Repositioning N-Acetylcysteine (NAC): NAC-Loaded Electrospun Drug Delivery Scaffolding for Potential Neural Tissue Engineering Application

Mahumane, Gillian Dumsile; Kumar, Pradeep; Pillay, Viness; Choonara, Yahya E.

doi:10.3390/pharmaceutics12100934

Cited by 18 publications

(13 citation statements)

References 61 publications

(75 reference statements)

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“…The fibers produced by 5% PCL solution are narrower than those produced by 10% PCL solution. It has been well reported that the nanofibers produced by electrospinning enlarge with the increase of polymer concentration used for synthesis [ 11 , 12 , 13 ].…”

Section: Resultsmentioning

confidence: 99%

“…If the thickness, hydrophobicity and molecular interaction of fibers and transporting molecules can be a tool to impact release, would the fiber diameter and pore size be another tool to manipulate the release? It has been well reported that the fiber diameter produced by electrospinning can be reduced by decreasing the polymer concentration used for synthesis process [ 11 , 12 , 13 ]. It was also reported in microfiltration that the flux of molecules can be altered by changing the microstructure of the nanofiber membranes such as the fiber diameter and porosity [ 14 ].…”

Section: Introductionmentioning

confidence: 99%

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Electrospun Membranes as a Porous Barrier for Molecular Transport: Membrane Characterization and Release Assessment

et al. 2021

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Electrospun nanofibers have been extensively studied for encapsulated drugs releasing from the inside of the fiber matrix, but have been barely looked at for their potential to control release as a semi-permeable membrane. This study investigated molecular transport behaviors across nanofiber membranes with different micro-structure sizes and compositions. Four types of membranes were made by 5% and 10% poly (ε-caprolactone) (PCL) solutions electro-spun with or without 50 nm calcium carbonate (CaCO3) nanoparticles. The membranes were tested for thickness, fiber diameter, pore size, porosity, tensile strength and elongation, contact angle of water and their impacts on molecular transport behaviors. The presence of the CaCO3 nanoparticles made the 5% membranes stronger and stiffer but the 10% membranes weaker and less stiff due to the different (covering or embedded) locations of the nanoparticles with the corresponding fibers. Solute transport studies using caffeine as the model drug found the 5% membranes further retarded release from the 10% membranes, regardless of only half the amount of material being used for synthesis. The addition of CaCO3 nanoparticles aided the water permeation process and accelerated initial transports. The difference in release profiles between 5% and 10% membranes suggests different release mechanisms, with membrane-permeability dominated release for 5% PCL membranes and solute-concentration-gradient dominated release for 10% PCL membranes.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Electrospun Membranes as a Porous Barrier for Molecular Transport: Membrane Characterization and Release Assessment

et al. 2021

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“…Surprisingly, the broadening peak of the PLGA polymer and disappearance of melting peaks instead of the intense sharp peak of the drug in the NAC-PLGA-MPPs further scrutinized that NAC was integrated into the polymer matrix; thus exists in the amorphous or partially crystalline state ( Fig. 3 D) ( Mahumane et al., 2020 ). This study also iterates the presence of the drug in a solubilized state in the lipid due to solid-state interaction induced by heating as mentioned in Fig.…”

Section: Resultsmentioning

confidence: 99%

Inhalation potential of N-Acetylcysteine loaded PLGA nanoparticles for the management of tuberculosis: In vitro lung deposition and efficacy studies

