96 research outputs found
Design and Characterization of Endostatin-Loaded Nanoparticles for In Vitro Antiangiogenesis in Squamous Cell Carcinoma
The aim of this study is to effectively enhance antitumor activities of endostatin by preparing polymeric nanocarriers. NMR and FT-IR spectra confirmed the successful grafting of the CHT-g-PEI and CHT-g-PEI-PEG-NH2 conjugates. SEM micrographs confirmed the shape of endostatin-loaded nanoparticles to be spherical while both TEM and zeta size results showed nanoparticle’s average size to be 100.6 nm having a positively charged surface with zeta potential of 7.95 mV. The concentrations of CHT and TPP as well as the changing pH conditions account for the increased swelling pattern of endostatin-loaded nanoparticles and influenced endostatin release in vitro. PEI increased the overall amine protonation while PEG aggravated endostatin encapsulation and release. Nanoparticles swell and release endostatin at acidic tumor pH of 6.8 compared to physiological pH of 7.4. The native CHT-g-PEI-PEG-NH2 conjugate showed high cytocompatibility above 80% cell viability across tested formulations. Endostatin-loaded nanoparticles showed a significant reduction in cell viability across tested formulations, with 5.32% cell death at 125 μg/mL and 13.36% at 250 μg/mL following 24 hours’ incubation period. Interestingly, more than a fourfold (61.68%) increment in cytotoxicity was observed at nanoparticle concentration of 1000 μg/mL. It was concluded that CHT-g-PEI-PEG-NH2 is an effective cargo for endostatin delivery with antiangiogenic effect in squamous cell carcinoma
Trends in the Molecular Pathogenesis and Clinical Therapeutics of Common Neurodegenerative Disorders
The term neurodegenerative disorders, encompasses a variety of underlying conditions, sporadic and/or familial and are characterized by the persistent loss of neuronal subtypes. These disorders can disrupt molecular pathways, synapses, neuronal subpopulations and local circuits in specific brain regions, as well as higher-order neural networks. Abnormal network activities may result in a vicious cycle, further impairing the integrity and functions of neurons and synapses, for example, through aberrant excitation or inhibition. The most common neurodegenerative disorders are Alzheimer’s disease, Parkinson’s disease, Amyotrophic Lateral Sclerosis and Huntington’s disease. The molecular features of these disorders have been extensively researched and various unique neurotherapeutic interventions have been developed. However, there is an enormous coercion to integrate the existing knowledge in order to intensify the reliability with which neurodegenerative disorders can be diagnosed and treated. The objective of this review article is therefore to assimilate these disorders’ in terms of their neuropathology, neurogenetics, etiology, trends in pharmacological treatment, clinical management, and the use of innovative neurotherapeutic interventions
A Review on Composite Liposomal Technologies for Specialized Drug Delivery
The combination of liposomes with polymeric scaffolds could revolutionize the current state of drug delivery technology. Although liposomes have been extensively studied as a promising drug delivery model for bioactive compounds, there still remain major drawbacks for widespread pharmaceutical application. Two approaches for overcoming the factors related to the suboptimal efficacy of liposomes in drug delivery have been suggested. The first entails modifying the liposome surface with functional moieties, while the second involves integration of pre-encapsulated drug-loaded liposomes within depot polymeric scaffolds. This attempts to provide ingenious solutions to the limitations of conventional liposomes such as short plasma half-lives, toxicity, stability, and poor control of drug release over prolonged periods. This review delineates the key advances in composite technologies that merge the concepts of depot polymeric scaffolds with liposome technology to overcome the limitations of conventional liposomes for pharmaceutical applications
Poly(ethylene glycol) enclatherated pectin-mucin submicron matrices for intravaginal anti-HIV-1 drug delivery
This paper explores the potential of polyethylene glycol enclatherated pectin-mucin (PEGencl-
PEC:MUC) submicron matrices (SMMs) as an intravaginal drug delivery system
capable of delivering an anti-HIV-1 agent (zidovudine; AZT) over a prolonged duration. A
three factor and three level (33) Box-Behnken statistical design was employed to optimize
the SMMs. Optimized PEG-encl-PEC:MUC SMMs prepared as a stable W/O emulsion
(determined by the degree of reversible colloidal phenomena) were spherical with a mean
particle size of 270.6±5.533nm and mean zeta potential of -34.4±0.539mV. The
microencapsulation of AZT and the hydrogen bonding mediated shielding of AZT by SMMs
was confirmed by Fourier Transform Infrared (FTIR) analysis. The thermochemical
(differential scanning calorimetry and thermogravimetric analysis) data proposed that Ca2+-
based macromolecular ionic crosslinking as well as the intermolecular interactions may be
responsible for the thermal stability of the delivery system. The partially amorphous nature of
drug-loaded SMMs, as confirmed by X-ray diffraction patterns, further strengthened the
matricization of AZT into the pectin-mucin matrix. In vitro drug release studies from the
SMMs showed approximately 91% zidovudine release in simulated vaginal fluid (SVF) and
94% in phosphate buffered saline (PBS) in 24 hours. The mean dissolution time (MDT) of
zidovudine from the SMMs was 5.974 hours. The attainment of required dimensional
structure and drug release profiles from SMMs highlights the potential of their inclusion into a
secondary carrier system for extended and controlled intravaginal stay.National Research Foundation (NRF) of South Africa.http://www.elsevier.com/locate/ijpharm2017-04-30hb2016Chemistr
Ex vivo and In vivo characterization of interpolymeric blend/nanoenabled gastroretentive levodopa delivery systems
