Transdermal drug delivery by coated microneedles: geometry effects on drug concentration in blood

Al-Qallaf, Barrak; Das, Diganta Bhusan; Davidson, Adam

doi:10.1002/apj.353

Cited by 31 publications

(24 citation statements)

References 45 publications

(67 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…MNs treated skin and the thickness of the skin change, so the effective thickness of the skin is 362 introduced in consistent with our previous studies [32,33]. Therefore, we deduce the diffusion 363 coefficient from the experiment data of passive diffusion and the effective thickness in this studycan be simply considered as reduction of the real skin thickness.…”

Section: Governing Equations 354supporting

confidence: 66%

“…As discussed earlier in our papers, an effective skin thickness can be defined for MN treated skin 355 which represents the average path length for drug diffusion through the skin [32,33]. Using the 356 same concept, we calculate the effective thickness in this work using the images that we have 357 collected.…”

Section: Governing Equations 354mentioning

confidence: 99%

“…The real skin thickness is 1.6 365 mm which is the average over 20 randomly selected samples. An effective thickness of the MNs 366 treated skin is then calculated using equations (2) and (3) as discussed earlier [33]. 367…”

Section: Governing Equations 354mentioning

confidence: 99%

See 2 more Smart Citations

A New Paradigm for Numerical Simulation of Microneedle-Based Drug Delivery Aided by Histology of Microneedle-Pierced Skin

Han

Das

2015

Journal of Pharmaceutical Sciences

Self Cite

View full text Add to dashboard Cite

Microneedle (MN) is a relatively recent invention and an efficient technology for transdermal 8 drug delivery (TDD). Conventionally, the mathematical models of MNs drug delivery define the 9 shape of the holes created by the MNs in the skin as the same as their actual geometry. 10 Furthermore, the size of the MN holes in the skin is considered to be either the same or a 11 certain fraction of the lengths of the MNs. However, the histological images of the MN treated 12 skin indicate that the real insertion depth is much shorter than the length of the MNs and the 13 shapes may vary significantly from one case to another. In addressing these points, we propose 14 a new approach for modelling MN based drug delivery, which incorporate the histology of MN 15 pierced skin using a number of concepts borrowed from image processing tools. It is expected 16 that the developed approach will provide better accuracy of the drug diffusion profile. A new 17 computer program is developed to automatically obtain the outline of the MNs treated holes and 18 import these images into computer software for simulation of drug diffusion from MN systems. 19This method can provide a simple and fast way to test the quality of MNs design and modelling, 20 as well as simulate experimental studies, e.g., permeation experiments on MN pierced skin 21 using diffusion cell. The developed methodology is demonstrated using two dimensional (2D) 22 numerical modelling of flat MNs (2D). However, the methodology is general and can be 23 implemented for 3D MNs if there is sufficient number of images for reconstructing a 3D image 24 for numerical simulation. Numerical modelling for 3D geometry is demonstrated by using 25 images of an ideal 3D MN. The methodology is not demonstrated for real 3D MN as there are 26 not sufficient numbers of images for the purpose of this paper. 27

show abstract

Section: Governing Equations 354supporting

confidence: 66%

Section: Governing Equations 354mentioning

confidence: 99%

See 1 more Smart Citation

A New Paradigm for Numerical Simulation of Microneedle-Based Drug Delivery Aided by Histology of Microneedle-Pierced Skin

Han

Das

2015

Journal of Pharmaceutical Sciences

Self Cite

View full text Add to dashboard Cite

show abstract

“…During the injection of microneedles, the drug molecules are assumed to move through an isotropic media which is consistent with many previous works (e.g., Davis, 2003). The detailed explanation of FEMLAB has been avoided in this paper due to brevity of the paper and since they were explained in our other work (Davidson et al, 2008;Al-Qallaf et al, 2009). Fig.9.…”

Section: Effect Of Skin Metabolism In Case Of Microneedle Systemsmentioning

confidence: 99%

Transdermal Drug Delivery by Microneedles: Does Skin Metabolism Matter?

Al-Qallaf¹,

Mori²,

Olatunji³

et al. 2009

International Journal of Chemical Reactor Engineering

Self Cite

View full text Add to dashboard Cite

Microneedle arrays have been shown to increase skin permeability for the transdermal delivery of drugs with high molecular weights. Various theoretical studies have been proposed to predict the drug transport behaviour after drug injection using microneedles. However it is important for the optimal design of microneedle systems to consider the effects of biological factors such as skin metabolism and variations in pharmacokinetic parameters as well as to improve the enhancement of skin permeability. A mathematical model for microneedle systems is introduced and applied to simulate the verapamil transport with metabolism in the skin. A comparative analysis for a transdermal delivery of verapamil from microneedles is presented in this paper. The results indicate that the skin metabolism does not markedly affect the skin permeation after verapamil injection using microneedles.

show abstract

“…Both models have been developed on the macroscopic (tissue) and microscopic (cell) levels, where aspects such as metabolic activity, binding to skin components, diffusion and partitioning are considered. In addition, some models focused on the transport through the skin after drug administration with microneedles (Al-Qallaf et al, 2009;Kim et al, 2015;Lv et al, 2006;Zhang et al, 2009). Most of these models focus on transport to the systemic circulation, as opposed to kinetics within the skin.…”

Section: Introductionmentioning

confidence: 99%

A theoretical compartment model for antigen kinetics in the skin

Römgens

Bader

Bouwstra

et al. 2016

European Journal of Pharmaceutical Sciences

View full text Add to dashboard Cite

The skin is a promising location for vaccination with its abundant population of antigen capturing and presenting cells. The development of new techniques, such as the use of microneedles, can facilitate the delivery of vaccines into the skin. In recent years, many different types of microneedle arrays have been designed. However, their geometry and arrangement within an array may be optimized to trigger sufficient antigen presenting cells. A computational model can support the rational design of microneedle arrays. Therefore, the aim of the current study was to describe the distribution and kinetics of a delivered antigen within the skin using a theoretical compartment model, which included binding of antigens to receptors and their uptake by cells, and to determine which parameters should be measured to validate the model for a specific application. Multiple simulations were performed using a high and low antigen delivery dose and a range of values for the rate constants. The results indicated that the cells were highly saturated when a high dose was applied, while for a low dose saturation was only reached in 5% of the simulations. This was caused by the difference in the ratio between the administered dose and the available binding sites and suggests the dose should be adapted to the number of cells and receptors for a specific compound. The sensitivity analysis of the model parameters confirmed that the initial dose and receptor concentrations were indeed the two parameters that had the largest influence on the variance in antigen concentrations within the cells and circulation at equilibrium. Hence, these parameters are important to be measured in vivo. The presented pharmacokinetics model can be used in future computational models to predict the influence of microneedle array geometry to optimize their design.

show abstract

Transdermal drug delivery by coated microneedles: geometry effects on drug concentration in blood

Cited by 31 publications

References 45 publications

A New Paradigm for Numerical Simulation of Microneedle-Based Drug Delivery Aided by Histology of Microneedle-Pierced Skin

A New Paradigm for Numerical Simulation of Microneedle-Based Drug Delivery Aided by Histology of Microneedle-Pierced Skin

Transdermal Drug Delivery by Microneedles: Does Skin Metabolism Matter?

A theoretical compartment model for antigen kinetics in the skin

Contact Info

Product

Resources

About