about
HZE Radiation Non-Targeted Effects on the Microenvironment That Mediate Mammary CarcinogenesisConcepts and challenges in cancer risk prediction for the space radiation environmentBreast cancer risk in BRCA1 mutation carriers: insight from mouse modelsThe effect of environmental chemicals on the tumor microenvironmentPhotoactivation of endogenous latent transforming growth factor-β1 directs dental stem cell differentiation for regeneration.Irradiation of juvenile, but not adult, mammary gland increases stem cell self-renewal and estrogen receptor negative tumors.Distinct luminal-type mammary carcinomas arise from orthotopic Trp53-null mammary transplantation of juvenile versus adult mice.Age- and pregnancy-associated DNA methylation changes in mammary epithelial cells.Identification of genetic loci that control mammary tumor susceptibility through the host microenvironment.TGFβ Is a Master Regulator of Radiation Therapy-Induced Antitumor ImmunityNoninvasive diagnosis and management of spontaneous intracranial hypotension in patients with marfan syndrome: Case Report and Review of the Literature.Tumors as organs: biologically augmenting radiation therapy by inhibiting transforming growth factor β activity in carcinomas.New tricks for an old fox: impact of TGFβ on the DNA damage response and genomic stability.The Microenvironment of Lung Cancer and Therapeutic Implications.Hydrogen Peroxide Enhances TGFβ-mediated Epithelial-to-Mesenchymal Transition in Human Mammary Epithelial MCF-10A Cells.Attenuation of the DNA damage response by transforming growth factor-beta inhibitors enhances radiation sensitivity of non-small-cell lung cancer cells in vitro and in vivo.Development of a novel multiplexed assay for quantification of transforming growth factor-β (TGF-β).TGFβ1 protects cells from γ-IR by enhancing the activity of the NHEJ repair pathway.TGF-β signaling links E-cadherin loss to suppression of nucleotide excision repair.BUB1-bling over with possibilitiesRadiation-Induced Fibrosis: Mechanisms and Opportunities to Mitigate. Report of an NCI Workshop, September 19, 2016.Densely ionizing radiation acts via the microenvironment to promote aggressive Trp53-null mammary carcinomas.Subverting misconceptions about radiation therapy.Evaluation of Radioresponse and Radiosensitizers in Glioblastoma Organotypic Cultures.ICRP Publication 131: Stem cell biology with respect to carcinogenesis aspects of radiological protection.Soil amendments that slow cancer growth.Low-Dose Radiation Knowledge Worth the CostAbstract 633: Inhibition of TGFβ as a strategy to convert the irradiated tumor into in situ individualized vaccineSubjugation of TGFβ Signaling by Human Papilloma Virus in Head and Neck Squamous Cell Carcinoma Shifts DNA Repair from Homologous Recombination to Alternative End JoiningEducation and Training for Radiation Scientists: Radiation Research Program and American Society of Therapeutic Radiology and Oncology Workshop, Bethesda, Maryland, May 12–14, 2003TGFβ Blockade Enhances Radiotherapy Abscopal Efficacy Effects in Combination with Anti-PD1 and Anti-CD137 Immunostimulatory Monoclonal AntibodiesRadiation therapy and the microenvironmentModels for evaluating agents intended for the prophylaxis, mitigation and treatment of radiation injuries. Report of an NCI Workshop, December 3-4, 2003In honor of Mina J. BissellTGFβ biology in breast: 15 years on"Praising What Is Lost. . .Misrepair in Context: TGFβ Regulation of DNA RepairAutocrine TGFβ Is a Survival Factor for Monocytes and Drives Immunosuppressive Lineage CommitmentAggressive Mammary Cancers Lacking Lymphocytic Infiltration Arise in Irradiated Mice and Can Be Prevented by Dietary Intervention
P50
Q26750868-D28755AB-E76D-4EBA-9364-CD043EFBA86EQ26800463-2900397E-107B-4E37-9E92-CC155B311546Q26823062-ACD359D4-1669-4C44-A2D1-EF81F68140F9Q28085138-0B3C7709-1CD6-4B90-88D0-B301AE56903CQ33961465-1309D0D9-58CE-46A3-A1E4-1F507E8CF98CQ34371336-27601829-AFDC-4093-8C0E-129E7CE9D643Q34616600-1E4FFFC8-042E-4DC2-B2A3-20D683A5C4DFQ35075323-D4F480EE-57ED-4CA1-BD1E-55691F00BD51Q35157258-E1B351B9-097B-442D-8F06-CE8885CFF44BQ35908369-62853A84-230E-4E1B-8147-F7DFC5208132Q37589583-F684659D-BED3-4C07-92AC-048B6B7A4A32Q37633861-8268CE99-FEAA-46D9-AB93-848CB7892B28Q38245806-83771E87-D2D7-4FC3-89B9-7DF0BF76E55DQ38679301-96199440-6E8C-40A6-AC6F-4A331DC61E47Q38711838-DF2F739C-7C3F-4E1D-BFD7-BC9772974028Q38891643-DE81B14B-88CD-4568-B67F-2FB4BE0573DBQ38920213-2D254AFC-E080-40A3-B5FE-098FB2EE9199Q38947586-A0988023-4D35-4FEB-8199-4DAADDB6ACA5Q40362004-66AD136B-98E0-4508-88FD-7717D2EFCB6AQ41823172-859C7026-B22A-4ABA-ABA8-0E846CBB17EDQ45058787-BA9A2CE8-342F-4A4D-87FF-51A248AC08BFQ45817562-5A6CEF46-A44E-4B84-86F5-90CE11387B98Q46962194-A426D073-9754-4430-8E55-88FAAE3A2D32Q47824479-A54A57B0-216F-46EB-914B-E9F67E5DA1E4Q52881606-5343250E-B312-4F34-81B7-E1442AB250E8Q54347995-A2F460D3-3C33-4A03-972E-767707885614Q57420854-31930DF9-605D-4FAE-B1B8-D418C7D44196Q57823183-8F86AF3C-06EA-4A91-AAE1-7F832F785538Q60308387-7B61666E-867E-4A51-B021-DCE89100CA15Q60594503-63F0E249-6900-44DC-9FF1-C07F2B7E8C8AQ63865741-1AD1C4B5-89BE-412A-AC91-4E2042F5DE3AQ80144504-82D64124-F4B4-4C36-886A-2893DF599A53Q81017607-F770928E-3816-4293-996C-689AA61736D0Q83745013-4088D95E-B344-4547-B2F9-5DCE9365E9EFQ84010938-DD3AB676-58F6-4B2C-AF1F-5E22D82B5F36Q89157247-20B133E7-5F0F-4A97-8076-AE56752E6074Q90266838-C89E0E53-371D-48CE-9B33-DF60A8CEEA53Q90410800-341BAFA6-38EA-4D03-B3F2-F055CF97DA65Q91931511-BC84ABB2-C3B6-40F3-A68D-B7764A143511
P50
description
hulumtuese
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Mary Helen Barcellos-Hoff
@ast
Mary Helen Barcellos-Hoff
@en
Mary Helen Barcellos-Hoff
@es
Mary Helen Barcellos-Hoff
@nl
type
label
Mary Helen Barcellos-Hoff
@ast
Mary Helen Barcellos-Hoff
@en
Mary Helen Barcellos-Hoff
@es
Mary Helen Barcellos-Hoff
@nl
prefLabel
Mary Helen Barcellos-Hoff
@ast
Mary Helen Barcellos-Hoff
@en
Mary Helen Barcellos-Hoff
@es
Mary Helen Barcellos-Hoff
@nl
P108
P106
P108
P21
P31
P496
0000-0002-5994-9558