Solution-enhanced dispersion by supercritical fluids: an ecofriendly nanonization approach for processing biomaterials and pharmaceutical compounds

Kankala, Ranjith Kumar; Chen, Biao‐Qi; Liu, Chenguang; Tang, Hanxiao; Wang, Shibin; Chen, Ai-Zheng

doi:10.2147/ijn.s166124

Cited by 57 publications

(20 citation statements)

References 134 publications

(296 reference statements)

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“…In this modern era, nanotechnology has garnered significant interest from researchers in various fields for the generation of materials with diverse compositions and morphological attributes. [11][12][13][14] In the past two decades, these interesting features have significantly influenced the researchers to explore enormous varieties of innovative nanobiomaterials with engineering characteristics and ideal functions through involving supramolecular, nanocrystal growth, and sol-gel chemistries. 15,16 The application of nanotechnology to medicine has sparked enormous interest in cancer treatment and diagnosis due to its given special attributes in generating materials with typically controlled multi-dimensional (1-3 D) structures on the nanoscale range (approximately 1-100 nm in one of the measurable dimensions) for drug/gene delivery, diagnostic probes for radioactive or other advanced therapeutic strategies.…”

Section: Introductionmentioning

confidence: 99%

<p>Subcellular Performance of Nanoparticles in Cancer Therapy</p>

Liu

Han

Kankala

et al. 2020

IJN

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113

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With the advent of nanotechnology, various modes of traditional treatment strategies have been transformed extensively owing to the advantageous morphological, physiochemical, and functional attributes of nano-sized materials, which are of particular interest in diverse biomedical applications, such as diagnostics, sensing, imaging, and drug delivery. Despite their success in delivering therapeutic agents, several traditional nanocarriers often end up with deprived selectivity and undesired therapeutic outcome, which significantly limit their clinical applicability. Further advancements in terms of improved selectivity to exhibit desired therapeutic outcome toward ablating cancer cells have been predominantly made focusing on the precise entry of nanoparticles into tumor cells via targeting ligands, and subsequent delivery of therapeutic cargo in response to specific biological or external stimuli. However, there is enough room intracellularly, where diverse small-sized nanomaterials can accumulate and significantly exert potentially specific mechanisms of antitumor effects toward activation of precise cancer cell death pathways that can be explored. In this review, we aim to summarize the intracellular pathways of nanoparticles, highlighting the principles and state of their destructive effects in the subcellular structures as well as the current limitations of conventional therapeutic approaches. Next, we give an overview of subcellular performances and the fate of internalized nanoparticles under various organelle circumstances, particularly endosome or lysosome, mitochondria, nucleus, endoplasmic reticulum, and Golgi apparatus, by comprehensively emphasizing the unique mechanisms with a series of interesting reports. Moreover, intracellular transformation of the internalized nanoparticles, prominent outcome and potential affluence of these interdependent subcellular components in cancer therapy are emphasized. Finally, we conclude with perspectives with a focus on the contemporary challenges in their clinical applicability.

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Section: Introductionmentioning

confidence: 99%

<p>Subcellular Performance of Nanoparticles in Cancer Therapy</p>

Liu

Han

Kankala

et al. 2020

IJN

Self Cite

113

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“…The most frequently reported example is lipase, where hydrophobic solvents can increase its productivity [80]. Generally, there are two types of non-aqueous solvents: ionic liquids (ILs) [81] and supercritical fluids (SCFs) [82,83] (Figure 2).…”

Section: Non-aqueous Solventsmentioning

confidence: 99%

Recent Developments in Carriers and Non-Aqueous Solvents for Enzyme Immobilization

2019

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Immobilization techniques are generally based on reusing enzymes in industrial applications to reduce costs and improve enzyme properties. These techniques have been developing for decades, and many methods for immobilizing enzymes have been designed. To find a better immobilization method, it is necessary to review the recently developed methods and have a clear overview of the advantages and limitations of each method. This review introduces the recently reported immobilization methods and discusses the improvements in enzyme properties by different methods. Among the techniques to improve enzyme properties, metal–organic frameworks, which have diverse structures, abundant organic ligands and metal nodes, offer a promising platform.

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“…Traditional mechanical destruction methods have several disadvantages, including a wide particle size distribution, formulation instabililty, may damage sensitive biomolecules due to excessive shear of forces (in pharmaceutical), and also requires large energy in refining [5]. The method of precipitation using organic solution also has disadvantages, including environmental pollution problems related to the use of organic solvents.…”

Section: Introductionmentioning

confidence: 99%

“…The use of large quantity of solvents have several issues, e.g. toxicity, inflammability, purity of product, and environmental issue [5]. The spray drying method is carried out by spraying solutions containing dissolved material into the hot gas stream to remove the solvent.…”

Section: Introductionmentioning

confidence: 99%

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Formation of fine particles using supercritical fluid (SCF) process: Short review

Chafidz

Jauhary

Kaavessina

et al. 2018

CST

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This paper will discuss about the utilization of supercritical fluid (SCF) process to produce fine particles. Supercritical fluids (SCFs) process can be considered as an emerging "clean" technology for the production of small-size or fine particles (e.g. micron-size). Microsphere is a material in micron scale which has been widely used as adsorbent, catalyst support, and drug delivery system. For advanced application, those materials are formulated in the form of porous microspheres. There are several methods that can be used using SCFs. Those method are, Rapid Expansion of Supercritical Solution (RESS), Gas Anti-Solvent/Supercritical Anti-Solvent (GAS/ SAS), Aerosol Solvent Extraction System (ASES), dan Solution Enhanced Dispersion by Supercritical Fluids (SEDS) and Particle from Gas-Saturated Solutions/Suspensions (PGSS). Considering the morphology of material which will be used to prepare microsphere, each of methods above has specific advantages and disadvantages toward the material. Based on the literatures, the ASES method is more likely to produce porous microparticles (microspheres). In the ASES method, porous microsphere formation is the result of interactions between: degrees of supersaturation, nucleation velocity and crystal growth.

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Solution-enhanced dispersion by supercritical fluids: an ecofriendly nanonization approach for processing biomaterials and pharmaceutical compounds

Cited by 57 publications

References 134 publications

<p>Subcellular Performance of Nanoparticles in Cancer Therapy</p>

<p>Subcellular Performance of Nanoparticles in Cancer Therapy</p>

Recent Developments in Carriers and Non-Aqueous Solvents for Enzyme Immobilization

Formation of fine particles using supercritical fluid (SCF) process: Short review

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