Novel bilayer dissolving microneedle arrays with concentrated PLGA nano-microparticles for targeted intradermal delivery: Proof of concept

Vora, Lalitkumar K.; Donnelly, Ryan F.; Larrañeta, Eneko; González-Vázquez, Patricia; Thakur, Raghu; Vavia, Pradeep R.

doi:10.1016/j.jconrel.2017.10.005

Cited by 114 publications

(86 citation statements)

References 41 publications

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“…This study builds upon work previously carried out in our research group, where we described the formulation, development and in vivo testing of dissolving microarray patches (MAPs) incorporating RPV LA for intradermal delivery . MAPs are micrometer‐scale devices, which have undergone extensive research in the fields of intradermal drug and vaccine delivery and have also been used in combination with nanosuspensions but had never before been used in the delivery of a LA nanosuspension, the potential of which we had previously theorized . An integral part of the present study, carried out with colleagues in PATH, involved conducting preliminary market research, early in the design concept phase, to inform the potential acceptability of MAPs for delivery of HIV PrEP intravaginally.…”

Section: Introductionmentioning

confidence: 89%

Design, Formulation, and Evaluation of Novel Dissolving Microarray Patches Containing Rilpivirine for Intravaginal Delivery

Crudden

Larrañeta

Clark

et al. 2019

Adv Healthcare Materials

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Antiretroviral (ARV) drugs have, for many years, been studied and administered in the prevention and treatment of human immunodeficiency virus (HIV). Intramuscular (IM) injection of long acting (LA) ARVs are in clinical development, but injectable formulations require regular access to healthcare facilities and disposal facilities for sharps. The development of a discrete, self‐administered, and self‐disabling vehicle to deliver ARVs could obviate these issues. This study describes the formulation, mechanical characterization, and in vivo evaluation of dissolving microarray patches (MAPs) containing a LA nanosuspension of the ARV, rilpivirine (RPV, RPV LA), for vaginal delivery. This is the first study to apply MAPs into vaginal tissue. The RPV LA MAPs penetrate ex vivo skin and a synthetic vaginal skin model and withstand the effects of potential dragging motion across synthetic vaginal epithelium. In in vivo studies, the mean plasma concentration of RPV in rats at the 56 day endpoint (116.5 ng mL−1) is comparable to that achieved in the IM control cohort (118.9 ng mL−1). RPV is detected systemically, in lymph and vaginal tissue, indicating the potential to deliver RPV LA to primary sites of viral challenge and replication. This innovative research has future potential for patients and healthcare workers, particularly in low‐resource settings.

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Section: Introductionmentioning

confidence: 89%

Design, Formulation, and Evaluation of Novel Dissolving Microarray Patches Containing Rilpivirine for Intravaginal Delivery

Crudden

Larrañeta

Clark

et al. 2019

Adv Healthcare Materials

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“…[44][45][46][47] Another strategy that can enable dissolving microneedles to release the payloads in a controlled manner is to combine nano-and microparticle technologies. 48,49 Vora et al fabricated PVP-based microneedles loaded with a mixture of poly (lactic-co-glycolic acid) (PLGA) nanoparticles and microparticles. 48 The developed system showed good mechanical and In the first step, the microneedles quickly dissolved and released the free drug as well as another drug encapsulated in PLGA microparticles.…”

Section: Slow-dissolving Microneedles Made Of Hydrophilic Polymersmentioning

confidence: 99%

Current Advances in Sustained Release Microneedles

Sun

2020

Pharmaceutical Fronts

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AbstractMicroneedles have been extensively investigated for intradermal delivery of drugs and vaccines due to advantages including high skin delivery efficiency, improved patient compliance, and potential for self-administration. However, traditional microneedles cannot regulate the release kinetics of payloads, limiting therapeutic utility of the biotherapeutics. Recently, several types of microneedles with sustained release properties, including slow-dissolving microneedles made of hydrophilic polymers, degradable microneedles made of hydrophobic polymers, and bioresponsive microneedles made of bioresponsive polymers, have been developed and investigated for intradermal delivery of the biotherapeutics, aiming for improving their therapeutic potency, reducing side effects and administration frequency, and further improving patient compliance. In this review, we introduced different types of microneedles that have been designed for sustained release of the payloads, summarized various applications of these microneedles, and discussed the future prospects of this technology.

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“…Dissolving microneedles efficiently deliver therapeutic agents through the dissolution of their biocompatible polymer matrices after penetration into the skin (Vora, Donnelly, et al, ; Vora, Sita, & Vavia, ). DMNs rely on the water solubility of both the loaded drug and the polymer matrix.…”

Section: Introductionmentioning

confidence: 99%

Novel nanosuspension‐based dissolving microneedle arrays for transdermal delivery of a hydrophobic drug

Vora

Vavia

Larrañeta

et al. 2018

J of Interdiscip Nanomed

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A nanosuspension (NS) was formulated from the lipophilic molecule cholecalciferol (CL) for enhanced transdermal delivery by embedding this NS into hydrophilic polymer‐based dissolving microneedles (DMNs). First, the NS was prepared by sonoprecpitation with different molecular weights of poly (vinyl alcohol) and poly (vinyl pyrrolidone) as stabilizers and using two different solvents for particle size and zeta potential optimization. DMN arrays were then prepared by centrifugation‐assisted micromoulding and subsequently dried. Poly (vinyl alcohol) (10 kDa) produced a NS with the lowest particle size ( ~ 300 nm). These particles yielded DMN with good mechanical properties when combined with aqueous blends of high molecular weight poly (vinyl pyrrolidone) (360 kDa). The particle size remained similar before and after MN preparation, as confirmed by scanning electron microscope. The CL was in the amorphous state in the free particles as well as in the DMN and, hence, no characteristic CL peak was observed in differential scanning calorimetry or X‐ray diffraction. DMN arrays were found to be strong enough to bear a 32 N force, showed efficient skin insertion, and penetrated down to the third layer (depth ≈ 375 μm) of the validated skin model Parafilm M®. An ex vivo porcine skin permeation study using Franz diffusion cells compared the permeation of CL from CL‐NS‐loaded DMN arrays and MN‐free CL‐NS patches. It was observed that CL‐NS‐loaded DMN arrays showed significantly higher (498.19 μg ± 89.3 μg) ex vivo skin permeation compared with MN‐free CL‐NS patches (73.2 μg ± 26.5 μg) over 24 h. This is the first time a NS of a hydrophobic drug has been successfully incorporated into dissolving MN and suggest that NS‐containing DMN systems could be a promising strategy for transdermal delivery of hydrophobic drugs.

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Novel bilayer dissolving microneedle arrays with concentrated PLGA nano-microparticles for targeted intradermal delivery: Proof of concept

Cited by 114 publications

References 41 publications

Design, Formulation, and Evaluation of Novel Dissolving Microarray Patches Containing Rilpivirine for Intravaginal Delivery

Design, Formulation, and Evaluation of Novel Dissolving Microarray Patches Containing Rilpivirine for Intravaginal Delivery

Current Advances in Sustained Release Microneedles

Novel nanosuspension‐based dissolving microneedle arrays for transdermal delivery of a hydrophobic drug

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