Your search keyword '"Tavakkoli, Armin D."' showing total 11 results

1. Anesthetic Oxygen Use and Sex Are Critical Factors in the FLASH Sparing Effect

Author

Tavakkoli, Armin D., Clark, Megan A., Kheirollah, Alireza, Sloop, Austin M., Soderholm, Haille E., Daniel, Noah J., Petusseau, Arthur F., Huang, Yina H., Thomas, Charles R., Jr, Jarvis, Lesley A., Zhang, Rongxiao, Pogue, Brian W., Gladstone, David J., and Hoopes, P. Jack

Published

2024

2. Porcine-human glioma xenograft model. Immunosuppression and model reproducibility

Author

Hoopes, P.Jack, Tavakkoli, Armin D., Moodie, Karen A., Maurer, Kirk J., Meehan, Kenneth R., Wallin, Diana J., Aulwes, Ethan, Duval, Kayla E.A., Chen, Kristen L., -Burney, Margaret A.Crary, Li, Chen, Fan, Xiaoyao, Evans, Linton T., and Paulsen, Keith D.

Published

2024

3. Major contributors to FLASH sparing efficacy emerge from murine skin studies: dose rate, total dose per fraction, anesthesia and oxygenation.

Author

Pogue, Brian W., Thomas, William S., Tavakkoli, Armin D., Jarvis, Lesley A., and Hoopes, P. Jack

Subjects

RADIATION dosimetry, RADIATION damage, TREATMENT effectiveness, RADIOBIOLOGY, OXYGEN in the blood

Abstract

Background: Normal tissue sparing from radiation damage upon ultra-high dose rate irradiation, known as the FLASH effect with an equivalent tumor response, has been widely reported in murine skin models, and translation of this type of radiotherapy to humans has already begun, with skin sparing being a primary outcome expected. Methods: This study reviews the status of the field, focusing on the proposed mechanisms and skin response assays, outlining what has become known in terms of input parameters that might control the magnitude of the FLASH effect. Results: Murine studies have largely focused on acute damage responses, developing over 3–8 weeks, to single doses of FLASH versus conventional dose rate (CDR), suggesting that at dose rates above tens of Gray per second, with a total dose of more than 20 Gy, the FLASH effect is induced. Fractionated delivery appears to be possible, although fraction sizes >17 Gy appear to be needed for sparing efficacy. The interplay between the dose rate and total dose per fraction remains to be fully elucidated. Oxygen is a modulator of efficacy, with both hypoxia and hyperoxia diminishing the effect of FLASH. Measurement of transient changes in oxygen levels is possible and may be a marker of treatment efficacy. Conclusion: Taken together, murine skin data provide important information for translational studies, despite the associated limitations. Studies of later-term sparing effects, as well as studies on pig skin, are needed to take the next step in assessing translational FLASH efficacy. The control of biological factors, such as tissue oxygenation, may be required to understand and control the response. [ABSTRACT FROM AUTHOR]

Published

2024

4. Establishing connectivity through microdissections of midbrain stimulation-related neural circuits.

Author

Skandalakis, Georgios P, Neudorfer, Clemens, Payne, Caitlin A, Bond, Evalina, Tavakkoli, Armin D, Barrios-Martinez, Jessica, Trutti, Anne C, Koutsarnakis, Christos, Coenen, Volker A, Komaitis, Spyridon, Hadjipanayis, Constantinos G, Stranjalis, George, Yeh, Fang-Cheng, Banihashemi, Layla, Hong, Jennifer, Lozano, Andres M, Kogan, Michael, Horn, Andreas, Evans, Linton T, and Kalyvas, Aristotelis

Subjects

DEEP brain stimulation, NEURAL circuitry, HUMAN behavior, LIMBIC system, ALZHEIMER'S disease

Abstract

Comprehensive understanding of the neural circuits involving the ventral tegmental area is essential for elucidating the anatomofunctional mechanisms governing human behaviour, in addition to the therapeutic and adverse effects of deep brain stimulation for neuropsychiatric diseases. Although the ventral tegmental area has been targeted successfully with deep brain stimulation for different neuropsychiatric diseases, the axonal connectivity of the region is not fully understood. Here, using fibre microdissections in human cadaveric hemispheres, population-based high-definition fibre tractography and previously reported deep brain stimulation hotspots, we find that the ventral tegmental area participates in an intricate network involving the serotonergic pontine nuclei, basal ganglia, limbic system, basal forebrain and prefrontal cortex, which is implicated in the treatment of obsessive–compulsive disorder, major depressive disorder, Alzheimer's disease, cluster headaches and aggressive behaviours. [ABSTRACT FROM AUTHOR]