Puri

Chaudhary

Singh

et al. 2022

Current Research in Pharmacology and Drug Discovery

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Several studies have stated that mucus is a critical hurdle for drug delivery to the mucosal tissues. As a result, Polymeric nanoparticles that can overcome mucus barriers are gaining popularity for controlled drug delivery into intra-macrophages to attain high intracellular drug concentration. The present study was aimed to fabricate inhalable N-acetylcysteine (NAC) modified PLGA mucus penetrating particles using the double emulsion method (w/o/w) for target delivery to alveolar macrophages and minimize the dose-related adverse effects, efficiently encapsulate hydrophilic drug, sustain the release profile and prolong the retention time for the management of tuberculosis. Among the numerous formulations, the drug/polymer ratio of 1:10 with 0.50% PVA concentration and sonication time for 2 min s was chosen for further research. The formulated nanoparticles had a mean particle size of 307.50 ± 9.54 nm, PDI was 0.136 ± 0.02, zeta potential about −11.3 ± 0.4 mV, decent entrapment efficiency (55.46 ± 2.40%), drug loading (9.05 ± 0.22%), and excellent flowability. FTIR confirmed that NAC and PLGA were compatible with each other. SEM graphs elucidated that the nanoparticles were spherically shaped with a slightly rough surface whereas TEM analysis ensured the nanometer size nanoparticles and coating of lipid over NPs surface. PXRD spectrum concluded the transformation of the drug from crystalline to amorphous state in the formulation. In vitro release pattern was biphasic started with burst release (64.67 ± 1.53% within 12hrs) followed by sustained release over 48hrs thus enabling the prolonged replenishing of NAC. In vitro lung deposition study pronounced that coated NAC-PLGA-MPPs showed favorable results in terms of emitted dose (86.67 ± 2.52%), MMAD value (2.57 ± 0.12 μm), GSD value (1.55 ± 0.11 μm), and FPF of 62.67 ± 2.08% for the deposition and targeting the lungs. Finally, in vitro efficacy studies demonstrated that NAC-PLGA-MPPs presented more prominent antibacterial activity against MTB H37Rv strain as compared to NAC. Hence, PLGA based particles could be a better strategy to deliver the NAC for lung targeting.

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“…Drug-loaded electrospun neural conduits also hold great attention (Mahumane et al 2020;Haidar et al 2021;Farzamfar et al 2018). In this concept, a gabapentinloaded cellulose acetate/gelatin wet-electrospun scaffold was fabricated for neural tissue regeneration (Farzamfar et al 2018).…”

Section: Nerve Tissue Engineering Scaffoldsmentioning

confidence: 99%

“…Improved regeneration of the created injury was achieved with the drug-loaded scaffold when compared with the gabapentin-free scaffold. N-acetylcysteine-incorporated PLGA biomimetic neuro-scaffold for traumatic brain injury was also found to be neurocompatible through ex vivo cytotoxicity assays that were realized on rat pheochromocytoma (PC12) and human glioblastoma multiform (A172) cell lines with a positive influence on cell proliferation (Mahumane et al 2020). In another study, the combined multi-technologies were used to determine the neuroprotective effects of atorvastatin and alpha-lipoic acid as active pharmaceutical ingredients in a composite scaffold.…”

Section: Nerve Tissue Engineering Scaffoldsmentioning

confidence: 99%

Electrospun Porous Biobased Polymer Mats for Biomedical Applications

Parın

Terzioğlu

2021

Advanced Functional Porous Materials

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The electrospinning method provides fabrication of nonwoven mats from nano to micrometers in size with controllable pores. Porous electrospun scaffolds have attracted increasing attention in biomedical applications especially due to their ability to mimic the extracellular matrix. This chapter presents a comprehensive overview of the advancements in the last five years through the design and preparation of porous biobased polymer mats using the electrospinning method for biomedical applications. Firstly, fundamentals of the electrospinning process are presented and followed by a discussion of the possible biomedical applications of micro-and nanostructured porous mats for drug delivery, wound dressing, tissue engineering, and other applications. Various crucial points for limitations and possible future trends are presented.

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Repositioning N-Acetylcysteine (NAC): NAC-Loaded Electrospun Drug Delivery Scaffolding for Potential Neural Tissue Engineering Application

Cited by 18 publications

References 61 publications

Electrospun Membranes as a Porous Barrier for Molecular Transport: Membrane Characterization and Release Assessment

Electrospun Membranes as a Porous Barrier for Molecular Transport: Membrane Characterization and Release Assessment

Inhalation potential of N-Acetylcysteine loaded PLGA nanoparticles for the management of tuberculosis: In vitro lung deposition and efficacy studies

Electrospun Porous Biobased Polymer Mats for Biomedical Applications

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