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5. Enhanced tumor control and survival in preclinical models with adoptive cell therapy preceded by low-dose radiotherapy.

Author

Puebla-Osorio, Nahum, Fowlkes, Natalie Wall, Barsoumian, Hampartsoum B., Xega, Kristina, Srivastava, Gitika, Kettlun-Leyton, Claudia, Nizzero, Sara, Voss, Tiffany, Riad, Thomas S., Wong, Christina, Huang, Ailing, Yun Hu, Mitchell, Joylise, Mingee Kim, Rafiq, Zahid, Kewen He, Sezen, Duygu, Hsu, Ethan, Masrorpour, Fatemeh, and Maleki, Aurian

Subjects
CHIMERIC antigen receptors, ATOMIC force microscopy, TREATMENT effectiveness, TUMOR growth, SURVIVAL rate
Abstract

Introduction: Effective infiltration of chimeric antigen receptor T (CAR-T) cells into solid tumors is critical for achieving a robust antitumor response and improving therapeutic outcomes. While CAR-T cell therapies have succeeded in hematologic malignancies, their efficacy in solid tumors remains limited due to poor tumor penetration and an immunosuppressive tumor microenvironment. This study aimed to evaluate the potential of low-dose radiotherapy (LDRT) administered before T-cell therapy to enhance the antitumor effect by promoting CAR-T cell infiltration. We hypothesized that combining LDRT with T-cell therapy would improve tumor control and survival compared to either treatment alone. Methods: We investigated this hypothesis using two NSG mouse models bearing GSU or CAPAN-2 solid tumors. The mice were treated with engineered CAR-T cells targeting guanyl cyclase-C (GCC) or mesothelin as monotherapy or in combination with LDRT. Additionally, we extended this approach to a C57BL/6 mouse model implanted with MC38-gp100+ cells, followed by adoptive transfer of pmel+ T cells before and after LDRT. Tumor growth and survival outcomes were monitored in all models. Furthermore, we employed atomic force microscopy (AFM) in a small cohort to assess the effects of radiotherapy on tumor stiffness and plasticity, exploring the role of tumor nanomechanics as a potential biomarker for treatment efficacy. Results: Our results demonstrated enhanced tumor control and prolonged survival in mice treated with LDRT followed by T-cell therapy across all models. The combination of LDRT with CAR-T or pmel+ T-cell therapy led to superior tumor suppression and survival compared to monotherapy, highlighting the synergistic impact of the combined approach. Additionally, AFM analysis revealed significant changes in tumor stiffness and plasticity in response to LDRT, suggesting that the nanomechanical properties of the tumor may be predictive of therapeutic response. Discussion: The findings of this study highlight the transformative potential of incorporating LDRT as a precursor to adoptive T-cell therapy in solid tumors. By promoting CAR-T and pmel+ T-cell infiltration into the tumor microenvironment, LDRT enhanced tumor control and improved survival outcomes, offering a promising strategy to overcome the challenges associated with CAR-T therapy in solid tumors. Additionally, the changes in tumor nanomechanics observed through AFM suggest that tumor stiffness and plasticity could be biomarkers for predicting treatment outcomes. These results support further investigation into the clinical application of this combined approach to improve the efficacy of cellbased therapies in patients with solid tumors. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Nanoparticle-enhanced proton beam immunoradiotherapy drives immune activation and durable tumor rejection

Author

Hu, Yun, primary, Paris, Sébastien, additional, Sahoo, Narayan, additional, Bertolet, Genevieve, additional, Wang, Qi, additional, Wang, Qianxia, additional, Barsoumian, Hampartsoum B., additional, Da Silva, Jordan, additional, Huang, Ailing, additional, Doss, Denaha J., additional, Pollock, David P., additional, Hsu, Ethan, additional, Selene, Nanez, additional, Leyton, Claudia S. Kettlun, additional, Voss, Tiffany A., additional, Masrorpour, Fatemeh, additional, Ganjoo, Shonik, additional, Leuschner, Carola, additional, Pietz, Jordan T., additional, Puebla-Osorio, Nahum, additional, Gandhi, Saumil, additional, Nguyen, Quynh-Nhu, additional, Wang, Jing, additional, Cortez, Maria Angelica, additional, and Welsh, James W., additional

