Predicting transdermal fentanyl delivery using mechanistic simulations for tailored therapy

Defraeye, Thijs; Bahrami, Flora; Ding, Liang; Malini, Riccardo Innocenti; Terrier, Alexandre; Rossi, René M.

doi:10.1101/2020.06.16.154195

Cited by 7 publications

(23 citation statements)

References 76 publications

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“…The funder was not involved in the study design, collection, analysis, interpretation of data, the writing of this article or the decision to submit it for publication. This manuscript has been released as a pre-print at bioRxiv (Defraeye et al, 2020).…”

Section: Fundingmentioning

confidence: 99%

Predicting Transdermal Fentanyl Delivery Using Mechanistic Simulations for Tailored Therapy

et al. 2020

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Transdermal drug delivery is a key technology for administering drugs. However, most devices are "one-size-fits-all", even though drug diffusion through the skin varies significantly from person-to-person. For next-generation devices, personalization for optimal drug release would benefit from an augmented insight into the drug release and percutaneous uptake kinetics. Our objective was to quantify the changes in transdermal fentanyl uptake with regards to the patient's age and the anatomical location where the patch was placed. We also explored to which extent the drug flux from the patch could be altered by miniaturizing the contact surface area of the patch reservoir with the skin. To this end, we used validated mechanistic modeling of fentanyl diffusion, storage, and partitioning in the epidermis to quantify drug release from the patch and the uptake within the skin. A superior spatiotemporal resolution compared to experimental methods enabled in-silico identification of peak concentrations and fluxes, and the amount of stored drug and bioavailability. The patients' drug uptake showed a 36% difference between different anatomical locations after 72 h, but there was a strong interpatient variability. With aging, the drug uptake from the transdermal patch became slower and less potent. A 70-year-old patient received 26% less drug over the 72-h application period, compared to an 18-year-old patient. Additionally, a novel concept of using micron-sized drug reservoirs was explored in silico. These reservoirs induced a much higher local flux (µg cm-2 h-1) than conventional patches. Up to a 200-fold increase in the drug flux was obtained from these small reservoirs. This effect was mainly caused by transverse diffusion in the stratum corneum, which is not relevant for much larger conventional patches. These micron-sized drug reservoirs open new ways to individualize reservoir design and thus transdermal therapy. Such computer-aided engineering tools also have great potential for in-silico design and precise control of drug delivery systems. Here, the validated mechanistic models can serve as a key building block for developing digital twins for transdermal drug delivery systems.

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Section: Fundingmentioning

confidence: 99%

Predicting Transdermal Fentanyl Delivery Using Mechanistic Simulations for Tailored Therapy

et al. 2020

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“…Also, first-generation TDDS are analyzed in-silico to increase our insight into how these systems interact with the patient's skin [10]. Here, drug uptake differences between different substances [11] or age categories of patients [12] were targeted. Also, the impact of the composition of the stratum corneum and viable epidermis on the drug uptake was quantified [13], [14].…”

Section: Introductionmentioning

confidence: 99%

“…A key advantage of such first-principles-based modeling is the high spatial and temporal resolution they offer. Transient changes in concentration profiles can be identified within different skin layers during the uptake process [12], [15]. This spatiotemporal resolution enables us to virtually probe the drug transport inside and out of the skin in time and space.…”

Section: Introductionmentioning

confidence: 99%

“…Another advantage is that such in-silico tests can be performed swiftly and noninvasively, without any side effects for the patient. Physics-based modeling opens new ways of tailoring TDD therapy for patients or patient groups [12]. This deterministic approach is also suffering from statistical variability in the data due to biological variability or measurement uncertainty.…”

Section: Introductionmentioning

confidence: 99%

“…Simulating, however, also consumes a lot of time and resources, making it is usually not more efficient than measuring the parameters separately. As a third way, modelers just source these parameters from literature data during model setup instead ( [12], [24]- [26]). Due to a lack of appropriate data, often, data of other drugs with similar molecular weight and lipophilicity are taken [21].…”

Section: Introductionmentioning

confidence: 99%

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Inverse mechanistic modeling of transdermal drug delivery for fast identification of optimal model parameters

Defraeye

Bahrami

Rossi

2020

Preprint

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Transdermal drug delivery systems are a key technology to administer drugs with a high first-pass effect in a non-invasive and controlled way. Physics-based modeling and simulation are on their way to become a cornerstone in the engineering of these healthcare devices since it provides a unique complementarity to experimental data and insights. Simulations enable to virtually probe the drug transport inside the skin at each point in time and space. However, the tedious experimental or numerical determination of material properties currently forms a bottleneck in the modeling workflow. We show that multiparameter inverse modeling to determine the drug diffusion and partition coefficients is a fast and reliable alternative. We demonstrate this strategy for transdermal delivery of fentanyl. We found that inverse modeling reduced the normalized root mean square deviation of the measured drug uptake flux from 26 to 9%, when compared to the experimental measurement of all skin properties. We found that this improved agreement with experiments was only possible if the diffusion in the reservoir holding the drug was smaller than the experimentally-measured diffusion coefficients suggested. For indirect inverse modeling, which systematically explores the entire parametric space, 30 000 simulations were required. By relying on direct inverse modeling, we reduced the number of simulations to be performed to only 300, so a factor 100 difference. The modeling approach’s added value is that it can be calibrated once in-silico for all model parameters simultaneously by solely relying on a single measurement of the drug uptake flux evolution over time. We showed that this calibrated model could accurately be used to simulate transdermal patches with other drug doses. We showed that inverse modeling is a fast way to build up an accurate mechanistic model for drug delivery. This strategy opens the door to clinically-ready therapy that is tailored to patients.

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An individualized digital twin of a patient for transdermal fentanyl therapy for chronic pain management

Bahrami

Rossi

Nys

et al. 2023

Drug Deliv. and Transl. Res.

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Fentanyl transdermal therapy is a suitable treatment for moderate-to-severe cancer-related pain. The inter-individual variability of the patients leads to different therapy responses. This study aims to determine the effect of physiological features on the achieved pain relief. Therefore, a set of virtual patients was developed by using Markov chain Monte Carlo (MCMC) based on actual patient data. The members of this virtual population differ by age, weight, gender, and height. Tailored digital twins were developed using these correlated, individualized parameters to propose a personalized therapy for each patient. It was shown that patients of different ages, weights, and gender have significantly different fentanyl blood uptake, plasma fentanyl concentration, pain relief, and ventilation rate. In the digital twins, we included the virtual patients’ response to the treatment, namely, pain relief. Therefore, the digital twin was able to adjust the therapy in silico to have more efficient pain relief. By implementing digital-twin-assisted therapy, the average pain intensity decreased by 16% compared to conventional therapy. The median time without pain increased by 23 h over 72 h. Therefore, the digital twin can be successfully used in individual control of transdermal therapy to reach higher pain relief and maintain steady pain relief. Graphical Abstract (Created with BioRender.com)

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Predicting transdermal fentanyl delivery using mechanistic simulations for tailored therapy

Cited by 7 publications

References 76 publications

Predicting Transdermal Fentanyl Delivery Using Mechanistic Simulations for Tailored Therapy

Predicting Transdermal Fentanyl Delivery Using Mechanistic Simulations for Tailored Therapy

Inverse mechanistic modeling of transdermal drug delivery for fast identification of optimal model parameters

An individualized digital twin of a patient for transdermal fentanyl therapy for chronic pain management

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