Optimization and scale up of microfluidic nanolipomer production method for preclinical and potential clinical trials

Gdowski, Andrew; Johnson, Kaitlyn; Shah, Sunil; Gryczyński, Ignacy; Vishwanatha, Jamboor K.; Ranjan, Amalendu

doi:10.1186/s12951-018-0339-0

Cited by 56 publications

(37 citation statements)

References 19 publications

(24 reference statements)

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“…Microuidics enable the precise manipulation of liquids that allow the control of process parameters, such as the total ow rate, ow rate ratios between different phases, particle geometry, drug loading, etc. [27][28][29] Nevertheless, despite the advantages of microuidics, few studies have exploited this technology to generate silk particles. Some approaches have included glass capillary-based microuidics (resulting in particles 145-200 mm in size), 30 double junction microuidics (10-200 mm particles) 31 and single and double Tjunction droplet microuidics (colloids 5-80 mm).…”

Section: Introductionmentioning

confidence: 99%

Microfluidic-assisted silk nanoparticle tuning

et al. 2019

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Silk is now making inroads into advanced pharmaceutical and biomedical applications. Both bottom-up and top-down approaches can be applied to silk and the resulting aqueous silk solution can be processed into a range of material formats, including nanoparticles. Here, we demonstrate the potential of microfluidics for the continuous production of silk nanoparticles with tuned particle characteristics. Our microfluidic-based design ensured efficient mixing of different solvent phases at the nanoliter scale, in addition to controlling the solvent ratio and flow rates. The total flow rate and aqueous : solvent ratios were important parameters affecting yield (1 mL min À1 > 12 mL min À1 ). The ratios also affected size and stability; a solvent : aqueous total flow ratio of 5 : 1 efficiently generated spherical nanoparticles 110 and 215 nm in size that were stable in water and had a high beta-sheet content. These 110 and 215 nm silk nanoparticles were not cytotoxic (IC50 > 100 mg mL À1 ) but showed size-dependent cellular trafficking. Overall, microfluidicassisted silk nanoparticle manufacture is a promising platform that allows control of the silk nanoparticle properties by manipulation of the processing variables.

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Section: Introductionmentioning

confidence: 99%

Microfluidic-assisted silk nanoparticle tuning

et al. 2019

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“…By utilizing microfluidics to more precisely guide nanoprecipitation, we controlled or removed many of the variables involved in manual nanoprecipitation, providing reliable and repeatable nanoassembly. Importantly, the microfluidic device employed here is scalable, enabling eventual clinical translation of squalenoylated NPs 45 .…”

Section: Discussionmentioning

confidence: 99%

A Scalable Method for Squalenoylation and Assembly of Multifunctional ⁶⁴Cu-Labeled Squalenoylated Gemcitabine Nanoparticles

Tucci¹,

Seo²,

Kakwere³

et al. 2018

Nanotheranostics

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Squalenoylation of gemcitabine, a front-line therapy for pancreatic cancer, allows for improved cellular-level and system-wide drug delivery. The established methods to conjugate squalene to gemcitabine and to form nanoparticles (NPs) with the squalenoylated gemcitabine (SqGem) conjugate are cumbersome, time-consuming and can be difficult to reliably replicate. Further, the creation of multi-functional SqGem-based NP theranostics would facilitate characterization of in vivo pharmacokinetics and efficacy.Methods: Squalenoylation conjugation chemistry was enhanced to improve reliability and scalability using tert-butyldimethylsilyl (TBDMS) protecting groups. We then optimized a scalable microfluidic mixing platform to produce SqGem-based NPs and evaluated the stability and morphology of select NP formulations using dynamic light scattering (DLS) and transmission electron microscopy (TEM). Cytotoxicity was evaluated in both PANC-1 and KPC (KrasLSL-G12D/+; Trp53LSL-R172H/+; Pdx-Cre) pancreatic cancer cell lines. A 64Cu chelator (2-S-(4-aminobenzyl)-1,4,7-triazacyclononane-1,4,7-triacetic acid, NOTA) was squalenoylated and used with positron emission tomography (PET) imaging to monitor the in vivo fate of SqGem-based NPs.Results: Squalenoylation yields of gemcitabine increased from 15% to 63%. Cholesterol-PEG-2k inclusion was required to form SqGem-based NPs using our technique, and additional cholesterol inclusion increased particle stability at room temperature; after 1 week the PDI of SqGem NPs with cholesterol was ~ 0.2 while the PDI of SqGem NPs lacking cholesterol was ~ 0.5. Similar or superior cytotoxicity was achieved for SqGem-based NPs compared to gemcitabine or Abraxane® when evaluated at a concentration of 10 µM. Squalenoylation of NOTA enabled in vivo monitoring of SqGem-based NP pharmacokinetics and biodistribution.Conclusion: We present a scalable technique for fabricating efficacious squalenoylated-gemcitabine nanoparticles and confirm their pharmacokinetic profile using a novel multifunctional 64Cu-SqNOTA-SqGem NP.

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“…For example, adjusting the flow rate ratio and different lipid components can precisely controlled the NPs size and surface properties [123]. Microfluidic devices are now capable of preparing a variety of NPs, including lipid-based nanobiomaterials [124][125][126], polymeric nanoparticles [127][128][129], lipid-polymer hybrid nanoparticles [130,131] and engineered exosomes [132,133].…”

Section: The Preparation Of Nano-drugsmentioning

confidence: 99%

Multifunctional microfluidic chip for cancer diagnosis and treatment

Guo¹,

Zhang²,

Liu³

et al. 2021

Nanotheranostics

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Microfluidic chip is not a chip in the traditional sense. It is technologies that control fluids at the micro level. As a burgeoning biochip, microfluidic chips integrate multiple disciplines, including physiology, pathology, cell biology, biophysics, engineering mechanics, mechanical design, materials science, and so on. The application of microfluidic chip has shown tremendous promise in the field of cancer therapy in the past three decades. Various types of cell and tissue cultures, including 2D cell culture, 3D cell culture and tissue organoid culture could be performed on microfluidic chips. Patient-derived cancer cells and tissues can be cultured on microfluidic chips in a visible, controllable, and high-throughput manner, which greatly advances the process of personalized medicine. Moreover, the functionality of microfluidic chip is greatly expanding due to the customizable nature. In this review, we introduce its application in developing cancer preclinical models, detecting cancer biomarkers, screening anti-cancer drugs, exploring tumor heterogeneity and producing nano-drugs. We highlight the functions and recent development of microfluidic chip to provide references for advancing cancer diagnosis and treatment.

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Optimization and scale up of microfluidic nanolipomer production method for preclinical and potential clinical trials

Cited by 56 publications

References 19 publications

Microfluidic-assisted silk nanoparticle tuning

Microfluidic-assisted silk nanoparticle tuning

A Scalable Method for Squalenoylation and Assembly of Multifunctional ⁶⁴Cu-Labeled Squalenoylated Gemcitabine Nanoparticles

Multifunctional microfluidic chip for cancer diagnosis and treatment

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Optimization and scale up of microfluidic nanolipomer production method for preclinical and potential clinical trials

Cited by 56 publications

References 19 publications

Microfluidic-assisted silk nanoparticle tuning

Microfluidic-assisted silk nanoparticle tuning

A Scalable Method for Squalenoylation and Assembly of Multifunctional 64Cu-Labeled Squalenoylated Gemcitabine Nanoparticles

Multifunctional microfluidic chip for cancer diagnosis and treatment

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A Scalable Method for Squalenoylation and Assembly of Multifunctional ⁶⁴Cu-Labeled Squalenoylated Gemcitabine Nanoparticles