Published
2023
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8. Radiation therapy modulates tumor physical characteristics to reduce intratumoral pressure and enhance intratumoral drug delivery and retention

Author

Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), Barsoumian, Hampartsoum B.; Sheth, Rahul A.; Ramapriyan, Rishab; Hsu, Ethan; Gagea, Mihai; Crowley, Kaitlyn; Williams, Malea; Welsh, James W., School of Medicine, Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), Barsoumian, Hampartsoum B.; Sheth, Rahul A.; Ramapriyan, Rishab; Hsu, Ethan; Gagea, Mihai; Crowley, Kaitlyn; Williams, Malea; Welsh, James W., and School of Medicine

Abstract

Purpose: high intratumoral pressure, caused by tumor cell-to-cell interactions, interstitial fluid pressure, and surrounding stromal composition, plays a substantial role in resistance to intratumoral drug delivery and distribution. Radiation therapy (XRT) is commonly administered in conjunction with different intratumoral drugs, but assessing how radiation can reduce pressure locally and help intratumoral drug administration and retention is important. Methods and Materials: 344SQ-parental or 344SQ-anti-programmed cell death protein 1-resistant lung adenocarcinoma cells were established in 129Sv/Ev mice, and irradiated with either 1 Gy × 2, 5 Gy × 3, 8 Gy × 3, 12 Gy × 3, or 20 Gy × 1. Intratumoral pressure was measured every 3 to 4 days after XRT. Contrast dye was injected into the tumors 3- and 6-days after XRT, and imaged to measure drug retention. Results: in the 344SQ-parental model, low-dose radiation (1 Gy × 2) created an early window of reduced intratumoral pressure 1 to 3 days after XRT compared with untreated control. High-dose stereotactic radiation (12 Gy × 3) reduced intratumoral pressure 3 to 12 days after XRT, and 20 Gy × 1 showed a delayed pressure reduction on day 12. Intermediate doses of radiation did not significantly affect intratumoral pressure. In the more aggressive 344SQ-anti-programmed cell death protein 1-resistant model, low-dose radiation reduced pressure 1 to 5 days after XRT, and 12 Gy × 3 reduced pressure 1 to 3 days after XRT. Moreover, both 1 Gy × 2 and 12 Gy × 3 significantly improved drug retention 3 days after XRT; however, there was no significance detected 6 days after XRT. Lastly, a histopathologic evaluation showed that 1 Gy × 2 reduced collagen deposition within the tumor, and 12 Gy × 3 led to more necrotic core and higher extracellular matrix formation in the tumor periphery. Conclusions: optimized low-dose XRT, as well as higher stereotactic XRT regimen led to a reduction in intratumoral pressure and increased drug retenti, Sources of support: Bristol Myers Squibb funded this work.

Published
2023

12. NBTXR3 improves the efficacy of immunoradiotherapy combining nonfucosylated anti-CTLA4 in an anti-PD1 resistant lung cancer model

Author

Hu, Yun, primary, Paris, Sébastien, additional, Bertolet, Genevieve, additional, Barsoumian, Hampartsoum B., additional, Wang, Qi, additional, Da Silva, Jordan, additional, Patel, Nalini B., additional, Nguyen, Nguyen, additional, Doss, Denaha J., additional, Huang, Ailing, additional, Hsu, Ethan, additional, Leyton, Claudia S. Kettlun, additional, Voss, Tiffany A., additional, Masrorpour, Fatemeh, additional, Leuschner, Carola, additional, Pietz, Jordan T., additional, Puebla-Osorio, Nahum, additional, Gandhi, Saumil, additional, Nguyen, Quynh-Nhu, additional, Wang, Jing, additional, Cortez, Maria Angelica, additional, and Welsh, James W., additional

Published
2022
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13. 869 NBTXR3-enhanced proton beam immunoradiotherapy reshapes tumor immune microenvironment and improves abscopal effect in an anti-PD1-resistant lung cancer

