HomePublications

Investigation of the mechanical properties of hot-melt extruded filaments for pharmaceutical applications of FDM

Research output: Contribution to conferenceAbstract

Standard

Investigation of the mechanical properties of hot-melt extruded filaments for pharmaceutical applications of FDM. / Nasereddin, Jehad; Belton, Peter; Qi, Sheng.

2018. Abstract from 2nd International Conference on 3D Printing Technology and Innovations
, London, United Kingdom.

Research output: Contribution to conferenceAbstract

Harvard

Nasereddin, J, Belton, P & Qi, S 2018, 'Investigation of the mechanical properties of hot-melt extruded filaments for pharmaceutical applications of FDM' 2nd International Conference on 3D Printing Technology and Innovations
, London, United Kingdom, 19/03/18 - 20/03/18, . https://doi.org/10.4172/0976-4860-C1-002

APA

Vancouver

Nasereddin J, Belton P, Qi S. Investigation of the mechanical properties of hot-melt extruded filaments for pharmaceutical applications of FDM. 2018. Abstract from 2nd International Conference on 3D Printing Technology and Innovations
, London, United Kingdom. https://doi.org/10.4172/0976-4860-C1-002

Author

Nasereddin, Jehad ; Belton, Peter ; Qi, Sheng. / Investigation of the mechanical properties of hot-melt extruded filaments for pharmaceutical applications of FDM. Abstract from 2nd International Conference on 3D Printing Technology and Innovations
, London, United Kingdom.

Bibtex- Download

@conference{ee87fd3770d5429e86a24bb94b905cf1,
title = "Investigation of the mechanical properties of hot-melt extruded filaments for pharmaceutical applications of FDM",
abstract = "The advent of additive manufacturing techniques, namely Fused Deposition Modeling (FDM), holds many promising prospects for medical applications, from tailored polypills for personalized medicine to patient-specific implants. However, the lack of pharmaceutically-acceptable materials that possess suitable properties for FDM is the main issue standing in the way of turning FDM into a commercially viable process. And although a number of research efforts has demonstrated the feasibility of using blends of pharmaceutically relevant polymers to print pharmaceutical dosage forms, there remains littleto-no investigation into the critical parameters that govern the feasibility of an FDM process. Mechanical properties of the filament used in FDM is one such critical parameter; part of the filament feeding process involves rotating gears pushing the filament into a pinhole slit that leads on to the heating element of the printer. Trial and error attempts at feeding various inhouse prepared filaments to the printer revealed that filaments need to possess specific mechanical properties; filaments which are too brittle will fracture inside the print head causing a blockage, filaments which are too deformable will coil around the conveyer gears without threading into the melting zone. This presentation outlines an in-house developed method to identify the desired mechanical properties for FDM filament: A TA.XT 2 Texture Analyzer fitted with an in-house prepared rig loosely based on the spaghetti flexure rig was used to quantify forces required to deform a number of commercial and in-house filaments. Principal Component Analysis (PCA) was used to sort the data collected from the texture analysis and categorize the various filaments into feedable and non-feedable. The method was then employed to evaluate the feedability of an ibuprofen formulation to verify its suitability as a method to test the mechanical properties of filaments.",
author = "Jehad Nasereddin and Peter Belton and Sheng Qi",
year = "2018",
month = "3",
day = "20",
doi = "10.4172/0976-4860-C1-002",
language = "English",
note = "2nd International Conference on 3D Printing Technology and Innovations<br/> ; Conference date: 19-03-2018 Through 20-03-2018",
url = "https://3dprinting.conferenceseries.com/",

}

RIS (suitable for import to EndNote) - Download

TY - CONF

T1 - Investigation of the mechanical properties of hot-melt extruded filaments for pharmaceutical applications of FDM

AU - Nasereddin, Jehad

AU - Belton, Peter

AU - Qi, Sheng

PY - 2018/3/20

Y1 - 2018/3/20

N2 - The advent of additive manufacturing techniques, namely Fused Deposition Modeling (FDM), holds many promising prospects for medical applications, from tailored polypills for personalized medicine to patient-specific implants. However, the lack of pharmaceutically-acceptable materials that possess suitable properties for FDM is the main issue standing in the way of turning FDM into a commercially viable process. And although a number of research efforts has demonstrated the feasibility of using blends of pharmaceutically relevant polymers to print pharmaceutical dosage forms, there remains littleto-no investigation into the critical parameters that govern the feasibility of an FDM process. Mechanical properties of the filament used in FDM is one such critical parameter; part of the filament feeding process involves rotating gears pushing the filament into a pinhole slit that leads on to the heating element of the printer. Trial and error attempts at feeding various inhouse prepared filaments to the printer revealed that filaments need to possess specific mechanical properties; filaments which are too brittle will fracture inside the print head causing a blockage, filaments which are too deformable will coil around the conveyer gears without threading into the melting zone. This presentation outlines an in-house developed method to identify the desired mechanical properties for FDM filament: A TA.XT 2 Texture Analyzer fitted with an in-house prepared rig loosely based on the spaghetti flexure rig was used to quantify forces required to deform a number of commercial and in-house filaments. Principal Component Analysis (PCA) was used to sort the data collected from the texture analysis and categorize the various filaments into feedable and non-feedable. The method was then employed to evaluate the feedability of an ibuprofen formulation to verify its suitability as a method to test the mechanical properties of filaments.

AB - The advent of additive manufacturing techniques, namely Fused Deposition Modeling (FDM), holds many promising prospects for medical applications, from tailored polypills for personalized medicine to patient-specific implants. However, the lack of pharmaceutically-acceptable materials that possess suitable properties for FDM is the main issue standing in the way of turning FDM into a commercially viable process. And although a number of research efforts has demonstrated the feasibility of using blends of pharmaceutically relevant polymers to print pharmaceutical dosage forms, there remains littleto-no investigation into the critical parameters that govern the feasibility of an FDM process. Mechanical properties of the filament used in FDM is one such critical parameter; part of the filament feeding process involves rotating gears pushing the filament into a pinhole slit that leads on to the heating element of the printer. Trial and error attempts at feeding various inhouse prepared filaments to the printer revealed that filaments need to possess specific mechanical properties; filaments which are too brittle will fracture inside the print head causing a blockage, filaments which are too deformable will coil around the conveyer gears without threading into the melting zone. This presentation outlines an in-house developed method to identify the desired mechanical properties for FDM filament: A TA.XT 2 Texture Analyzer fitted with an in-house prepared rig loosely based on the spaghetti flexure rig was used to quantify forces required to deform a number of commercial and in-house filaments. Principal Component Analysis (PCA) was used to sort the data collected from the texture analysis and categorize the various filaments into feedable and non-feedable. The method was then employed to evaluate the feedability of an ibuprofen formulation to verify its suitability as a method to test the mechanical properties of filaments.

U2 - 10.4172/0976-4860-C1-002

DO - 10.4172/0976-4860-C1-002

M3 - Abstract

ER -

ID: 137017532