Published

2024

5. Anesthetic oxygen use and sex are critical factors in the FLASH sparing effect

Author

Tavakkoli, Armin D., primary, Clark, Megan A., additional, Kheirollah, Alireza, additional, Sloop, Austin M., additional, Soderholm, Haille E., additional, Daniel, Noah J., additional, Petusseau, Arthur F., additional, Huang, Yina H., additional, Thomas, Charles R., additional, Jarvis, Lesley A., additional, Zhang, Rongxiao, additional, Pogue, Brian W., additional, Gladstone, David J., additional, and Hoopes, P. Jack, additional

Published

2023

6. Enhancement of Radiation Therapy through Blockade of the Immune Checkpoint, V-domain Ig Suppressor of T Cell Activation (VISTA), in Melanoma and Adenocarcinoma Murine Models

Author

Duval, Kayla E. A., primary, Tavakkoli, Armin D., additional, Kheirollah, Alireza, additional, Soderholm, Haille E., additional, Demidenko, Eugene, additional, Lines, Janet L., additional, Croteau, Walburga, additional, Zhang, Samuel C., additional, Wagner, Robert J., additional, Aulwes, Ethan, additional, Noelle, Randolph J., additional, and Hoopes, P. Jack, additional

Published

2023

7. Enhancement of Adiation Therapy through Blockade of the Immune Checkpoint VISTA in Melanoma and Adenocarcinoma Murine Models

Author

Duval, Kayla E.A., primary, Tavakkoli, Armin D., additional, Kheirollah, Alireza, additional, Soderholm, Haille E., additional, Demidenko, Eugene, additional, Lines, Janet L., additional, Croteau, Walburga, additional, Wagner, Robert J., additional, Aulwes, Ethan, additional, Noelle, Randolph J., additional, and Hoopes, P. Jack, additional

Published

2023

8. White matter connections within the central sulcus subserving the somato-cognitive action network.

Author

Skandalakis GP, Viganò L, Neudorfer C, Rossi M, Fornia L, Cerri G, Kinsman KP, Bajouri Z, Tavakkoli AD, Koutsarnakis C, Lani E, Komaitis S, Stranjalis G, Zadeh G, Barrios-Martinez J, Yeh FC, Serletis D, Kogan M, Hadjipanayis CG, Hong J, Simmons N, Gordon EM, Dosenbach NUF, Horn A, Bello L, Kalyvas A, and Evans LT

Abstract

The somato-cognitive action network (SCAN) consists of three nodes interspersed within Penfield's motor effector regions. The configuration of the somato-cognitive action network nodes resembles the one of the 'plis de passage' of the central sulcus: small gyri bridging the precentral and postcentral gyri. Thus, we hypothesize that these may provide a structural substrate of the somato-cognitive action network. Here, using microdissections of sixteen human hemispheres, we consistently identified a chain of three distinct plis de passage with increased underlying white matter, in locations analogous to the somato-cognitive action network nodes. We mapped localizations of plis de passage into standard stereotactic space to seed fMRI connectivity across 9,000 resting-state fMRI scans, which demonstrated the connectivity of these sites with the somato-cognitive action network. Intraoperative recordings during direct electrical central sulcus stimulation further identified inter-effector regions corresponding to plis de passage locations. This work provides a critical step towards improved understanding of the somato-cognitive action network in both structural and functional terms. Further, our work has the potential to guide the development of refined motor cortex stimulation techniques for treating brain disorders, and operative resective techniques for complex surgery of the motor cortex., (© The Author(s) 2025. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2025

9. Oxygen Consumption In Vivo by Ultra-High Dose Rate Electron Irradiation Depends Upon Baseline Tissue Oxygenation.

Author

Sunnerberg JP, Tavakkoli AD, Petusseau AF, Daniel NJ, Sloop AM, Schreiber WA, Gui J, Zhang R, Swartz HM, Hoopes PJ, Gladstone DJ, Vinogradov SA, and Pogue BW

Abstract

Purpose: This study aimed to assess the impact of tissue oxygen levels on transient oxygen consumption induced by ultra-high dose rate (UHDR) electron radiation in murine flank and to examine the effect of dose rate variations on this relationship., Methods and Materials: Real-time oximetry using the phosphorescence quenching method and Oxyphor PdG4 molecular probe was employed. Continuous measurements were taken during radiation delivery on a UHDR-capable Mobetron linear accelerator. Oxyphor PdG4 was administered into the subcutaneous tissue of the flank skin 1 hour before irradiation. Skin oxygen tension (pO 2 ) was manipulated by adjusting oxygen content in the inhaled gas mixture and/or by vasculature compression. A skin surface radiation dose of 19.8 ± 0.3 Gy was verified using a calibrated semiconductor diode dosimeter. Dose rate was varied across the UHDR range by changing linear accelerator cone length and pulse repetition frequency., Results: The decrease in pO 2 per unit dose during radiation delivery, termed oxygen consumption g-value (g O2 , mmHg/Gy), was significantly influenced by tissue oxygen levels in the range 0 to 65 mmHg under UHDR conditions. Within the 0 to 20 mmHg range, g O2 exhibited a sharp increase with rising baseline pO 2 , plateauing at 0.26 mmHg/Gy. Dose rate variations (mean values, 25-1170 Gy/s; per pulse doses of 2.5-9.8 Gy) were explored by varying both cone length and pulse repetition frequency (10-120 Hz) with no significant changes in g O2 . Conventional dose rate irradiation resulted in no discernible changes in pO 2 ., Conclusions: The results show significant differences in the radiation-chemical effects of UHDR radiation between hypoxic and well-oxygenated tissues. Similar trends between earlier published in vitro and in vivo experiments presented herein suggest the chemical mechanisms driving the dependencies of g O2 on pO 2 are similar, potentially underpinning the FLASH effect. Importantly, significant variations in baseline pO 2 were observed in animals kept under identical conditions, underscoring the necessity to control and monitor tissue oxygen levels for preclinical investigations and future clinical applications of FLASH radiation therapy., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