Author

Hu, Yun, primary, Paris, Sebastien, additional, Sahoo, Narayan, additional, Bertolet, Genevieve, additional, Wang, Qi, additional, Wang, Qianxia, additional, Barsoumian, Hampartsoum, additional, SILVA, Jordan, additional, Huang, Ailing, additional, Leyton, Claudia Kettlun, additional, Voss, Tiffany, additional, Hsu, Ethan, additional, Masrorpour, Fatemeh, additional, Leuschner, Carola, additional, Osorio, Nahum Puebla, additional, Nguyen, Quynh, additional, Gandhi, Saumil, additional, Wang, Jing, additional, Cortez, Maria, additional, and Welsh, James, additional

Published
2022
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15. Pulsed radiotherapy to mitigate high tumor burden and generate immune memory

Author

Sezen, Duygu, primary, Barsoumian, Hampartsoum B., additional, He, Kewen, additional, Hu, Yun, additional, Wang, Qi, additional, Abana, Chike O., additional, Puebla-Osorio, Nahum, additional, Hsu, Ethan Y., additional, Wasley, Mark, additional, Masrorpour, Fatemeh, additional, Wang, Jing, additional, Cortez, Maria Angelica, additional, and Welsh, James W., additional

Published
2022
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16. High plus low dose radiation strategy in combination with TIGIT and PD1 blockade to promote systemic antitumor responses

Author

Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), Barsoumian, Hampartsoum B.; Menon, Hari; Younes, Ahmed I.; Hu, Yun; He, Kewen; Puebla-Osorio, Nahum; Wasley, Mark; Hsu, Ethan; Patel, Roshal R.; Yang, Liangpeng; Cortez, Maria A.; Welsh, James W., School of Medicine, Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), Barsoumian, Hampartsoum B.; Menon, Hari; Younes, Ahmed I.; Hu, Yun; He, Kewen; Puebla-Osorio, Nahum; Wasley, Mark; Hsu, Ethan; Patel, Roshal R.; Yang, Liangpeng; Cortez, Maria A.; Welsh, James W., and School of Medicine

Abstract

This study combines a novel strategy of radiotherapy that utilizes high- and low- dose radiation with immune oncology agents (anti-TIGIT and anti-PD1 monoclonal antibodies) in order to overcome the inhibitory tumor stroma and battle tumors systemically. The findings from this work will impact how checkpoint inhibitors are delivered to maximize their efficacy. Tumors deploy various immune-evasion mechanisms that create a suppressive environment and render effector T-cells exhausted and inactive. Therefore, a rational utilization of checkpoint inhibitors may alleviate exhaustion and may partially restore antitumor functions. However, in high-tumor-burden models, the checkpoint blockade fails to maintain optimal efficacy, and other interventions are necessary to overcome the inhibitory tumor stroma. One such strategy is the use of radiotherapy to reset the tumor microenvironment and maximize systemic antitumor outcomes. In this study, we propose the use of anti-PD1 and anti-TIGIT checkpoint inhibitors in conjunction with our novel RadScopal technique to battle highly metastatic lung adenocarcinoma tumors, bilaterally established in 129Sv/Ev mice, to mimic high-tumor-burden settings. The RadScopal approach is comprised of high-dose radiation directed at primary tumors with low-dose radiation delivered to secondary tumors to improve the outcomes of systemic immunotherapy. Indeed, the triple therapy with RadScopal + anti-TIGIT + anti-PD1 was able to prolong the survival of treated mice and halted the growth of both primary and secondary tumors. Lung metastasis counts were also significantly reduced. In addition, the low-dose radiation component reduced TIGIT receptor (PVR) expression by tumor-associated macrophages and dendritic cells in secondary tumors. Finally, low-dose radiation within triple therapy decreased the percentages of TIGIT(+) exhausted T-cells and TIGIT(+) regulatory T-cells. Together, our translational approach provides a new treatment alternative for cas, United States Department of Health and Human Services; National Institutes of Health (NIH); NIH National Cancer Institute (NCI)

Published
2022

17. High Plus Low Dose Radiation Strategy in Combination with TIGIT and PD1 Blockade to Promote Systemic Antitumor Responses

Author

Barsoumian, Hampartsoum B., primary, Sezen, Duygu, additional, Menon, Hari, additional, Younes, Ahmed I., additional, Hu, Yun, additional, He, Kewen, additional, Puebla-Osorio, Nahum, additional, Wasley, Mark, additional, Hsu, Ethan, additional, Patel, Roshal R., additional, Yang, Liangpeng, additional, Cortez, Maria A., additional, and Welsh, James W., additional

