxpar Direct Immune Profiling Assay to incorporate additional surface and intracellular markers to study antigen-specific immunity in the context of whole blood immune profiling. For RUO.

Published

2021

25. Unusual post-blepharoplasty infection: Gordonia Bronchialis case study

Author

McKenzie E. Maloney, Brennan Bogdanovich, Christina Lohmann, and Brian Maloney

Subjects

Gordonia bronchialis, blepharoplasty, cutaneous infection, cutaneous surgery, post-surgical infection, Dermatology, RL1-803

Abstract

Introduction: Post-procedure infections following in-office blepharoplasty are rare. Gordonia bronchialis is a weakly acid-fast, gram-positive, aerobic Actinomyces that rarely causes infections in humans. Case: A 35-year-old female presented two weeks after an upper blepharoplasty with cyst-like swellings near the incision site. Injection with Kenalog did not resolve the cyst. Histology of the cyst showed benign fibroadipose tissue with noncaseating granulomatous inflammation alongside occasional foreign body giant cells. Anaerobic culture yielded Gordonia Bronchialis. Amoxicillin 750mg QID was prescribed. The infection regressed but reappeared after tapering. A CT scan showed a small retention cyst in the right sphenoid sinus. The patient was then put on amoxicillin and clavulanic acid combination 875 mg BID and Minocycline 100mg BID for 3-4 weeks. After two months of treatment, the infection was cleared. Discussion: Most commonly, post-blepharoplasty infections these infections are due to Mycobacterium. We report a case of G. bronchialis infection following a cutaneous surgery performed in the office.

Published

2024

26. Expanding the capabilities of the Maxpar Direct Immune Profiling Assay with additional markers, and customization of the analysis model in Maxpar Pathsetter

Author

Stephen K.H. Li, Shariq Mujib, Michael Cohen, Huihui Yao, Daniel Majonis, and Christina Loh

Subjects

Immunology, Immunology and Allergy

Abstract

Mass cytometry, which utilizes CyTOF® technology, is a single-cell analysis platform that uses metal-tagged antibodies. CyTOF can resolve more than 50 parameters in a single panel without the need for compensation, making it an ideal solution for routine enumeration of immune cells. The Maxpar® Direct™ Immune Profiling System is a sample-to-answer solution for human immune profiling using mass cytometry. The Maxpar®Direct™ Immune Profiling Assay™ is an optimized 30-marker panel contained in a dry single-tube format for human whole blood or PBMC staining, and samples are acquired on the Helios™ system. Maxpar Pathsetter™ is an automated software that reports cell counts, percentage calculations, and staining intensity. It also produces graphical elements such as dot plots and a Cen-se′™ graph for 37 immune cell populations. The panel can be tailored by adding markers to open channels, the Maxpar Pathsetter model can then be customized to measure expression markers on existing classified populations or identify additional immune cell subsets. We present data where the Maxpar Direct Immune Profiling Assay is used as a core immunophenotyping panel and additional markers are added to create a nearly 50 marker panel. Added markers are used to identify MDSCs, further classify existing cell populations, and measure immuno-oncology related markers including OX40, TIM-3, Fas, PD-1, PD-L1, ICOS, and TIGIT. We demonstrate how the Maxpar Pathsetter model is modified to incorporate the added markers. The ability to customize the Maxpar Pathsetter model and expand the Maxpar Direct Immune Profiling Assay allows for flexibility of the system. It allows researchers to have a streamlined solution for broad immune profiling using mass cytometry.

Published

2020

27. mir-181a-1/b-1 Modulates Tolerance through Opposing Activities in Selection and Peripheral T Cell Function

Author

Robert C. Axtell, Garry P. Nolan, K. Mark Ansel, Christopher P. Arnold, Steven Schaffert, Evan W. Newell, Lawrence Steinman, Song Wang, Chang-Zheng Chen, Christina Loh, and Mark M. Davis

Subjects

Encephalomyelitis, Autoimmune, Experimental, MAP Kinase Signaling System, T cell, Immunology, Oligonucleotides, Receptors, Antigen, T-Cell, Autoimmunity, Context (language use), Biology, medicine.disease_cause, Article, Immune tolerance, Mice, Cell Movement, Dual Specificity Phosphatase 6, Sphingosine, T-Lymphocyte Subsets, Immune Tolerance, medicine, Animals, Immunology and Allergy, Clonal Selection, Antigen-Mediated, Mice, Knockout, Thymocytes, Experimental autoimmune encephalomyelitis, T-cell receptor, medicine.disease, Cell biology, Disease Models, Animal, MicroRNAs, medicine.anatomical_structure, T cell selection, Immunization, RNA Interference, Lysophospholipids, Signal transduction, Gene Deletion, Signal Transduction

