MET-4 Clinical investigation of the cases recurred as dissemination after postoperative local irradiation for metastatic brain tumors

Last year, the authors examined the outcome of the patients with metastatic brain tumor (MBT)treated by whole-brain irradiation (WBRT)or local irradiation (LRT)after surgery. As a result, it was shown that the overall survival (OS) was same but the recurrence pattern was different. Furthermore, it was shown that there were some cases with disseminated recurrence in the LRT group. One year has passed, cases showing disseminated recurrence after LRT were examined. The subjects were 28 patients for whom LRT was selected as post-surgical irradiation since December 2017, with an average age of 66.2 years and a male-female ratio of 19: 9. Non-small cell lung cancer was the most in 17 cases. During the observation period, recurrence was observed in 12 cases, new outbreaks at other sites in 8 cases, disseminated recurrence in 4 cases, and no local recurrence. There was no clear difference in kinds of carcinoma and removal fashion between disseminated recurrence cases and other cases. Disseminated recurrence occurred between 3–10 months after surgery, 2 presented with headache, 1 with convulsions, 1 confirmed during follow-up of images, and all underwent WBRT. The lesions shrank after irradiation, but they were easy to re-grow, and the prognosis was poor. On the other hand, 10 cases died in 24 cases other than disseminated recurrence, but all cases died of primary cancer. Although LRT after surgery is non-inferior to WBRT in terms of OS and has the advantage of maintaining cognitive function, this study shows that there is a considerable risk of disseminated recurrence regardless of the removal fashion or kinds of carcinoma. It was also shown that prognosis after disseminated recurrence was poor. It is desirable to select postoperative irradiation after explaining the recurrence pattern, and when LRT is adopted, it is necessary to consider setting a short observation interval immediately after irradiation.

Targeted Radiation Evokes Catecholamine Production Triggering Systemic Inflammatory Responses

Targeted irradiation (TR) is widely used for tumor treatment in the clinic. TR benefits tumor therapy through direct effects as well as poorly understood systemic (abscopal) effects. Recent studies suggest that the systemic innate and acquired immune responses to TR contribute to elimination of tumor cells, but also cause systemic inflammation with prolonged tissue injury that may result in secondary malignancies. To elucidate and eventually target the mechanisms underlying these systemic effects of TR, we utilized a murine model using the small animal radiation research platform (SARRP). To define the dynamics of cytokine production and immune responses after TR, we administered local irradiation to a single tibia of 6-8 week old C57BL/6 male mice using a single dose of 15 Gy. We analyzed bone marrow (BM) and BM extracellular fluid (BMEF) from both the irradiated (TR) and non-irradiated, contralateral (CONT) tibiae at 2, 6, 48 hours, 1 and 3 weeks post-TR, performing phenotypic (flow cytometry) and cytokine analyses. As a tumor-bearing model, we utilized 3-4 weeks old C57BL/6 mice injected with Rhabdomyosarcoma (RMS) in one hind limb, and treated with (1) one dose i.p injection of 1mg/Kg Vincristine (Vin) as chemotherapy model, (2) 4.8GyX5times fractionated TR to the tumor area and (3) combination (TR+Vin) therapy. Analysis of peripheral blood (PB), BM, BMEF was performed 3 weeks after the final TR dose (n = 5-13 mice/time point). We found that multiple inflammatory cytokines and chemokines, such as IL-1b, IL-18, CCL2, CCL3, CXCL2, CXCL9, CXCL10 were upregulated from very early phase (2hrs) up to 48hrs in BMEF of the radiated tibiae. Consistent with the dynamics of these cytokines, we observed influx of myeloid cells in both TR and CONT side and expansion of T cells peaking at 6hrs in BM. At the same time of these immune responses, Norepinephrine (NE) was elevated in BMEF even in CONT side. In the tumor-bearing model of RMS, fractionated TR eliminated the tumor while systemically expanding CD8+ cytotoxic T cells and reducing neutrophils. Vin alone did not eliminate the tumor and was associated with systemic decrease of lymphoid cells and expansion of neutrophils. In Vin+TR, tumor control and CD8+ cell expansion were restored, with normalization of neutrophils. These data suggest that TR in the setting of tumor differentially activates lymphoid and myeloid cells. Since recent studies showed catecholamine production from myeloid cells may augment cytokine production in the setting of infection, we hypothesized that BM myeloid cells respond to radiation-induced cell damage by producing catecholamines that trigger a systemic inflammatory response after TR. To test this hypothesis, we utilized standard long-term bone marrow cultures (LT-BM) that reproduce three-dimensional BM structures with myeloid-skewing in vitro, and irradiated them to look at inflammatory changes induced by radiation at 2, 6 and 24hrs. In this experimental model, 5Gy of radiation led to the elevation of NE along with the production of chemokines CCL2, CCL3, CXCL2, CXCL9 mostly peaking at 6hrs in the cell culture supernatants. In contrast, these responses could not be reproduced in spleen cultures, which also had a much lower baseline NE production compared to LT-BMs. These data indicate that radiation induced-chemokine elevations might come from myeloid cells stimulated by NE, independent of systemic innervation. To define the contribution of catecholamines to cytokine production in LT-BM, we directly stimulated culture-LT-BM with NE and Isoproterenol, a pan beta stimulant. While both agents showed similar effect and increased CXCL2, CXCL9, CCL2 and CCL3 at 6hrs, they decreased CXCL10 level, suggesting that catecholamine mostly stimulate myeloid cells but rather inhibit lymphoid activation through chemokine production. Together, these data show that local irradiation initiates global immune responses, and identify local BM production of NE as its potential trigger. Blocking local catecholamine production in the bone marrow could therefore be a positive adjuvant to TR in tumor treatment by inhibiting unfavorable effects of radiation, such as chronic inflammation with systemic increases of neutrophils, while facilitating expansion and recruitment of the cytotoxic T cells which play an essential beneficial role in tumor immunity. Disclosures No relevant conflicts of interest to declare.