10. Dynamic oxygen assessment techniques enable determination of anesthesia's impact on tissue.

Author

Clark MA, Tavakkoli AD, Petusseau AF, Scorzo AV, Kheirollah A, Davis SC, Strawbridge RR, Bruza P, Pogue BW, Gladstone DJ, and Hoopes PJ

Abstract

Tissue oxygenation is well understood to impact radiosensitivity, with reports demonstrating a significant effect of breathing condition and anesthesia type on tissue oxygenation levels and radiobiological response. However, the temporal kinetics of intracellular and extracellular oxygenation have never been quantified, on the timescale that may affect radiotherapy studies. C57BL/6 mice were anesthetized using isoflurane at various percentages or ketamine/xylazine (ket/xyl: 100/10 mg/kg) (N = 48). Skin pO 2 was measured using Oxyphor PdG4 and tracked after anesthetization began. Oxyphor data was validated with relative measurements of intracellular oxygen via protoporphyrin IX (PpIX) delayed fluorescence (DF) imaging. Ex vivo localization of both PdG4 Oxyphor and PpIX were quantified. Under all isoflurane anesthesia conditions, leg skin pO2 levels significantly increased from 12-15 mmHg at the start of anesthesia induction (4-6 minutes) to 24-27 mmHg after 10 minutes (p < 0.05). Ketamine/xylazine anesthesia led to skin pO2 maintained at 15-16 mmHg throughout the 10-minute study period (p < 0.01). An increase of pO2 in mice breathing isoflurane was demonstrated with Oxyphor and PpIX DF, indicating similar intracellular and extracellular oxygenation. These findings demonstrate the importance of routine anesthesia administration, where consistency in the timing between induction and irradiation may be crucial to minimizing variability in radiation response., Competing Interests: Declarations Additional Declarations: No competing interests reported.

Published

2024

11. Anesthetic oxygen use and sex are critical factors in the FLASH sparing effect.

Author

Tavakkoli AD, Clark MA, Kheirollah A, Sloop AM, Soderholm HE, Daniel NJ, Petusseau AF, Huang YH, Thomas CR, Jarvis LA, Zhang R, Pogue BW, Gladstone DJ, and Hoopes PJ

Abstract

Introduction: Ultra-high dose-rate (UHDR) radiation has been reported to spare normal tissue compared to conventional dose-rate (CDR) radiation. However, reproducibility of the FLASH effect remains challenging due to varying dose ranges, radiation beam structure, and in-vivo endpoints. A better understanding of these inconsistencies may shed light on the mechanism of FLASH sparing. Here, we evaluate whether sex and/or use of 100% oxygen as carrier gas during irradiation contribute to the variability of the FLASH effect., Methods: C57BL/6 mice (24 male, 24 female) were anesthetized using isoflurane mixed with either room air or 100% oxygen. Subsequently, the mice received 27 Gy of either 9 MeV electron UHDR or CDR to a 1.6 cm 2 diameter area of the right leg skin using the Mobetron linear accelerator. The primary post-radiation endpoint was time to full thickness skin ulceration. In a separate cohort of mice (4 male, 4 female) skin oxygenation was measured using PdG4 Oxyphor under identical anesthesia conditions., Results: In the UHDR group, time to ulceration was significantly shorter in mice that received 100% oxygen compared to room air, and amongst them female mice ulcerated sooner compared to males. However, no significant difference was observed between male and female UHDR mice that received room air. Oxygen measurements showed significantly higher tissue oxygenation using 100% oxygen as the anesthesia carrier gas compared to room air, and female mice showed higher levels of tissue oxygenation compared to males under 100% oxygen., Conclusion: The FLASH sparing effect is significantly reduced using oxygen during anesthesia compared to room air. The FLASH sparing was significantly lower in female mice compared to males. Both tissue oxygenation and sex are likely sources of variability in UHDR studies. These results suggest an oxygen-based mechanism for FLASH, as well as a key role for sex in the FLASH skin sparing effect.

Published

2023