Ganesh Narayanasamy

Assistant Professor

UAMS

Last publication 2025 Last refreshed 2026-05-16

faculty

15 h-index 138 pubs 872 cited

Research Areas

Links

ORCID Lab Website

OverviewAI-generated summary

Ganesh Narayanasamy's research focuses on the application of computational methods and advanced imaging techniques in radiation oncology. His work investigates methods to improve the accuracy and efficacy of cancer treatments, particularly for prostate and spine cancers. Narayanasamy has published research evaluating the clinical impact of dose delivery consistency in prostate cancer radiotherapy, exploring the use of convolutional neural networks for detecting vertebral body misalignments in X-ray images, and assessing the utility of normal tissue complication probability methodologies for evaluating treatment side effects.

His publications also address the computational simulation of tumor control probability in fractionated radiation treatments and comparative dosimetric analyses of different treatment planning techniques for spine stereotactic body radiation therapy (SBRT). Narayanasamy collaborates with researchers at the University of Arkansas for Medical Sciences, including Faraz Kalantari, Forouh Kalantari, and Fen Xia, with whom he has co-authored multiple publications. His scholarship metrics include an h-index of 6, with 27 total publications and 150 total citations.

Metrics

h-index: 15
Publications: 138
Citations: 872

Selected Publications

AAPM task group report 210: Conventional linear accelerator acceptance testing (2025)

1 citation DOI OpenAlex
Producing high quality cranial SRS plans with 4Pi planning technique in a commercial clinical solution (2025)

DOI OpenAlex
The effective normal tissue non-complication probability (E0): a probabilistic methodology in the representation of the stochastic health safety effects of low levels of ionizing radiation on the human tissues or organs (2025)

DOI OpenAlex
Use of the Bayesian statistics and the product of probabilities in the ionizing radiation field (2024)

DOI OpenAlex
Cleaning the dose falloff with low modulation in SBRT lung plans (2023)

2 citations DOI OpenAlex
Development and multi‐institutional validation of a convolutional neural network to detect vertebral body mis‐alignments in 2D x‐ray setup images (2023)

4 citations DOI OpenAlex
Use of the Bayesian statistics and the product of probabilities in the ionizing radiation field (2023)

DOI OpenAlex
Evaluation of the clinical impact of the differences between planned and delivered dose in prostate cancer radiotherapy based on CT‐on‐rails IGRT and patient‐reported outcome scores (2022)

5 citations DOI OpenAlex
The use of the normal tissue non-complication probability (NTCP0) in the safety evaluations as a new alternative of assessing the side-effects of the radiation oncology treatments (2022)

3 citations DOI OpenAlex
A phantom-based study and clinical implementation of brainlab’s treatment planning system for radiosurgical treatments of arteriovenous malformations (2022)

DOI OpenAlex
The use of the normal tissue non-complication probability (NTCP0) methodology as a new alternative of assessing side-effects in brachytherapy treatments (2022)

4 citations DOI OpenAlex
A dosimetric comparative analysis of Brainlab elements and Eclipse RapidArc for spine SBRT treatment planning (2022)

2 citations DOI OpenAlex
A treatment planning system with new paradigms in the effectiveness and side-effect evaluation sections (2021)

DOI OpenAlex
Evaluation of the Dose Delivery Consistency and Its Dependence on Imaging Modality and Deformable Image Registration Algorithm in Prostate Cancer Patients (2021)

3 citations DOI OpenAlex
Output factor measurements with multiple detectors in CyberKnife® Robotic Radiosurgery System (2021)

1 citation DOI OpenAlex