Multiscale Tumor Spatiokinetic Model for Intraperitoneal Therapy

Au, Jessie L.-S.; Guo, Peng; Gao, Yue; Lu, Ze; Wientjes, M. Guillaume; Tsai, Max

doi:10.1208/s12248-014-9574-y

Cited by 28 publications

(42 citation statements)

References 54 publications

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“…Parameters that were assumed to be spatially varying were the volume fractions of the different components (interstitium, vasculature and cellular), the drug diffusivity, the surface to volume ratio of the vascular component, and the tissue permeability. The model was validated using the data of a mouse model with IP tumours (n = 4) and the experimental results were in good agreement with the simulated results with a 1 % deviation for the total drug AUC and 23 % deviations for individual data points [47].…”

Section: Tissue Level: Distributed Modelsmentioning

confidence: 62%

“…The incorporation of accurate IFP profiles might offer a significant advantage over using an idealized pressure profile. Au et al [47] created three different tumour zones in their model to account for the spatial variations of certain parameters within the tumour tissue.…”

Section: Discussionmentioning

confidence: 99%

“…In 2014, a spatiokinetic model for intraperitoneal administration of paclitaxel was described by Au et al [47]. In a single spherical tumour nodule model (r = 2 mm) which consists of three separate layers, the cellular level of the tumour tissue was averaged and modelled as a homogeneous, isotropic porous medium.…”

Section: Tissue Level: Distributed Modelsmentioning

confidence: 99%

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Modelling drug transport during intraperitoneal chemotherapy

Steuperaert

Debbaut

Segers

et al. 2017

Pleura and Peritoneum

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Despite a strong rationale for intraperitoneal (IP) chemotherapy, the actual use of the procedure is limited by the poor penetration depth of the drug into the tissue. Drug penetration into solid tumours is a complex mass transport process that involves multiple parameters not only related to the used cytotoxic agent but also to the tumour tissue properties and even the therapeutic setup. Mathematical modelling can provide unique insights into the different transport barriers that occur during IP chemotherapy as well as offer the possibility to test different protocols or drugs without the need for in vivo experiments. In this work, a distinction is made between three different types of model: the lumped parameter model, the distributed model and the cell-based model. For each model, we discuss which steps of the transport process are included and where assumptions are made. Finally, we focus on the advantages and main limitations of each category and discuss some future perspectives for the modelling of IP chemotherapy.

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Section: Tissue Level: Distributed Modelsmentioning

confidence: 62%

Section: Discussionmentioning

confidence: 99%

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Modelling drug transport during intraperitoneal chemotherapy

Steuperaert

Debbaut

Segers

et al. 2017

Pleura and Peritoneum

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“…The current report summarizes our findings in IP therapy; detailed information can be found in our earlier research publications and reviews (3)(4)(5)(6)(7)(8)(9).…”

Section: Introductionmentioning

confidence: 90%

“…To our knowledge, there have been no or few studies to address these critical issues. For example, there have been multiple studies, including several from our group, on the pharmacokinetics of IP therapy (e.g., 3,7,8,15,25,87). But these studies primarily deal with the time scale and not the spatial scale.…”

Section: Part IV Perspectivesmentioning

confidence: 99%

Versatility of Particulate Carriers: Development of Pharmacodynamically Optimized Drug-Loaded Microparticles for Treatment of Peritoneal Cancer

Wientjes

2015

AAPS J

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Abstract. Intraperitoneal (IP) chemotherapy confers significant survival benefits in cancer patients. However, several problems, including local toxicity and ineffectiveness against bulky tumors, have prohibited it from becoming a standard-of-care. We have developed drug-loaded, tumor-penetrating microparticles (TPM) to address these problems. TPM comprises two components and uses the versatile PLGA or poly(lacticco-glycolic acid) copolymer to provide tumor-selective adherence and pharmacodynamically optimized fractionated dosing to achieve the desired tumor priming (which promotes particle penetration into tumors) plus immediate and sustained antitumor activity. Preclinical studies show that TPM is less toxic and more effective against several IP metastatic tumors with different characteristics (fast vs. slow growing, porous vs. densely packed structures, wide-spread vs. solitary tumors, early vs. late stage, with or without peritoneal carcinomatosis or ascites), compared to the intravenous paclitaxel/ Cremophor micellar solution that has been used off-label in previous IP studies. TPM further requires less frequent dosing. These encouraging preclinical results have motivated the follow-up clinical development of TPM. We are working with National Institutes of Health on the IND-enabling studies.

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