Ji Won Byun
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View article: Supplementary Figure S8 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S8 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S8. The RORγ/γt inhibitors digoxin and SR2211 inhibit Th17 cell differentiation in vitro.
View article: Supplementary Figure S9 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S9 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S9. Gating strategies for the flow cytometry analysis of lymphoid cell populations.
View article: Supplementary Figure S7 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S7 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S7. Rorg expression is not increased in CSCs isolated from the lungs of KrasG12D mice.
View article: Supplementary Figure S12 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S12 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S12. Gating strategies for the flow cytometry analysis of myeloid cell populations.
View article: Supplementary Figure S13 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S13 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S13. Digoxin treatment does not alter the infiltration of M1, M2, or PD-1-expressing tumorassociated macrophages (TAMs) in the lungs of KrasG12D mice.
View article: Supplementary Table S3 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Table S3 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Table S3. Oligonucleotides used for qPCR analysis.
View article: Supplementary Figure S11 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S11 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S11. Digoxin treatment does not affect the infiltration of some of the major myeloid cell subsets into the lungs of KrasG12D mice.
View article: Supplementary Figure S1 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S1 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S1. Effect of digoxin treatment on tumor progression and cytokine expression in a KrasG12D-driven lung cancer (LC) model.
View article: Supplementary Figure S6 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S6 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S6. Rorg expression is not increased in LLC CSCs.
View article: Supplementary Table S1 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Table S1 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Table S1. Key resources table.
View article: Supplementary Figure S4 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S4 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S4. The proliferation and viability of LUAD cell lines are unaffected by RORγ/γt pharmacological inhibition or Rorc genetic deletion.
View article: Supplementary Figure S10 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S10 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S10. Digoxin treatment does not affect the infiltration of NK17, NKT17, and γ/δT17 cells into the lungs of KrasG12D mice.
View article: Supplementary Figure S2 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S2 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S2. mIF panel validation.
View article: Supplementary Figure S15 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S15 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S15. Effect of digoxin treatment on cytokine expression in urethane-treated Rag1–/– mice.
View article: Supplementary Figure S14 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S14 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S14. Effect of Rorc gene deletion in a urethane-induced LC model.
View article: Supplementary Figure S16 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S16 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S16. Analysis of IL17A, IL17F, and IL22 promotor methylation and gene expression in LUAD patients.
View article: Supplementary Table S2 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Table S2 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Table S2. Control and Rorc-targeting gRNA sequences and homology arm sequences used for CRISPR/Cas9 for Rorc KO and HDR repair.
View article: Supplementary Figure S5 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S5 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S5. Rorg expression is not regulated by IL-1R1 signaling in LC cells in vitro.
View article: Data from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Data from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
The retinoic acid receptor–related orphan receptor C (RORC) gene encodes two isoforms, RORγ and RORγt, which function as transcription factors in different cell types. RORγt is expressed in specific immune cells involved in inflammatory re…
View article: Supplementary Figure S3 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S3 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S3. Pharmacological inhibition of RORγ/γt does not affect the expression of cell proliferation, cell death, or cell survival markers in a Kras-mutated mouse LC cell line.
View article: Supplementary Figure S17 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
Supplementary Figure S17 from RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
Supplementary Figure S17. Correlation between RORC gene expression and immune and stromal cell infiltration in LUAD patients.
View article: RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer
RORγt Inhibition Reduces Protumor Inflammation and Decreases Tumor Growth in Experimental Models of Lung Cancer Open
The retinoic acid receptor–related orphan receptor C (RORC) gene encodes two isoforms, RORγ and RORγt, which function as transcription factors in different cell types. RORγt is expressed in specific immune cells involved in inflammatory re…
View article: In Vivo Bioluminescence Imaging of Tumor Progression in the Lewis Lung Carcinoma Orthotopic Mouse Model: A Comparison Between the Tail Vein Injection and Intranasal Instillation Methods
In Vivo Bioluminescence Imaging of Tumor Progression in the Lewis Lung Carcinoma Orthotopic Mouse Model: A Comparison Between the Tail Vein Injection and Intranasal Instillation Methods Open
Metastasis remains a leading cause of cancer‐related mortality, yet its study has been constrained by the lack of reliable animal models that faithfully replicate this complex process. Syngeneic models for studying lung cancer metastasis a…
Genomic progression for local invasion of cutaneous squamous cell carcinoma from the superficial to the deep portion Open
Cutaneous squamous cell carcinoma (cSCC) is the second most common skin cancer. While many treatments exist, our understanding of its genomic progression, especially from the epidermis to the deep dermis, remains limited. This study aims t…
Dickkopf-related Protein 2 Promotes Hair Growth by Upregulating the Wnt/β-catenin Signaling Pathway in Human Dermal Papilla Cells Open
Our results indicate that rhDKK2 could promote hair growth by facilitating the proliferation of human DPCs through activation of the Wnt/β-catenin signaling pathway.
The Quality of Life and Psychosocial Impact on Female Pattern Hair Loss Open
FPHL damages the psychosocial aspects of patients, such as QoL, depression, and medical consumption, according to the severity of hair loss.
Back Cover Open
The cover image is based on the Original Article Efficacy of radiofrequency combined with single‐dot ultrasound efficacy for skin rejuvenation: A non‐randomized split‐face trial with blinded response evaluation by Ji Won Byun et al., https…
Efficacy of radiofrequency combined with single‐dot ultrasound efficacy for skin rejuvenation: A non‐randomized split‐face trial with blinded response evaluation Open
Background High‐intensity focused ultrasound (HIFU) and radiofrequency (RF) are non‐invasive modalities for skin rejuvenation, but their combined effects have not been evaluated. Objective We evaluated and compared the efficacy of HIFU alo…