Spatio-Temporal Simulation of First Pass Drug Perfusion in the Liver

Metastases in the liver frequently grow as scattered tumor nodules that neither can be removed by surgical resection nor focally ablated. Previously, we have proposed a novel technique based on irreversible electroporation that may be able to simultaneously treat all nodules in the liver while sparing healthy tissue. The proposed technique requires increasing the electrical conductivity of healthy liver by injecting a hypersaline solution through the portal vein. Aiming to assess the capability of increasing the global conductivity of the liver by means of hypersaline fluids, here, it is presented a mathematical model that estimates the NaCl distribution within the liver and the resulting conductivity change. The model fuses well-established compartmental pharmacokinetic models of the organ with saline injection models used for resuscitation treatments, and it considers changes in sinusoidal blood viscosity because of the hypertonicity of the solution. Here, it is also described a pilot experimental study in pigs in which different volumes of NaCl 20% (from 100 to 200 mL) were injected through the portal vein at different flow rates (from 53 to 171 mL/minute). The in vivo conductivity results fit those obtained by the model, both quantitatively and qualitatively, being able to predict the maximum conductivity with a 14.6% average relative error. The maximum conductivity value was 0.44 second/m, which corresponds to increasing 4 times the mean basal conductivity (0.11 second/m). The results suggest that the presented model is well suited for predicting on liver conductivity changes during hypertonic saline injection.

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“…Based on already reported models, a compartment model was implemented (see Figure ). The model has 4 macroscopic compartments.…”

Section: Methodsmentioning

confidence: 99%

Modeling liver electrical conductivity during hypertonic injection

Castellví

Sánchez-Velázquez

Moll

et al. 2017

Numer Methods Biomed Eng

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“…Indeed, new predictive models should move away from a 'static' target definition as effects are refracted through dynamic systems and may change over space and time, emphasising the importance of pharmacokinetic considerations [42,43]. The localisation of targets influence the action of a drug, whether due to a property of the drug itself (e.g., its exclusion from the bloodbrain barrier or conversion into more or less active metabolites) or of the actual target (e.g., biased signalling) [44,45].…”

Section: Considerations When Designing a Predictive Model For Multitamentioning

confidence: 99%

Polypharmacology Shakes Hands with Complex Aetiopathology

Brodie

Marzo²,

Guy

2015

Trends in Pharmacological Sciences

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“…This requires suitable models of perfusion and flow (Debbaut et al, 2014;Ricken et al, 2010;Schwen et al, 2014;Siggers et al, 2014) that will be integrated with the spatial-temporal models, and at the body scale, the contribution of external influences, for example transport of material from extra-hepatic sources into the liver, that is usually addressed by compartment models (Krauss et al, 2012).…”

Section: The Iterative Cycles Of Multi-scale Model Developmentmentioning

confidence: 99%