Published
2022
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18. Novel Use of Low-Dose Radiotherapy to Modulate the Tumor Microenvironment of Liver Metastases

Author

He, Kewen, primary, Barsoumian, Hampartsoum B., additional, Bertolet, Genevieve, additional, Verma, Vivek, additional, Leuschner, Carola, additional, Koay, Eugene J., additional, Ludmir, Ethan B., additional, Hsu, Ethan, additional, Pisipati, Esha, additional, Voss, Tiffany A., additional, Puebla-Osorio, Nahum, additional, Cortez, Maria Angelica, additional, and Welsh, James W., additional

Published
2021
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19. Pulsed radiotherapy to mitigate high tumor burden and generate immune memory.

Author

Duygu Sezen, Barsoumian, Hampartsoum B., Kewen He, Yun Hu, Qi Wang, Abana, Chike O., Puebla-Osorio, Nahum, Hsu, Ethan Y., Wasley, Mark, Masrorpour, Fatemeh, Jing Wang, Cortez, Maria Angelica, and Welsh, James W.

Subjects
IMMUNOLOGIC memory, SECONDARY primary cancer, RADIOTHERAPY, TUMOR growth, T cells, PSYCHONEUROIMMUNOLOGY
Abstract

Radiation therapy (XRT) has a well-established role in cancer treatment. Given the encouraging results on immunostimulatory effects, radiation has been increasingly used with immune-check-point inhibitors in metastatic disease, especially when immunotherapy fails due to tumor immune evasion. We hypothesized that using high-dose stereotactic radiation in cycles (pulses) would increase T-cell priming and repertoire with each pulse and build immune memory in an incremental manner. To prove this hypothesis, we studied the combination of anti-CTLA-4 and Pulsed radiation therapy in our 344SQ non-small cell lung adenocarcinoma murine model. Primary and secondary tumors were bilaterally implanted in 129Sv/Ev mice. In the Pulsed XRT group, both primary and secondary tumors received 12Gyx2 radiation one week apart, and blood was collected seven days afterwards for TCR repertoire analysis. As for the delayed-Pulse group, primary tumors received 12Gyx2, and after a window of two weeks, the secondary tumors received 12Gyx2. Blood was collected seven days after the second cycle of radiation. The immunotherapy backbone for both groups was anti-CTLA-4 antibody to help with priming. Treatment with Pulsed XRT + anti-CTLA-4 led to significantly improved survival and resulted in a delayed tumor growth, where we observed enhanced antitumor efficacy at primary tumor sites beyond XRT + anti-CTLA-4 treatment group. More importantly, Pulsed XRT treatment led to increased CD4+ effector memory compared to single-cycle XRT. Pulsed XRT demonstrated superior efficacy to XRT in driving antitumor effects that were largely dependent on CD4+ T cells and partially dependent on CD8+ T cells. These results suggest that combinatorial strategies targeting multiple points of tumor immune evasion may lead to a robust and sustained antitumor response. [ABSTRACT FROM AUTHOR]

Published
2022
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20. Pulsed Radiation Therapy to Improve Systemic Control of Metastatic Cancer

Author

He, Kewen, primary, Barsoumian, Hampartsoum B., additional, Sezen, Duygu, additional, Puebla-Osorio, Nahum, additional, Hsu, Ethan Y., additional, Verma, Vivek, additional, Abana, Chike O., additional, Chen, Dawei, additional, Patel, Roshal R., additional, Gu, Meidi, additional, Cortez, Maria Angelica, additional, and Welsh, James W., additional

Published
2021
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21. Pulsed radiation therapy to improve systemic control of metastatic cancer

Author

Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), He, Kewen; Barsoumian, Hampartsoum B.; Puebla-Osorio, Nahum; Hsu, Ethan Y.; Verma, Vivek; Abana, Chike O.; Chen, Dawei; Patel, Roshal R.; Gu, Meidi; Cortez, Maria Angelica; Welsh, James W., School of Medicine, Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), He, Kewen; Barsoumian, Hampartsoum B.; Puebla-Osorio, Nahum; Hsu, Ethan Y.; Verma, Vivek; Abana, Chike O.; Chen, Dawei; Patel, Roshal R.; Gu, Meidi; Cortez, Maria Angelica; Welsh, James W., and School of Medicine

