Samantha DʼAndrea scite author profile

Pancreatic cancer is characterized by extensive stromal desmoplasia which decreases blood perfusion and impedes chemotherapy delivery. Breaking the stromal barrier could both increase perfusion and permeabilize the tumor, enhancing chemotherapy penetration. Mechanical disruption of the stroma can be achieved using ultrasound-induced bubble activity – cavitation. Cavitation is also known to result in microstreaming and could have the added benefit of actively enhancing diffusion into the tumors. Here, we report the ability to enhance chemotherapeutic drug doxorubicin (Dox) penetration using ultrasound-induced cavitation in a genetically engineered mouse model (KPC mouse) of pancreatic ductal adenocarcinoma. To induce localized inertial cavitation in pancreatic tumors, pulsed high intensity focused ultrasound (pHIFU) was used either during or before doxorubicin administration to elucidate the mechanisms of enhanced drug delivery (active versus passive drug diffusion). For both types, the pHIFU exposures which were associated with high cavitation activity resulted in disruption of the highly fibrotic stromal matrix and enhanced the normalized Dox concentration by up to 4.5 fold compared to controls. Furthermore, normalized Dox concentration was associated with the cavitation metrics (p < 0.01), indicating that high and sustained cavitation results in increased chemotherapy penetration. No significant difference between the outcomes of the two types, i.e., Dox infusion during or after pHIFU treatment, was observed, suggesting that passive diffusion into previously permeabilized tissue is the major mechanism for the increase in drug concentration. Together, the data indicate that pHIFU treatment of pancreatic tumors when resulting in high and sustained cavitation can efficiently enhance chemotherapy delivery to pancreatic tumors.

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Boiling Histotripsy Ablation of Renal Cell Carcinoma in the Eker Rat Promotes a Systemic Inflammatory Response

Schade

Wang

DʼAndrea

et al. 2019

Ultrasound in Medicine & Biology

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Boiling histotripsy (BH) is an experimental focused ultrasound technique that produces non-thermal mechanical ablation. We evaluated the feasibility, short-term histologic effects, and the resulting acute inflammatory response to BH ablation of renal cell carcinoma (RCC) in the Eker rat. Genotyped Eker rats were monitored for de novo RCCs with serial ultrasound (US) imaging. When tumors were ≥8 mm, rats underwent ultrasound-guided extracorporeal ablation of the tumor with BH, a pulsed focused US technique that produces non-thermal mechanical ablation of targeted tissues, or a sham US procedure. Treatments targeted approximately 50% of the largest RCC with a margin of normal kidney. BH treated rats were euthanized at 1 (n=4) or 48 (n=4) hours, and sham subjects (n=4) at 48 hours. Circulating plasma cytokine levels were assessed with multiplex assays prior to and at 0.25, 1, 4, 24 and 48 hours following treatment. Kidneys were collected and processed for histologic assessment, immunohistochemistry and intrarenal cytokine concentration measurements. For statistical analysis Student’s t-test was used. US-guided BH treatment was successful in all animals, producing hypoechoic regions within the targeted volume consistent with BH treatment effect. Grossly, regions of homogenized tissue were apparent with evidence of focal intra-parenchymal hemorrhage. Histologically, BH produced a sharply demarcated region of homogenized tumor and non-tumor tissue containing acellular debris. BH treatment was associated with significantly increased relative concentration of plasma TNF vs. sham treatment (p<0.05) and transient elevations in HMGB1, IL-10 and IL-6 consistent with acute inflammatory response to trauma. Intrarenal cytokine concentrations followed the same trend. At 48 hours, enhanced infiltration of CD8+ T cells was observed by immunohistochemistry in both the treated and un-treated contralateral RCC/kidneys in BH-treated animals vs. sham treatment. BH treatment was well tolerated with transient gross hematuria and a perinephric hematoma developing in one subject each. The study demonstrates the feasibility of BH ablation of de novo RCC and suggests activation of the acute inflammatory cascade following treatment that appears to stimulate CD8+ T cell infiltration of both treated and untreated tumors. Longer duration chronic studies are ongoing to characterize the longevity and robustness of this response.

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Endoscopic high-intensity focused US: technical aspects and studies in an in vivo porcine model (with video)

Khokhlova

Maloney

et al. 2015

Gastrointestinal Endoscopy

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Background High-intensity focused ultrasound (HIFU) is becoming more widely used for non-invasive and minimally invasive ablation of benign and malignant tumors. Recent studies suggest that HIFU can also enhance targeted drug delivery and stimulate an anti-tumor immune response in many tumors. However, targeting of pancreatic and liver tumors using an extracorporeal source is challenging due to the lack of an adequate acoustic window. The development of an endoscopic ultrasound (EUS)-guided HIFU transducer has many potential benefits including improved targeting, decreased energy requirements and decreased potential for injury to intervening structures. Objective To design, develop and test an EUS-guided HIFU transducer for endoscopic applications. Design A pre-clinical, pilot characterization and feasibility study. Setting Academic research center. Patients Studies were performed in an in vivo porcine model. Intervention Thermal ablation of in vivo porcine pancreas and liver was performed with EUS guided focused ultrasound through the gastric tract. Results The transducer successfully created lesions in gel phantoms and ex vivo bovine livers. In vivo studies demonstrated that targeting and creating lesions in the porcine pancreas and liver are feasible. Limitations This is a pre-clinical, single-center feasibility study with a limited number of subjects. Conclusion An EUS-guided HIFU transducer was successfully designed and developed with dimensions that are appropriate for endoscopic use. Feasibility of performing EUS-guided HIFU ablation in vivo has been demonstrated in an in vivo porcine model. Further development of this technology will allow endoscopists to perform precise therapeutic ablation of peri-lumenal lesions without breaching the wall of the gastric tract.

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