One approach for delivery of narrow absorption window drugs is to formulate gastroretentive drug delivery systems. This study was undertaken to provide insight into in vivo performances of two gastroretentive systems (PXLNET and IPB matrices) in comparison to Madopar® HBS capsules. The pig model was used to assess gastric residence time and pharmacokinetic parameters using blood, cerebrospinal fluid (CSF), and urine samples. Histopathology and cytotoxicity testing were also undertaken. The pharmacokinetic parameters indicated that levodopa was liberated from the drug delivery systems, absorbed, widely distributed, metabolized, and excreted. were 372.37, 257.02, and 461.28 ng/mL and MRT were 15.36, 14.98, and 13.30 for Madopar HBS capsules, PXLNET, and IPB, respectively. In addition, X-ray imaging indicated that the gastroretentive systems have the potential to reside in the stomach for 7 hours. There was strong in vitro-in vivo correlation for all formulations with values of 0.906, 0.935, and 0.945 for Madopar HBS capsules, PXLNET, and IPB, respectively. Consequently, PXLNET and IPB matrices have pertinent potential as gastroretentive systems for narrow absorption window drugs (e.g., L-dopa) and, in this application specifically, enhanced the central nervous system and/or systemic bioavailability of such drugs.The National Research Foundation
(NRF) of South Africahttps://www.hindawi.com/journals/pdam2017Paraclinical Science
Dexamethasone-Loaded, PEGylated, vertically aligned, multiwalled carbon nanotubes for potential ischemic stroke intervention
Abstract: Please refer to full text to view abstract
Diagnosis and Treatment of Neurological and Ischemic Disorders Employing Carbon Nanotube Technology
Extensive research on carbon nanotubes has been conducted due to their excellent physicochemical properties. Based on their outstanding physicochemical properties, carbon nanotubes have the potential to be employed as theranostic tools for neurological pathologies such as Alzheimer’s disease and Parkinson’s disease including ischemic stroke diagnosis and treatment. Stroke is currently regarded as the third root cause of death and the leading source of immobility around the globe. The development and improvement of efficient and effective procedures for central nervous system disease diagnosis and treatment is necessitated. The main aim of this review is to discuss the application of nanotechnology, specifically carbon nanotubes, to the diagnosis and treatment of neurological disorders with an emphasis on ischemic stroke. Areas covered include the conventional current diagnosis and treatment of neurological disorders, as well as a critical review of the application of carbon nanotubes in the diagnosis and treatment of ischemic stroke, covering areas such as functionalization of carbon nanotubes and carbon nanotube-based biosensors. A broad perspective on carbon nanotube stimuli-responsiveness, carbon nanotube toxicity, and commercially available carbon nanotubes is provided. Potential future studies employing carbon nanotubes have been discussed, evaluating their extent of advancement in the diagnosis and treatment of neurological and ischemic disorders
In vivo evaluation of an Ultra-fast Disintegrating Wafer matrix : a molecular simulation approach to the ora-mucoadhesivity
The purpose of this study was to design and evaluate the performance of an Ultra-fast Disintegrating Wafer (U-D-WAF) loaded with highly water soluble diphenhydramine hydrochloride (DPH) through the oramucosa of the Large White Pig model. For the first time this work explored the oramucosivity of the U-D-WAF by detailed molecular modeling of the matrix on buccal tissue in order to mechanistically deduce the mucodhesivity. The U-D-WAF was formulated using a blend of hydroxypropylcellulose, poly(acrylic) acid, sodium starch glycolate and β –cyclodextrin in accordance with a Box-Benkhen experimental design for optimization prior to ex vivo permeation and in vivo release studies in the Large White Pig. Molecular simulation studies assess the mucoadhesivity of the U-D-WAF to the oramucosa. A mean Drug Entrapment Efficiency of 72.96 ± 4.32%, disintegration time of 29.33 ± 15.91 s and drug release after 60 s of 86.32 ± 20.37% was recorded. Ex vivo permeation studies revealed cumulative drug permeation of 86.32 ± 20.34% 60 s after onset. In vivo evaluation of the optimized U-D-WAF had a Cmax = 59 μgL−1 approximately 300 s after administration. The ultrafast disintegration of the U-D-WAF matrix with desirable mucoadhesivity in in vitro and in vivo studies makes it suitable for effective and rapid oramucosal drug delivery.The National Research Foundation (NRF) and the Technology Innovation Agency (TIA) of South Africa.http://www.elsevier.com/locate/jddst2018-02-20hj2018Paraclinical Science
A Review of the Effect of Processing Variables on the Fabrication of Electrospun Nanofibers for Drug Delivery Applications
Electrospinning is a fast emerging technique for producing ultrafine fibers by utilizing electrostatic repulsive forces. The technique has gathered much attention due to the emergence of nanotechnology that sparked worldwide research interest in nanomaterials for their preparation and application in biomedicine and drug delivery. Electrospinning is a simple, adaptable, cost-effective, and versatile technique for producing nanofibers. For effective and efficient use of the technique, several processing parameters need to be optimized for fabricating polymeric nanofibers. The nanofiber morphology, size, porosity, surface area, and topography can be refined by varying these parameters. Such flexibility and diversity in nanofiber fabrication by electrospinning has broadened the horizons for widespread application of nanofibers in the areas of drug and gene delivery, wound dressing, and tissue engineering. Drug-loaded electrospun nanofibers have been used in implants, transdermal systems, wound dressings, and as devices for aiding the prevention of postsurgical abdominal adhesions and infection. They show great promise for use in drug delivery provided that one can confidently control the processing variables during fabrication. This paper provides a concise incursion into the application of electrospun nanofibers in drug delivery and cites pertinent processing parameters that may influence the performance of the nanofibers when applied to drug delivery
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