Printing of small molecular medicines from the vapor phase

Shalev, Olga; Raghavan, Shreya; Mazzara, J. Maxwell; Senabulya, Nancy; Sinko, Patrick D.; Fleck, Elyse M. A.; Rockwell, Christopher; Simopoulos, Nicholas; Jones, Christina M.; Mehta, Geeta; Clarke, Roy; Amidon, Gregory E.; Shtein, Max

doi:10.1038/s41467-017-00763-6

Cited by 12 publications

(11 citation statements)

References 53 publications

(57 reference statements)

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“…However, scaling this technique is challenging because of slow deposition rates. Most recently, organic vapor jet printing was employed as a technique to deposit thin films of APIs, wherein a jet of inert carrier gas thrusts APIs in the vapor phase onto cooled substrates . However, precise control of the deposit thickness and uniformity at the nanometer scale is less straightforward by varying simple processing parameters.…”

Section: Introductionmentioning

confidence: 99%

Solution Coating of Pharmaceutical Nanothin Films and Multilayer Nanocomposites with Controlled Morphology and Polymorphism

Horstman

Kafle

Zhang

et al. 2018

ACS Appl. Mater. Interfaces

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Nanosizing is rapidly emerging as an alternative approach to enhance solubility and thus the bioavailability of poorly aqueous soluble active pharmaceutical ingredients (APIs). Although numerous techniques have been developed to perform nanosizing of API crystals, precise control and modulation of their size in an energy and material efficient manner remains challenging. In this study, we present meniscus-guided solution coating as a new technique to produce pharmaceutical thin films of nanoscale thickness with controlled morphology. We demonstrate control of aspirin film thickness over more than 2 orders of magnitude, from 30 nm to 1.5 μm. By varying simple process parameters such as the coating speed and the solution concentration, the aspirin film morphology can also be modulated by accessing different coating regimes, namely the evaporation regime and the Landau-Levich regime. Using ellipticine-a poorly water-soluble anticancer drug-as another model compound, we discovered a new polymorph kinetically trapped during solution coating. Furthermore, the polymorphic outcome can be controlled by varying coating conditions. We further performed layer-by-layer coating of multilayer nanocomposites, with alternating thin films of ellipticine and a biocompatible polymer, which demonstrate the potential of additive manufacturing of multidrug-personalized dosage forms using this approach.

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Section: Introductionmentioning

confidence: 99%

Solution Coating of Pharmaceutical Nanothin Films and Multilayer Nanocomposites with Controlled Morphology and Polymorphism

Horstman

Kafle

Zhang

et al. 2018

ACS Appl. Mater. Interfaces

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“…The growth of glassy molecular solids by condensation of gas is the main growth mechanism for molecular solids in the interstellar medium, 8 is frequently used for the production of molecular electronic components 9 and, increasingly, for drug delivery solutions. 10 It has recently been discovered that molecular ordering can occur in films formed through physical vapour deposition. [11][12][13][14] The phenomenon appears to be a general consequence of the growth of thin films of molecular materials from the vapour phase.…”

mentioning

confidence: 99%

A mechanism for ageing in a deeply supercooled molecular glass

et al. 2021

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“…Some of the examples of oral tablets are flat-faced [40], spritam (levetiracetam) [41], and paracetamol [42]. Presently, analysts use vapour-stream as a 3D printing method to keep drug measurements on an assortment of surfaces that incorporate dissolvable Listerine tabs [43]. In the meantime, 3D printing technology can also produce antibiotic and chemotherapeutic drugs that are customized according to patient anatomy and clinical presentation [44].…”

Section: Drug Deliverymentioning

confidence: 99%

Challenges of 3D printing technology for manufacturing biomedical products: A case study of Malaysian manufacturing firms

Shahrubudin

Koshy

Alipal

et al. 2020

Heliyon

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Additive manufacturing has attracted increasing attention worldwide, especially in the healthcare, biomedical, aerospace, and construction industries. In Malaysia, insufficient acceptance of this technology by local industries has resulted in a call for government and local practitioners to promulgate the development of this technology for various industries, particularly for biomedical products. The current study intends to frame the challenges endured by biomedical industries who use 3D printing technology for their manufacturing processes. Qualitative methods, particularly in-depth interviews, were used to identify the challenges faced by manufacturing firms when producing 3D printed biomedical products. This work was able to identify twelve key challenges when deploying additive manufacturing in biomedical products and these include issues related to binder selection, poor mechanical properties, low-dimensional accuracy, high levels of powder agglomeration, nozzle size, distribution size, limited choice of materials, texture and colour, lifespan of materials, customization of fit and design, layer height, and, lastly, build-failure. Furthermore, there also are six challenges in the management of manufacturing biomedical products using 3D printing technology, and these include staff re-education, product pricing, limited guidelines, cyber-security issues, marketing, and patents and copyright. This study discusses the reality faced by 3D printing players when producing biomedical products in Malaysia, and presents a primary reference for practitioners in other developing countries.

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Printing of small molecular medicines from the vapor phase

Cited by 12 publications

References 53 publications

Solution Coating of Pharmaceutical Nanothin Films and Multilayer Nanocomposites with Controlled Morphology and Polymorphism

Solution Coating of Pharmaceutical Nanothin Films and Multilayer Nanocomposites with Controlled Morphology and Polymorphism

A mechanism for ageing in a deeply supercooled molecular glass

Challenges of 3D printing technology for manufacturing biomedical products: A case study of Malaysian manufacturing firms

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