Courage Mahuvava, Nolan Matthew Esplen, Yannick Poirier, Stephen F Kry, Magdalena Bazalova-Carter

Dose calculations for preclinical radiobiology experiments conducted with single-field cabinet irradiators

Improving dose accuracy in pre-clinical research can have a direct impact in improving dose calculations in clinical radiation therapy, improving treatments and outcomes.

M Schwengler, B Ibironke, K Lemke, A Walther, A Ekpenyong

Computational Modelling of Impedance Based Cell Migration for Improved Chemotherapy and Radiotherapy

Melanie Schwengler et al, at Creighton University, continue their work using a CellRAD benchtop irraditor to study the complex biological phenomenon of metastasis in brain cancer cells.

Anne Hubbard, Caleb Thiegs, Honour Djam, Harry Kramer, Yohan Walter, Michael Mimlitz, Dr. Andrew Ekpenyong

Concurrent Radiosensitization and Chemotherapy for Brain Tumors

Anne Hubbard from Creighton University, with the help of a CellRAD benchtop cabinet irradiator, works on improving treatment outcomes for highly radioresistant and chemoresistant cancers employing nanoparticle mediated radiosensitization and chemoradiotherapy.

Ivo P. Torres Filho, Luciana N. Torres, David Barraza, Charnae E. Williams, Kim Hildreth

X-Ray Beam Characterization of the CellRad X-Ray Irradiator Using Plane-Parallel Ionization Chamber and X-Ray Beam Analyzer

How important is repeatability to you in radiobiological studies? Dr. Cabahug from Philippine Nuclear Research Institute shows off the commissioning of a Precision CellRAD+ benchtop cell irradiator at AAPM! His work reflects a high accuracy of the X-ray tube output including multiple energy levels and can serve as a basis for the development of research protocols for cell irradiation operational commissioning.

Clara M.G. de Faria, Claudia P. Barrera-Patiño, Jhone P.P. Santana, Lucimar R. da Silva de Avó, Vanderlei S. Bagnato

Tumor Radiosensitization by Photobiomodulation

Investigating the combination of radiation with several other techniques for oncological treatment, such as Photodynamic Therapy and Photobiomodulation Therapy. Read more about what the team at the University of São Paulo is doing in their research.

The Effect of Mouse Size on Dose from an X-Rad320 Irradiator

When looking to attain consistent and reproducible results, how does variable mouse sizes affect dose delivery? Researchers in the Department of Medical Physics, University of Wisconsin School of Medicine and Public Health published their findings on this topic.

María E. GuerraGarcía, David G.Kirsch, Zachary J.Reitman

Targeting the ATM Kinase to Enhance the Efficacy of Radiotherapy and Outcomes for Cancer Patients

Targeting the DNA damage response represents a promising approach to improve the efficacy of radiation therapy. The serine/threonine kinase ATM mediates signal transduction following DNA double strand breaks and promotes cell cycle arrest, apoptosis, senescence, and metabolic reprogramming. Because radiation therapy selectively kills cancer cells by inducing DSBs and because mice and humans lacking ATM function are sensitized to radiation, inhibiting ATM has been proposed as a strategy to improve Cancer Radiation Therapy for over 25 years.

Michael Merrick, Michael J Mimlitz, Catherine Weeder, Haris Akhter, Allie Bray, Andrew Walther, Chisom Nwakama, Joe Bamesberger, Honour Djam, Kaamil Abid, Andrew Ekpenyong 

In Vitro Radiotherapy and Chemotherapy Alter Migration of Brain Cancer Cells Before Cell Death

The more we understand cancer, the closer we are to eradicating it. Stressing the need for anti-metastasis strategies alongside chemotherapy and radiation therapy, researchers @Creighton University, Omaha, NE, using a CellRad system, irradiated cancer and non-cancer cells to determine their level of migration. It is in this migration where cancer cell metastases invade healthy tissue, causing the growth of new tumors that lead to over 90% of all cancer deaths. Together, we can not only fight cancer, but we can beat it! Contact us today to see how we can help your cancer research.

Nathalie Donis, Zheshen Jiang, Céline D’Emal, Alexia Hulin, Margaux Debuisson, Raluca Dulgheru, Mai-Linh Nguyen, Adriana Postolache, François Lallemand, Philippe Coucke, Philippe Martinive, Marielle Herzog, Dorian Pamart, Jason Terrell, Joel Pincemail, Pierre Drion, Philippe Delvenne, Alain Nchimi, Patrizio Lancellotti, Cécile Oury

Differential Biological Effects of Dietary Lipids and Irradiation on the Aorta, Aortic Valve, and the Mitral Valve

Dietary cholesterol and palmitic acid are risk factors for cardiovascular diseases (CVDs) affecting the arteries and the heart valves. The ionizing radiation that is frequently used as an anticancer treatment promotes CVD and the specific pathophysiology of these distinct disease manifestations is poorly understood. Using rabbit models and a SmART+ irradiator, researchers study the biological effects of these dietary lipids and their cardiac irradiation on the arteries and the heart valves to help understand the relationship and improve life expectancy.

L Maigne, A Delsol, G Fois, E Debiton, F Degoul, H Payno

CPOP: An Open Source C++ Cell POPulation Modeler for Radiation Biology Applications

Continuing the fight against cancer, researchers @Université.Clermont.Auvergne in France, used a CPOP method and a Precision X-Rad320 irradiator, to successfully model cell populations and combine them with Geant14 simulations. This is a big step in studying the effects of anticancer drugs and evaluating the resistance of cancer cells under specific conditions.