Modifying release characteristics from 3D printed drug-eluting products

Johan Boetker; Jorrit Water; Johanna Aho; Lærke Arnfast; Adam Bohr; Jukka Rantanen

doi:10.1016/j.ejps.2016.03.013

Modifying release characteristics from 3D printed drug-eluting products

Johan Boetker, Jorrit Water, Johanna Aho, Lærke Arnfast, Adam Bohr, Jukka Rantanen

68 Citationer (Scopus)

Abstract

Abstract This work describes an approach to modify the release of active compound from a 3D printed model drug product geometry intended for flexible dosing and precision medication. The production of novel polylactic acid and hydroxypropyl methylcellulose based feed materials containing nitrofurantoin for 3D printing purposes is demonstrated. Nitrofurantoin, Metolose® and polylactic acid were successfully co-extruded with up to 40% Metolose® content, and subsequently 3D printed into model disk geometries (ø10 mm, h = 2 mm). Thermal analysis with differential scanning calorimetry and solid phase identification with Raman spectroscopy showed that nitrofurantoin remained in its original solid form during both hot-melt extrusion and subsequent 3D printing. Rheological measurements of the different compositions showed that the flow properties were sensitive to the amount of undissolved particles present in the formulation. Release of nitrofurantoin from the disks was dependent on Metolose® loading, with higher accumulated release observed for higher Metolose® loads. This work shows the potential of custom-made, drug loaded feed materials for 3D printing of precision drug products with tailored drug release characteristics.

Originalsprog	Dansk
Tidsskrift	European Journal of Pharmaceutical Sciences
Vol/bind	90
Sider (fra-til)	47-52
Antal sider	6
ISSN	0928-0987
DOI	https://doi.org/10.1016/j.ejps.2016.03.013
Status	Udgivet - 30 jul. 2016

Emneord

Controlled release/delivery
Polylactic acid (PLA)
Biodegradable polymers
Rheology
Extrusion
3D printing Biofilm
Antimicrobial Implant

Adgang til dokumentet

10.1016/j.ejps.2016.03.013

Citationsformater

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abstract = "Abstract This work describes an approach to modify the release of active compound from a 3D printed model drug product geometry intended for flexible dosing and precision medication. The production of novel polylactic acid and hydroxypropyl methylcellulose based feed materials containing nitrofurantoin for 3D printing purposes is demonstrated. Nitrofurantoin, Metolose{\textregistered} and polylactic acid were successfully co-extruded with up to 40% Metolose{\textregistered} content, and subsequently 3D printed into model disk geometries ({\o}10 mm, h = 2 mm). Thermal analysis with differential scanning calorimetry and solid phase identification with Raman spectroscopy showed that nitrofurantoin remained in its original solid form during both hot-melt extrusion and subsequent 3D printing. Rheological measurements of the different compositions showed that the flow properties were sensitive to the amount of undissolved particles present in the formulation. Release of nitrofurantoin from the disks was dependent on Metolose{\textregistered} loading, with higher accumulated release observed for higher Metolose{\textregistered} loads. This work shows the potential of custom-made, drug loaded feed materials for 3D printing of precision drug products with tailored drug release characteristics.",

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AU - Boetker, Johan

AU - Water, Jorrit

AU - Aho, Johanna

AU - Arnfast, Lærke

AU - Bohr, Adam

AU - Rantanen, Jukka

PY - 2016/7/30

Y1 - 2016/7/30

N2 - Abstract This work describes an approach to modify the release of active compound from a 3D printed model drug product geometry intended for flexible dosing and precision medication. The production of novel polylactic acid and hydroxypropyl methylcellulose based feed materials containing nitrofurantoin for 3D printing purposes is demonstrated. Nitrofurantoin, Metolose® and polylactic acid were successfully co-extruded with up to 40% Metolose® content, and subsequently 3D printed into model disk geometries (ø10 mm, h = 2 mm). Thermal analysis with differential scanning calorimetry and solid phase identification with Raman spectroscopy showed that nitrofurantoin remained in its original solid form during both hot-melt extrusion and subsequent 3D printing. Rheological measurements of the different compositions showed that the flow properties were sensitive to the amount of undissolved particles present in the formulation. Release of nitrofurantoin from the disks was dependent on Metolose® loading, with higher accumulated release observed for higher Metolose® loads. This work shows the potential of custom-made, drug loaded feed materials for 3D printing of precision drug products with tailored drug release characteristics.

AB - Abstract This work describes an approach to modify the release of active compound from a 3D printed model drug product geometry intended for flexible dosing and precision medication. The production of novel polylactic acid and hydroxypropyl methylcellulose based feed materials containing nitrofurantoin for 3D printing purposes is demonstrated. Nitrofurantoin, Metolose® and polylactic acid were successfully co-extruded with up to 40% Metolose® content, and subsequently 3D printed into model disk geometries (ø10 mm, h = 2 mm). Thermal analysis with differential scanning calorimetry and solid phase identification with Raman spectroscopy showed that nitrofurantoin remained in its original solid form during both hot-melt extrusion and subsequent 3D printing. Rheological measurements of the different compositions showed that the flow properties were sensitive to the amount of undissolved particles present in the formulation. Release of nitrofurantoin from the disks was dependent on Metolose® loading, with higher accumulated release observed for higher Metolose® loads. This work shows the potential of custom-made, drug loaded feed materials for 3D printing of precision drug products with tailored drug release characteristics.

KW - Controlled release/delivery

KW - Polylactic acid (PLA)

KW - Biodegradable polymers

KW - Rheology

KW - Extrusion

KW - 3D printing Biofilm

KW - Antimicrobial Implant

U2 - 10.1016/j.ejps.2016.03.013

DO - 10.1016/j.ejps.2016.03.013

M3 - Tidsskriftartikel

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SN - 0928-0987

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SP - 47

EP - 52

JO - European Journal of Pharmaceutical Sciences

JF - European Journal of Pharmaceutical Sciences

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