Authors :
Dr. Jayanti Mukherjee; Pothulapalli Shruthi; Nagulapally Sanjana; Peddi Varshitha; T. Rama Rao
Volume/Issue :
Volume 9 - 2024, Issue 3 - March
Google Scholar :
https://tinyurl.com/57kr3b3d
Scribd :
https://tinyurl.com/wkyx5eua
DOI :
https://doi.org/10.38124/ijisrt/IJISRT24MAR1757
Note : A published paper may take 4-5 working days from the publication date to appear in PlumX Metrics, Semantic Scholar, and ResearchGate.
Abstract :
Technology involving 3-dimensional printing
has begun to revolutionize several fields, including
pharmacy. In pharmacy, it offers a reliable avenue for
precision medicine, dosage forms and drug delivery
systems. The creation of complex drug structures with
precise control over composition, shape and release
kinetics, catering to individual patient needs has been
possible with the intervention of this method. One
significant utilization in pharmacy is the customization
of dosage forms. Traditional manufacturing methods
often struggle to produce tailored medications for
patients with unique requirements, such as paediatric or
geriatric populations. With 3D printing, pharmacists can
create personalized medication with appropriate
dosages, structures, and release kinetics, improving
patient adherence and beneficial results. Moreover,
sophisticated medication delivery systems may be
created thanks to 3D printing. For instance, multi-
layered tablets can be designed to release multiple drugs
at different rates, optimizing treatment regimens for
conditions requiring combination therapies.
Furthermore, intricate structures like porous scaffolds or
micro needle arrays can facilitate targeted drug delivery,
enhancing bioavailability and minimizing side effects.
Additionally, 3D printing facilitates the rapid
prototyping of pharmaceutical formulations,
accelerating the drug development process. Researchers
can efficiently iterate through various designs,
optimizing formulations for efficacy, stability and
manufacturability. Despite its promise, challenges
remain in integrating 3D printing into mainstream
pharmacy practice, including regulatory hurdles,
material selection and scalability issues. However,
ongoing advancements in technology and collaborations
between academia, industry and regulatory agencies are
driving progress in overcoming these barriers. In
conclusion, 3D printing technology holds immense
potential to transform pharmacy by enabling
personalized medicine, new dosage formulations and
cutting-edge medication delivery technologies. As
research and development in this field continue, the
prospect of tailored pharmaceuticals tailored to
individual patient needs becomes increasingly attainable.
Keywords :
3D Printing, Precision Medicine, Release Kinetics, Porous Scaffolds.
Technology involving 3-dimensional printing
has begun to revolutionize several fields, including
pharmacy. In pharmacy, it offers a reliable avenue for
precision medicine, dosage forms and drug delivery
systems. The creation of complex drug structures with
precise control over composition, shape and release
kinetics, catering to individual patient needs has been
possible with the intervention of this method. One
significant utilization in pharmacy is the customization
of dosage forms. Traditional manufacturing methods
often struggle to produce tailored medications for
patients with unique requirements, such as paediatric or
geriatric populations. With 3D printing, pharmacists can
create personalized medication with appropriate
dosages, structures, and release kinetics, improving
patient adherence and beneficial results. Moreover,
sophisticated medication delivery systems may be
created thanks to 3D printing. For instance, multi-
layered tablets can be designed to release multiple drugs
at different rates, optimizing treatment regimens for
conditions requiring combination therapies.
Furthermore, intricate structures like porous scaffolds or
micro needle arrays can facilitate targeted drug delivery,
enhancing bioavailability and minimizing side effects.
Additionally, 3D printing facilitates the rapid
prototyping of pharmaceutical formulations,
accelerating the drug development process. Researchers
can efficiently iterate through various designs,
optimizing formulations for efficacy, stability and
manufacturability. Despite its promise, challenges
remain in integrating 3D printing into mainstream
pharmacy practice, including regulatory hurdles,
material selection and scalability issues. However,
ongoing advancements in technology and collaborations
between academia, industry and regulatory agencies are
driving progress in overcoming these barriers. In
conclusion, 3D printing technology holds immense
potential to transform pharmacy by enabling
personalized medicine, new dosage formulations and
cutting-edge medication delivery technologies. As
research and development in this field continue, the
prospect of tailored pharmaceuticals tailored to
individual patient needs becomes increasingly attainable.
Keywords :
3D Printing, Precision Medicine, Release Kinetics, Porous Scaffolds.
