Controlling Structure and Function of Polymeric Drug Delivery Nanoparticles Using Microfluidics

Bains, Aman; Cao, Yimeng; Kly, Sundiata; Wulff, Jeremy E.; Moffitt, Matthew G.

doi:10.1021/acs.molpharmaceut.7b00177

Cited by 34 publications

(88 citation statements)

References 69 publications

(195 reference statements)

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“…This result showed that the on‐chip flow rate hold the potential for tuning timed release of specific drugs for desired treatments. In a more recent work of Moffitt's group, the effects of PCL block lengths and flow rate on sizes, morphologies, and PTX‐loading efficiencies of PCL‐ b ‐PEO micelles were studied systematically.…”

Section: Microfluidics For Fabrication Of Sddss With Well‐controlled mentioning

confidence: 99%

Microfluidics for Cancer Nanomedicine: From Fabrication to Evaluation

Zhang

Zhu

Shen

2018

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Self-assembled drug delivery systems (sDDSs), made from nanocarriers and drugs, are one of the major types of nanomedicines, many of which are in clinical use, under preclinical investigation, or in clinical trials. One of the hurdles of this type of nanomedicine in real applications is the inherent complexity of their fabrication processes, which generally lack precise control over the sDDS structures and the batch-to-batch reproducibility. Furthermore, the classic 2D in vitro cell model, monolayer cell culture, has been used to evaluate sDDSs. However, 2D cell culture cannot adequately replicate in vivo tissue-level structures and their highly complex dynamic 3D environments, nor can it simulate their functions. Thus, evaluations using 2D cell culture often cannot correctly correlate with sDDS behaviors and effects in humans. Microfluidic technology offers novel solutions to overcome these problems and facilitates studying the structure-performance relationships for sDDS developments. In this Review, recent advances in microfluidics for 1) fabrication of sDDSs with well-defined physicochemical properties, such as size, shape, rigidity, and drug-loading efficiency, and 2) fabrication of 3D-cell cultures as "tissue/organ-on-a-chip" platforms for evaluations of sDDS biological performance are in focus.

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Section: Microfluidics For Fabrication Of Sddss With Well‐controlled mentioning

confidence: 99%

Microfluidics for Cancer Nanomedicine: From Fabrication to Evaluation

Zhang

Zhu

Shen

2018

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“…14 Although the hydrolytic degradation of PCL makes it an appropriate in vivo host for a wide variety therapeutic molecules, its semicrystalline nature can strongly influence drug delivery properties. 15,16 For example, an increase in the crystallinity of the core-forming PCL blocks has been shown to increase drug release times in some studies. [15][16][17][18] However, crystallites can also exclude drug molecules leading to lower encapsulation efficiencies.…”

Section: Introductionmentioning

confidence: 99%

“…15,16 For example, an increase in the crystallinity of the core-forming PCL blocks has been shown to increase drug release times in some studies. [15][16][17][18] However, crystallites can also exclude drug molecules leading to lower encapsulation efficiencies. 15,16,18 In addition, SN-38 generally shows low solubility in aliphatic polyesters including PCL and PLGA.…”

Section: Introductionmentioning

confidence: 99%

“…[15][16][17][18] However, crystallites can also exclude drug molecules leading to lower encapsulation efficiencies. 15,16,18 In addition, SN-38 generally shows low solubility in aliphatic polyesters including PCL and PLGA. 11 Together these features highlight a need for studies involving systematic variation in block copolymer hydrophobic block composition and crystallinity, in order to gain insights en route to improved materials for SN-38 delivery systems.…”

Section: Introductionmentioning

confidence: 99%

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Microfluidic encapsulation of SN-38 in block copolymer nanoparticles: effect of hydrophobic block composition on loading and release properties

et al. 2019

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A gas–liquid microfluidic reactor was used to prepare polymer nanoparticles (PNPs) containing the drug 7-ethyl-10-hydroxy camptothecin (SN-38) from a series of poly(methyl caprolactone-co-caprolactone)-b-poly(ethylene oxide) (P(MCL-co-CL)-b-PEO) amphiphilic block copolymers with variable MCL content in the hydrophobic block. All three copolymers formed spheres with ∼20 nm core diameters by TEM, although some rigid rod-like aggregates were also formed by the PMCL-50 and PMCL-75 copolymers. SN-38 encapsulation efficiencies (EE = 2.7%–3.0%) and loading levels (DL = 2.0%–2.9%) were similar for the three copolymers. In vitro release kinetics became significantly slower as the MCL content increased, with release half times increasing monotonically from 3.4 to 6.2 h as the MCL content of the hydrophobic block increased from 50% to 100%. The ability to systematically tune release half times via controlled variation in the hydrophobic block composition, while maintaining constant PNP size and loading levels, represents an intriguing chemical handle for the optimization of SN-38 nanomedicines.

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“…Drug‐loaded hydrogels can be directly injected in a minimally invasive way, thanks to their high moldability, and the ability to form tissue constructs in‐situ . Particularly interesting is the use of external stimuli to trigger the release of the drug at a specific site or specific time …”

Section: Introductionmentioning

confidence: 99%

Strategies for Drug Encapsulation and Controlled Delivery Based on Vapor‐Phase Deposited Thin Films

2017

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Vapor-phase deposition methods allow the synthesis and engineering of organic and inorganic thin films, with high control on the chemical composition, physical properties, and conformality. In this review, the recent applications of vapor-phase deposition methods such as initiated chemical vapor deposition (iCVD), plasma enhanced chemical vapor deposition (PE-CVD), and atomic layer deposition (ALD), for the encapsulation of active pharmaceutical drugs are reported. The strategies and emergent routes for the application of vapor-deposited thin films on the drug controlled release and for the engineering of advanced release nanostructured devices are presented.

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Controlling Structure and Function of Polymeric Drug Delivery Nanoparticles Using Microfluidics

Cited by 34 publications

References 69 publications

Microfluidics for Cancer Nanomedicine: From Fabrication to Evaluation

Microfluidics for Cancer Nanomedicine: From Fabrication to Evaluation

Microfluidic encapsulation of SN-38 in block copolymer nanoparticles: effect of hydrophobic block composition on loading and release properties

Strategies for Drug Encapsulation and Controlled Delivery Based on Vapor‐Phase Deposited Thin Films

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