Radiotherapy Response Assessment of Multiple Myeloma: A Dual-Energy CT Approach With Virtual Non-Calcium Images

BackgroundLife expectancy of patients with multiple myeloma (MM) has increased over the past decades, underlining the importance of local tumor control and avoidance of dose-dependent side effects of palliative radiotherapy (RT). Virtual noncalcium (VNCa) imaging from dual-energy computed tomography (DECT) has been suggested to estimate cellularity and metabolic activity of lytic bone lesions (LBLs) in MM.ObjectiveTo explore the feasibility of RT response monitoring with DECT-derived VNCa attenuation measurements in MM.MethodsThirty-three patients with 85 LBLs that had been irradiated and 85 paired non-irradiated LBLs from the same patients were included in this retrospective study. Irradiated and non-irradiated LBLs were measured by circular regions of interest (ROIs) on conventional and VNCa images in a total of 216 follow-up measurements (48 before and 168 after RT). Follow-ups were rated as therapy response, stable disease, or local progression according to the MD Anderson criteria. Receiver operating characteristic (ROC) analysis was performed to discriminate irradiated vs. non-irradiated and locally progressive vs. stable/responsive LBLs using absolute attenuation post-irradiation and percentage attenuation change for patients with pre-irradiation DECT, if available.ResultsAttenuation of LBLs decreased after RT depending on the time that had passed after irradiation [absolute thresholds for identification of irradiated LBLs 30.5–70.0 HU [best area under the curve [AUC] 0.75 (0.59–0.91)] and -77.0 to -22.5 HU [best AUC 0.85 (0.65–1.00)]/-50% and -117% to -167% proportional change of attenuation on conventional and VNCa images, respectively]. VNCa CT was significantly superior for identification of RT effects in LBLs with higher calcium content [best VNCa AUC 0.96 (0.91–1.00), best conventional CT AUC 0.64 (0.45–0.83)]. Thresholds for early identification of local irradiation failure were >20.5 HU on conventional CT [AUC 0.78 (0.68–0.88)] and >-27 HU on VNCa CT [AUC 0.83 (0.70–0.96)].ConclusionTherapy response of LBLs after RT can be monitored by VNCa imaging based on regular myeloma scans, which yields potential for optimizing the lesion-specific radiation dose for local tumor control. Decreasing attenuation indicates RT response, while above threshold attenuation of LBLs precedes local irradiation failure.

Local Irradiation of Mouse Tooth Germ Gives Insight into the Direct Effects of Irradiation on Root Development

To elucidate the mechanism underlying the failure of root formation after irradiation, we established a method of local irradiation of the molar tooth germ and demonstrated that radiation directly affected dental root development. In the current study, to locally irradiate the lower first molars of 5-day-old C57BL/6J mice, we used lead glass containing a hole as a collimator. We confirmed that our local irradiation method targeted only the tooth germ. The irradiated root was immature in terms of apical growth, and dentin formation was irregular along the outside of the root apices. Moreover, calcified tissue apically surrounded Hertwig's epithelial root sheath, which disappeared abnormally early. This method using a local irradiation experimental model will facilitate research into radiation-induced disorders of dental root formation.