Abstract

Radiation therapy (RT) is emerging as an interventional modality in the cancer-immunity cycle, augmenting the activation of an adaptive immune response against tumors. RT, particularly in combination with immunotherapy, can enhance immune memory effects and shape the tumor-directed T-cell populations. However, a single cycle of RT delivered to a limited number of polymetastatic lesions is rarely sufficient to achieve systemic control. We hypothesize that several rounds of RT, akin to several rounds of immunotherapeutic drugs, is likely to provide greater clinical benefit to patients with metastatic disease. We propose that the repeated exposure to tumor antigens released by ""pulsed-RT"" (i.e., treating 2-4 tumor lesions with 3 irradiation cycles given one month apart) may amplify the adaptive immune response by expanding the tumor-specific T-cell receptor repertoire, the production of high-affinity tumor antibodies, and the generation of memory lymphocytes and thereby improve immune control of systemic disease., National Cancer Institute; National Institutes of Health; Cancer Center Support (Core) Grant

Published
2021

23. Systemic AAV9.BVES delivery ameliorates muscular dystrophy in a mouse model of LGMDR25

Author

Li, Haiwen, Wang, Peipei, Hsu, Ethan, Pinckard, Kelsey M., Stanford, Kristin I., and Han, Renzhi

Abstract

Limb-girdle muscular dystrophy type R25 (LGMDR25) is caused by recessive mutations in BVESencoding a cAMP-binding protein, characterized by progressive muscular dystrophy with deteriorating muscle function and impaired cardiac conduction in patients. There is currently no therapeutic treatment for LGMDR25 patients. Here we report the efficacy and safety of recombinant adeno-associated virus 9 (AAV9)-mediated systemic delivery of human BVESdriven by a muscle-specific promoter MHCK7 (AAV9.BVES) in BVES-knockout (BVES-KO) mice. AAV9.BVES efficiently transduced the cardiac and skeletal muscle tissues when intraperitoneally injected into neonatal BVES-KO mice. AAV9.BVES dramatically improved body weight gain, muscle mass, muscle strength, and exercise performance in BVES-KO mice regardless of sex. AAV9.BVES also significantly ameliorated the histopathological features of muscular dystrophy. The heart rate reduction was also normalized in BVES-KO mice under exercise-induced stress following systemic AAV9.BVES delivery. Moreover, intravenous AAV9.BVES administration into adult BVES-KO mice after the disease onset also resulted in substantial improvement in body weight, muscle mass, muscle contractility, and stress-induced heart rhythm abnormality. No obvious toxicity was detected. Taken together, these results provide the proof-of-concept evidence to support the AAV9.BVES gene therapy for LGMDR25.

Published
2022
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24. High Plus Low Dose Radiation Strategy in Combination with TIGIT and PD1 Blockade to Promote Systemic Antitumor Responses

Author

Hampartsoum B. Barsoumian, Duygu Sezen, Hari Menon, Ahmed I. Younes, Yun Hu, Kewen He, Nahum Puebla-Osorio, Mark Wasley, Ethan Hsu, Roshal R. Patel, Liangpeng Yang, Maria A. Cortez, James W. Welsh, Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), Barsoumian, Hampartsoum B., Menon, Hari, Younes, Ahmed I., Hu, Yun, He, Kewen, Puebla-Osorio, Nahum, Wasley, Mark, Hsu, Ethan, Patel, Roshal R., Yang, Liangpeng, Cortez, Maria A., Welsh, James W., and School of Medicine

Subjects
Cancer Research, lung cancer, radiotherapy, immunotherapy, abscopal, TIGIT, Oncology, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Radiotherapy, Immunotherapy, Abscopal, Lung cancer, RC254-282, Article
Abstract