Abstract

Understanding the consequences of tuning TCR signaling on selection, peripheral T cell function, and tolerance in the context of native TCR repertoires may provide insight into the physiological control of tolerance. In this study, we show that genetic ablation of a natural tuner of TCR signaling, mir-181a-1/b-1, in double-positive thymocytes dampened TCR and Erk signaling and increased the threshold of positive selection. Whereas mir-181a-1/b-1 deletion in mice resulted in an increase in the intrinsic reactivity of naive T cells to self-antigens, it did not cause spontaneous autoimmunity. Loss of mir-181a-1/b-1 dampened the induction of experimental autoimmune encephalomyelitis and reduced basal TCR signaling in peripheral T cells and their migration from lymph nodes to pathogenic sites. Taken together, these results demonstrate that tolerance can be modulated by microRNA gene products through the control of opposing activities in T cell selection and peripheral T cell function.

Published

2015

28. Scrofuloderma management with scar excision

Author

McKenzie E. Maloney, BS, Christina Lohmann, MD, and Brian Maloney, MD, FACS

Subjects

cutaneous tuberculosis, dermatologic surgery, scar excision, scar revision, scrofuloderma, Dermatology, RL1-803

Published

2023

29. Thalamic haemorrhagic stroke

Author

Daniel Bell and Christina Loh

Published

2015

30. Charcot-Bouchard aneurysm

Author

Sonam Vadera and Christina Loh

Published

2015

31. IL-10 Production Is Critical for Sustaining the Expansion of CD5+ B and NKT Cells and Restraining Autoantibody Production in Congenic Lupus-Prone Mice

Author

Christina Loh, Joan E. Wither, Eric Gracey, Nan-Hua Chang, Yuriy Baglaenko, and Kieran P. Manion

Subjects

0301 basic medicine, B Cells, Physiology, lcsh:Medicine, Autoimmunity, medicine.disease_cause, Biochemistry, White Blood Cells, Spectrum Analysis Techniques, 0302 clinical medicine, Animal Cells, immune system diseases, Immune Physiology, Medicine and Health Sciences, Lupus Erythematosus, Systemic, lcsh:Science, Mice, Knockout, Staining, B-Lymphocytes, Immune System Proteins, Multidisciplinary, Systemic lupus erythematosus, Mice, Inbred NZB, Cell Staining, Animal Models, Flow Cytometry, Natural killer T cell, Interleukin-10, Interleukin 10, Spectrophotometry, Cytophotometry, Cellular Types, Research Article, Immune Cells, Immunology, Congenic, Mouse Models, Biology, CD5 Antigens, Research and Analysis Methods, Systemic Lupus Erythematosus, Antibodies, Autoimmune Diseases, 03 medical and health sciences, Model Organisms, Rheumatology, Genetics, medicine, Animals, Antibody-Producing Cells, Autoantibodies, Blood Cells, Lupus erythematosus, Lupus Erythematosus, lcsh:R, Autoantibody, Biology and Life Sciences, Proteins, Cell Biology, medicine.disease, Chromosomes, Mammalian, 030104 developmental biology, Specimen Preparation and Treatment, Genetic Loci, Natural Killer T-Cells, lcsh:Q, Clinical Immunology, Clinical Medicine, CD5, 030215 immunology

Abstract

The development and progression of systemic lupus erythematosus is mediated by the complex interaction of genetic and environmental factors. To decipher the genetics that contribute to pathogenesis and the production of pathogenic autoantibodies, our lab has focused on the generation of congenic lupus-prone mice derived from the New Zealand Black (NZB) strain. Previous work has shown that an NZB-derived chromosome 4 interval spanning 32 to 151 Mb led to expansion of CD5+ B and Natural Killer T (NKT) cells, and could suppress autoimmunity when crossed with a lupus-prone mouse strain. Subsequently, it was shown that CD5+ B cells but not NKT cells derived from these mice could suppress the development of pro-inflammatory T cells. In this paper, we aimed to further resolve the genetics that leads to expansion of these two innate-like populations through the creation of additional sub-congenic mice and to characterize the role of IL-10 in the suppression of autoimmunity through the generation of IL-10 knockout mice. We show that expansion of CD5+ B cells and NKT cells localizes to a chromosome 4 interval spanning 91 to 123 Mb, which is distinct from the region that mediates the majority of the suppressive phenotype. We also demonstrate that IL-10 is critical to restraining autoantibody production and surprisingly plays a vital role in supporting the expansion of innate-like populations.