Combining losartan with radiotherapy increases tumor control and inhibits lung metastases from a HER2/neu-positive orthotopic breast cancer model

Background Patients with metastatic HER2/neu-positive (HER2/neu +) breast cancer (BC) often experience treatment resistance, disease recurrences and metastases. Thus, new approaches for improving the treatment of HER2/neu + BC to prevent metastatic dissemination are urgently needed. Our previous studies have shown that losartan, an angiotensin receptor blocker, increases tumor perfusion and decreases hypoxia in a number of tumor models. Hypoxia reduces the efficacy of radiation and increases metastases. We therefore hypothesized that by modifying tumor stroma and increasing oxygenation, losartan will improve the outcome of radiotherapy and inhibit disease progression in a highly metastatic HER2/neu + murine BC model. Methods We established a metastatic HER2/neu + murine BC line (MCa-M3C) and used it to generate mammary fat pad isografts in syngeneic female FVB/N mice. Starting on day 3 after orthotopic tumor implantation, we administered a 7-day losartan treatment (40 mg/kg BW, gavage daily); or a 7-day losartan treatment followed by 20 Gy single dose local irradiation (S-IR) on day 10 (tumor size ~ 100 mm3), or 20 Gy local fractionated (5 × 4 Gy daily) irradiation (F-IR) on days 10–14. We analyzed tumor-growth delay (TGD), development of spontaneous lung metastases, animal survival, tumor vascular density, and tumor hypoxia. Results Treatments with S-IR, F-IR, Losartan + S-IR, or Losartan + F-IR resulted in a significantly increased TGD (8–16 days) in MCa-M3C tumors versus controls. However, the combination of Losartan + S-IR and Losartan + F-IR further enhanced tumor response to radiation alone by increasing TGD an additional 5 to 8 days for both single and fractionated dose irradiation (P < 0.01), decreasing lung metastasis (Losartan + IR vs. Control, P < 0.025), and increasing animal survival (Losartan + IR vs. Control, P = 0.0303). In addition, losartan treatment significantly increased tumor vascularity (P = 0.0314) and decreased pimonidazole positive (hypoxic) area (P = 0.0002). Conclusions Combining losartan with local irradiation significantly enhanced tumor response, at least in part via reduced tumor hypoxia presumably due to increased tumor perfusion. Our findings suggest that combining losartan with radiotherapy is a potential new treatment strategy for local control and inhibiting metastasis in HER2 + BC.

A Review of Light Sources and Enhanced Targeting for Photodynamic Therapy.

: Photodynamic Therapy (PDT), as a clinically approved modality for the treatment of various disordered diseases including cancer, has received great advances in recent years. By preferentially accumulating non-toxic Photosensitizers (PSs) in the pathological area, and in situ generation of cytotoxic reactive oxygen species (ROS) under local irradiation by a light source with appropriate wavelength, PDT works in a dual-selective manner. Over the past decades, numerous studies and reviews on PDT mainly focused on activable PSs and the newly emerging PSs in PDT. However, to the best of our knowledge, there are few articles on the systematic introduction of light sources and limited reports about targeted strategies in PDT. This review comprehensively summarizes various light sources applied in PDT together with typical enhanced targeting strategies, and outlines their advantages and disadvantages, respectively. The clinical applications and future perspectives in light sources are also partly presented and discussed.

Photodynamic Therapy with Mitochondria-targeted Biscyclometalated Ir(III) Complexes. Multi-action Mechanism and Strong influence of the Cyclometallating Ligand

Photodynamic therapy is an alternative to classical chemotherapy due to its potential to reduce side effects by a controlled activation of a photosensitizer through local irradiation, which then interacts with...

Radiation-induced eosinophils improve cytotoxic T lymphocyte recruitment and response to immunotherapy

The efficacy of cancer immunotherapy is dictated by CD8+ T cell infiltration and the nature of the tumor microenvironment (TME). By inflaming the TME to favor CD8+ T cell immunity, radiation is now widely considered as a neoadjuvant for immunomodulation. Here, we observed that local irradiation enhances the infiltration of intratumoral eosinophils, and depletion of eosinophil dampens CD8+ T cell infiltration and diminishes the anti-tumor effectiveness of radiation. Retrospectively, we identified a strong correlation between eosinophilia and survival benefit in radiation-treated cancer patients. Experimentally, we further show that radiation enhances the intratumoral infiltration of adoptive transferred T cells therapy, bolstering eosinophils by intravenous interleukin-5 administration promotes the efficacy of radiation-induced abscopal effect. Together, these results suggest that eosinophil mobilization can be considered as a mechanistically relevant biomarker for predicting the effectiveness of pre-immunotherapy radiation, as well as a new strategy to enhance T cell-mediated immunotherapy against cancers.

EFFECTS OF RADIATION EXPOSURE OF THE BLADDER ON EARLY CHANGES OF EXTRACELLULAR DNA AND OTHER INDICATORS OF PERIPHERAL BLOOD

On the model of radiation cystitis in rats, a decrease in the number of blood cells was found 6 h after local irradiation and an increase in extracellular DNA level was found in 6-24 h with normalization 48 h after exposure. The relative change in the content of extracellular DNA (0 h against 6 h) correlated with changes in triglycerides (0 h against 24 h).