This study combines a novel strategy of radiotherapy that utilizes high- and low- dose radiation with immune oncology agents (anti-TIGIT and anti-PD1 monoclonal antibodies) in order to overcome the inhibitory tumor stroma and battle tumors systemically. The findings from this work will impact how checkpoint inhibitors are delivered to maximize their efficacy. Tumors deploy various immune-evasion mechanisms that create a suppressive environment and render effector T-cells exhausted and inactive. Therefore, a rational utilization of checkpoint inhibitors may alleviate exhaustion and may partially restore antitumor functions. However, in high-tumor-burden models, the checkpoint blockade fails to maintain optimal efficacy, and other interventions are necessary to overcome the inhibitory tumor stroma. One such strategy is the use of radiotherapy to reset the tumor microenvironment and maximize systemic antitumor outcomes. In this study, we propose the use of anti-PD1 and anti-TIGIT checkpoint inhibitors in conjunction with our novel RadScopal technique to battle highly metastatic lung adenocarcinoma tumors, bilaterally established in 129Sv/Ev mice, to mimic high-tumor-burden settings. The RadScopal approach is comprised of high-dose radiation directed at primary tumors with low-dose radiation delivered to secondary tumors to improve the outcomes of systemic immunotherapy. Indeed, the triple therapy with RadScopal + anti-TIGIT + anti-PD1 was able to prolong the survival of treated mice and halted the growth of both primary and secondary tumors. Lung metastasis counts were also significantly reduced. In addition, the low-dose radiation component reduced TIGIT receptor (PVR) expression by tumor-associated macrophages and dendritic cells in secondary tumors. Finally, low-dose radiation within triple therapy decreased the percentages of TIGIT(+) exhausted T-cells and TIGIT(+) regulatory T-cells. Together, our translational approach provides a new treatment alternative for cases refractory to other checkpoints and may bring immunotherapy into a new realm of systemic disease control., United States Department of Health and Human Services; National Institutes of Health (NIH); NIH National Cancer Institute (NCI)

Published
2022

25. Pulsed radiation therapy to improve systemic control of metastatic cancer

Author

Maria Angelica Cortez, Ethan Y Hsu, Meidi Gu, Chike O. Abana, Kewen He, Vivek Verma, Dawei Chen, James W. Welsh, Nahum Puebla-Osorio, Roshal R. Patel, Hampartsoum B. Barsoumian, Duygu Sezen, Sezen, Duygu (ORCID 0000-0002-4505-2280 & YÖK ID 170535), He, Kewen, Barsoumian, Hampartsoum B., Puebla-Osorio, Nahum, Hsu, Ethan Y., Verma, Vivek, Abana, Chike O., Chen, Dawei, Patel, Roshal R., Gu, Meidi, Cortez, Maria Angelica, Welsh, James W., and School of Medicine

Subjects
Pulsed radiation, Systemic disease, Cancer Research, business.industry, medicine.medical_treatment, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Cancer, adaptive immunity, Immunotherapy, Disease, memory effect, medicine.disease, Acquired immune system, radiation therapy, Radiation therapy, metastatic cancer, Antigen, Oncology, Perspective, medicine, Cancer research, immunotherapy, business, Metastatic cancer, Adaptive immunity, Memory effect, RC254-282
Abstract

Radiation therapy (RT) is emerging as an interventional modality in the cancer-immunity cycle, augmenting the activation of an adaptive immune response against tumors. RT, particularly in combination with immunotherapy, can enhance immune memory effects and shape the tumor-directed T-cell populations. However, a single cycle of RT delivered to a limited number of polymetastatic lesions is rarely sufficient to achieve systemic control. We hypothesize that several rounds of RT, akin to several rounds of immunotherapeutic drugs, is likely to provide greater clinical benefit to patients with metastatic disease. We propose that the repeated exposure to tumor antigens released by ""pulsed-RT"" (i.e., treating 2-4 tumor lesions with 3 irradiation cycles given one month apart) may amplify the adaptive immune response by expanding the tumor-specific T-cell receptor repertoire, the production of high-affinity tumor antibodies, and the generation of memory lymphocytes and thereby improve immune control of systemic disease., National Cancer Institute; National Institutes of Health; Cancer Center Support (Core) Grant

