In the present study, silver nanoparticles (AgNPs) were synthesized using aqueous leaf extracts of three Congolese plant species, namely
Brillantaisia patula
(BR-PA),
Crossopteryx febrifuga
(CR-FE) and
Senna siamea
(SE-SI). The obtained AgNPs were studied for their optical, structural, surface morphological and antibacterial properties. The prepared AgNPs were characterized by using UV-Visible spectra, Transmission Electron Microscopy (TEM), Fourier Transform Infrared Spectroscopy (FTIR), X-ray spectroscopy (EDX) and X-ray diffractometer (XRD). The synthesized nanoparticles were spherical shaped and well-dispersed with average sizes ranging from 45 to 110 nm. The AgNPs derived from BR-PA, CR-FE and SE-SI exhibited higher antibacterial activity against three bacterial pathogens of the human skin compared to their respective crude extracts and AgNO
3
. This indicated that the biomolecules covering the nanoparticles may enhance the biological activity of metal nanoparticles. Hence, our results support that biogenic synthesis of AgNPs from Congolese plants constitutes a potential area of interest for the therapeutic management of microbial diseases such as infectious skin diseases.
Liposomes are currently part of the most reputed carriers for various molecular species, from small and simple to large and complex molecules. Since their discovery, liposomes have been subject to extensive evolution, in terms of composition, manufacturing and applications, which led to several openings in both basic and applied life sciences. However, most of the advances in liposome research have been more devoted to launching new developments than improving the existing technology for potential implementation. For instance, the evolution of the conventional lipid hydration methods to novel microfluidic technologies has permitted upscale production, but with increase in manufacturing cost and persistent use of organic solvents. This chapter intends to present general concepts in liposome technology, highlighting some longstanding bottlenecks that remain challenging to the preparation, characterization and applications of liposomal systems. This would enhance the understanding of the gaps in the field and, hence, provide directions for future research and developments.
Nanoencapsulation is an approach to circumvent shortcomings such as reduced bioavailability, undesirable side effects, frequent dosing and unpleasant organoleptic properties of conventional drug delivery systems. The process of nanoencapsulation involves the use of biomaterials such as surfactants and/or polymers, often in combination with charge inducers and/or ligands for targeting. The biomaterials selected for nanoencapsulation processes must be as biocompatible as possible. The type(s) of biomaterials used for different nanoencapsulation approaches are highlighted and their use and applicability with regard to haemo- and, histocompatibility, cytotoxicity, genotoxicity and carcinogenesis are discussed.
Cowpea
mosaic virus (CPMV) is a potent immunogenic adjuvant and
epitope display platform for the development of vaccines against cancers
and infectious diseases, including coronavirus disease 2019. However,
the proteinaceous CPMV nanoparticles are rapidly degraded in vivo.
Multiple doses are therefore required to ensure long-lasting immunity,
which is not ideal for global mass vaccination campaigns. Therefore,
we formulated CPMV nanoparticles in injectable hydrogels to achieve
slow particle release and prolonged immunostimulation. Liquid formulations
were prepared from chitosan and glycerophosphate (GP) before homogenization
with CPMV particles at room temperature. The formulations containing
high-molecular-weight chitosan and 0–4.5 mg mL
–1
CPMV gelled rapidly at 37 °C (5–8 min) and slowly released
cyanine 5-CPMV particles in vitro and in vivo. Importantly, when a
hydrogel containing CPMV displaying severe acute respiratory syndrome
coronavirus 2 spike protein epitope 826 (amino acid 809–826)
was administered to mice as a single subcutaneous injection, it elicited
an antibody response that was sustained over 20 weeks, with an associated
shift from Th1 to Th2 bias. Antibody titers were improved at later
time points (weeks 16 and 20) comparing the hydrogel versus soluble
vaccine candidates; furthermore, the soluble vaccine candidates retained
Th1 bias. We conclude that CPMV nanoparticles can be formulated effectively
in chitosan/GP hydrogels and are released as intact particles for
several months with conserved immunotherapeutic efficacy. The injectable
hydrogel containing epitope-labeled CPMV offers a promising single-dose
vaccine platform for the prevention of future pandemics as well as
a strategy to develop long-lasting plant virus-based nanomedicines.
Liposomes are reputed colloidal vehicles that hold the promise for targeted delivery of anti-tubercular drugs (ATBDs) to alveolar macrophages that host Mycobacterium tuberculosis. However, the costly status of liposome technology, particularly due to the use of special manufacture equipment and expensive lipid materials, may preclude wider developments of therapeutic liposomes. In this study, we report efficient encapsulation of a complex system, consisting of isoniazid-hydrazone-phthalocyanine conjugate (Pc-INH) in gamma-cyclodextrin (
γ
-CD), in liposomes using crude soybean lecithin by means of a simple organic solvent-free method, heating method (HM). Inclusion complexation was performed in solution and solid-state, and evaluated using UV-Vis, magnetic circular dichroism,
1
H NMR, diffusion ordered spectroscopy and FT-IR. The HM-liposomes afforded good encapsulation efficiency (71%) for such a large Pc-INH/
γ
-CD complex (PCD) system. The stability and properties of the PCD-HM-liposomes look encouraging; with particle size 240 nm and Zeta potential −57 mV that remained unchanged upon storage at 4 °C for 5 weeks. The release study performed in different pH media revealed controlled release profiles that went up to 100% at pH 4.4, from about 40% at pH 7.4. This makes PCD-liposomes a promising system for site-specific ATBD delivery, and a good example of simple liposomal encapsulation of large hydrophobic compounds.
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