Published

2016

32. Piloting the Update: The Use of Therapeutic Relationship for Change – A Free Energy Account

Author

Gernot Hauke and Christina Lohr

Subjects

free energy, active inference, exploration-exploitation-dilemma, therapeutic relationship, cognitive behavioral therapy, safety regulation, Psychology, BF1-990

Abstract

We apply the Free Energy Principle (FEP) to cognitive behavioral therapy (CBT). FEP describes the basic functioning of the brain as a predictive organ and states that any self-organizing system that is in equilibrium with its environment must minimize its free energy. Based on an internal model of the world and the self, predictions—so-called priors—are created, which are matched with the information input. The sum of prediction errors corresponds to the Free Energy, which must be minimized. Internal models can be identified with the cognitive-affective schemas of the individual that has become dysfunctional in patients. The role of CBT in this picture is to help the patient update her/his priors. They have evolved in learning history and no longer provide adaptive predictions. We discuss the process of updating in terms of the exploration-exploitation dilemma. This consists of the extent to which one relies on what one already has, i.e., whether one continues to maintain and “exploit” one’s previous priors (“better safe than sorry”) or whether one does explore new data that lead to an update of priors. Questioning previous priors triggers stress, which is associated with increases in Free Energy in short term. The role of therapeutic relationship is to buffer this increase in Free Energy, thereby increasing the level of perceived safety. The therapeutic relationship is represented in a dual model of affective alliance and goal attainment alliance and is aligned with FEP. Both forms of alliance support exploration and updating of priors. All aspects are illustrated with the help of a clinical case example.

Published

2022

33. Anticipating social incentives recruits alpha-beta oscillations in the human substantia nigra and invigorates behavior across the life span

Author

Alexandra Sobczak, Stefan Repplinger, Eva M. Bauch, Norbert Brueggemann, Christina Lohse, Hermann Hinrichs, Lars Buentjen, Juergen Voges, Tino Zaehle, and Nico Bunzeck

Subjects

Substantia nigra, Intracranial EEG, Dopamine, Social reward learning, Parkinson, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Anticipating social and non-social incentives recruits shared brain structures and promotes behavior. However, little is known about possible age-related behavioral changes, and how the human substantia nigra (SN) signals positive and negative social information. Therefore, we recorded intracranial electroencephalography (iEEG) from the SN of Parkinson's Disease (PD) patients (n = 12, intraoperative, OFF medication) in combination with a social incentive delay task including photos of neutral, positive or negative human gestures and mimics as feedback. We also tested a group of non-operated PD patients (n = 24, ON and OFF medication), and a sample of healthy young (n = 51) and older (n = 52) adults with behavioral readouts only. Behaviorally, the anticipation of both positive and negative social feedback equally accelerated response times in contrast to neutral social feedback in healthy young and older adults. Although this effect was not significant in the group of operated PD patients – most likely due to the small sample size – iEEG recordings in their SN showed a significant increase in alpha-beta power (9–20 Hz) from 300 to 600 ms after cue onset again for both positive and negative cues. Finally, in non-operated PD patients, the behavioral effect was not modulated by medication status (ON vs OFF medication) suggesting that other processes than dopaminergic neuromodulation play a role in driving invigoration by social incentives. Together, our findings provide novel and direct evidence for a role of the SN in processing positive and negative social information via specific oscillatory mechanisms in the alpha-beta range, and they suggest that anticipating social value in simple cue-outcome associations is intact in healthy aging and PD.

Published

2021

34. Embodied Cognition and the Direct Induction of Affect as a Compliment to Cognitive Behavioural Therapy

Author

Tania Pietrzak, Christina Lohr, Beverly Jahn, and Gernot Hauke

Subjects

embodiment, CBT, interpersonal synchrony, therapeutic alliance, emotional regulation, emotional field, emotional mastery, affect experience, change process, Psychology, BF1-990

Abstract

We make the case for the possible integration of affect experience induced via embodiment techniques with CBT for the treatment of emotional disorders in clinical settings. Theoretically we propose a possible integration of cognitive behavioural theory, neuroscience, embodied cognition and important processes of client change outcomes such as the therapeutic alliance to enhance client outcomes. We draw from evidence of bidirectional effects between embodiment modes of bottom-up (sensory-motor simulations giving rise to important basis of knowledge) and top-down (abstract mental representations of knowledge) processes such as CBT in psychotherapy. The paper first describes the dominance and success of CBT for the treatment of a wide range of clinical disorders. Some limitations of CBT, particularly for depression are also outlined. There is a growing body of evidence for the added value of experiential affect-focused interventions combined with CBT. Evidence for the embodied model of cognition and emotion is reviewed. Advantages of embodiment is highlighted as a complimentary process model to deepen the intensity and valence of affective experience. It is suggested that an integrated embodiment approach with CBT enhances outcomes across a wide range of emotional disorders. A description of our embodiment method integrated with CBT for inducing affective experience, emotional regulation, acceptance of unwanted emotions and emotional mastery is given. Finally, the paper highlights the importance of the therapeutic alliance as a critical component of the change process. The paper ends with a case study highlighting some clinical strategies that may aid the therapist to integrate embodiment techniques in CBT that can further explore in future research on affective experience in CBT for a wider range of clinical disorders.

Published

2018