Published
2021

26. NLRP3 agonist enhances radiation-induced immune priming and promotes abscopal responses in anti-PD1 resistant model.

Author

Barsoumian HB, He K, Hsu E, Bertolet G, Sezen D, Hu Y, Cortez MA, and Welsh JW

Abstract

Radiotherapy (XRT), a well-known activator of the inflammasome and immune priming, is in part capable of reversing resistance to anti-PD1 treatment. Although NLRP3 is typically observed for its role in exacerbating XRT-induced tissue damage, the NLRP3 inflammasome can also be protective and augment the effect of XRT when used in proper dosing and sequencing. However, whether NLRP3 agonist boosts radiation-induced immune priming and promote abscopal responses in anti-PD1 resistant model is still unknown. Therefore, in this study, we paired intratumoral injection of an NLRP3 agonist with XRT to stimulate the immune system in both wild type (344SQ-P) and anti-PD1 resistant (344SQ-R) murine-implanted lung adenocarcinoma models. We found that the combination of XRT + NLPR3 agonist enhanced control of implanted lung adenocarcinoma primary as well as secondary tumors in a radiological dose-dependent manner, in which 12Gy x 3 fractions of stereotactic XRT was better than 5Gy x 3, while 1Gy x 2 did not improve the NLRP3 effect. Survival and tumor growth data also showed significant abscopal response with the triple therapy (12Gyx3 + NLRP3 agonist + α-PD1) in both 344SQ-P and 344SQ-R aggressively growing models. Multiple pro-inflammatory cytokines (IL-1b, IL-4, IL-12, IL-17, IFN-γ and GM-CSF) were elevated in the serum of mice treated with XRT + NLRP3 or triple therapy. The Nanostring results showed that NLRP3 agonist is capable of increasing antigen presentation, innate function, and T-cell priming. This study can be of particular importance to treat patients with immunologically-cold solid tumors whom are also refractory to prior checkpoint treatments.

Published
2023
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27. Radiation Therapy Modulates Tumor Physical Characteristics to Reduce Intratumoral Pressure and Enhance Intratumoral Drug Delivery and Retention.

Author

Barsoumian HB, Sheth RA, Ramapriyan R, Hsu E, Gagea M, Crowley K, Sezen D, Williams M, and Welsh JW

Abstract

Purpose: High intratumoral pressure, caused by tumor cell-to-cell interactions, interstitial fluid pressure, and surrounding stromal composition, plays a substantial role in resistance to intratumoral drug delivery and distribution. Radiation therapy (XRT) is commonly administered in conjunction with different intratumoral drugs, but assessing how radiation can reduce pressure locally and help intratumoral drug administration and retention is important., Methods and Materials: 344SQ-parental or 344SQ-anti-programmed cell death protein 1-resistant lung adenocarcinoma cells were established in 129Sv/Ev mice, and irradiated with either 1 Gy × 2, 5 Gy × 3, 8 Gy × 3, 12 Gy × 3, or 20 Gy × 1. Intratumoral pressure was measured every 3 to 4 days after XRT. Contrast dye was injected into the tumors 3- and 6-days after XRT, and imaged to measure drug retention., Results: In the 344SQ-parental model, low-dose radiation (1 Gy × 2) created an early window of reduced intratumoral pressure 1 to 3 days after XRT compared with untreated control. High-dose stereotactic radiation (12 Gy × 3) reduced intratumoral pressure 3 to 12 days after XRT, and 20 Gy × 1 showed a delayed pressure reduction on day 12. Intermediate doses of radiation did not significantly affect intratumoral pressure. In the more aggressive 344SQ-anti-programmed cell death protein 1-resistant model, low-dose radiation reduced pressure 1 to 5 days after XRT, and 12 Gy × 3 reduced pressure 1 to 3 days after XRT. Moreover, both 1 Gy × 2 and 12 Gy × 3 significantly improved drug retention 3 days after XRT; however, there was no significance detected 6 days after XRT. Lastly, a histopathologic evaluation showed that 1 Gy × 2 reduced collagen deposition within the tumor, and 12 Gy × 3 led to more necrotic core and higher extracellular matrix formation in the tumor periphery., Conclusions: Optimized low-dose XRT, as well as higher stereotactic XRT regimen led to a reduction in intratumoral pressure and increased drug retention. The findings from this work can be readily translated into the clinic to enhance intratumoral injections of various anticancer agents., (© 2022 The Authors.)

Published
2022
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