ABSTRACT
The solubility of gentamicin in various formulation vehicles (oils, surfactants and co-surfactants)
was determined using the shake flask method. Emulsifying ability of the surfactants for the
selected oil was screened. Different SNEF prototypes were developed following the construction
of ternary phase diagrams using water titration method. The effect of drug and other additives on
the ternary phase diagrams were studied and the selected formulations were optimized.
Optimized formulations were characterized by weight uniformity of their capsule shells and
visual assessment of their self nanoemulsification. The optical clarity and robustness to dilution
of the SNEFs were evaluated. Emulsification time, droplet size, zeta potential, polydispersity
index and Fourier transform-infrared spectroscopy were measured. SNEFs were also
characterized by scanning electron microscopy (SEM). Apparent viscosities, absolute drug
content and drug content efficiencies were determined. Stability studies and octanol/water
partition coefficient were evaluated, while in vitro antibacterial studies of the SNEFs and
permeation studies were carried out. In vitro anti-pneumococcal study of the SNEFs against S.
pneumoniae was done followed by extrapolation of their minimum inhibitory concentrations
(MICs). In vivo anti-pneumococcal studies of gentamicin released in the sera and CSF of white
albino rats were evaluated. Haematological studies were carried out to measure packed cell
volume (PCV), total white blood cells (WBC), red blood cells (RBC) and haemoglobin (Hb)
concentrations. Biochemical studies were performed to evaluate alanine aminotransferase (ALT),
aspartate aminotransferase (AST), alkaline phosphatase (ALP), bilirubin and creatinine
concentrations. This was followed by histopathological examinations of the brain, kidney and
liver of the animals. Results were expressed as mean ± SD. ANOVA and student t-tests were
performed on the data sets. Ternary phase plots were analyzed using SigmaPlot® 11.0.
Permeation calculations were performed with a special Microsoft excel programme. Differences
were considered significant for p values < 0.05. Gentamicin produced maximum solubility in
soyabean oil, Kolliphor® EL, Kolliphor® P188, and in Transcutol® HP. PEG 4000 and
gentamicin reduced the area of nanoemulsion formation in the ternary phase diagrams for the
selected systems. The emulsion droplet size was in the nanometer scale. The SNEF capsules had
uniform average weight of 300 mg ± 0.7. The SNEFs had good optical clarity with percentage
transmittances above 50 % and showed low propensity to drug precipitation, and exhibited rapid
emulsification rate (17 – 40 s). FTIR revealed that the structure of gentamicin remained
completely intact in all the formulations. SEM micrographs showed smooth and spherical
globules. Rheological studies showed decrease in apparent viscosities with increase in shearing
speed. Drug content ranged from 36.3 – 99.8 %. Stability studies suggest that the SNEFs were
relatively stable over 4 months. Octanol/water partition coefficient ranged from 0.38 – 1.46. In
vitro antibacterial studies showed susceptibility in the order: K. pneumonia > E. coli > S. aureus
> B. subtilis. In vitro permeation studies of showed overall extended permeation of gentamicin.
In vitro anti-pneumococcal study showed MICs of 2.5 – 5 mg/ml. In vivo anti-pneumococcal
study of gentamicin in sera suggests that sera from animals administered with batch C (3:1 w/w)
gentamicin SNEFs at 7 mg/kg produced good inhibition of the bacteria. The in vivo antipneumococcal
activity of gentamicin in CSF showed rapid establishment of a biocidal
concentration after 30 min. Haematological studies showed increase in PCV, RBC and Hb
counts while WBC count and its differentials decreased. Biochemical studies showed decreased
ALP and varying AST, ALT, bilirubin and creatinine concentrations. Histopathological findings
showed dominant astrocytosis of the brain for gentamicin-loaded SNEFs indicating a breach of
the integrity of the BBB.
EMMANUEL, U (2021). Formulation And Characterization Of Novel Pegylated Selfnanoemulsifying Formulations (Snefs) For Oral Delivery Of Gentamicin And Its Possible Use In The Treatment Of Pneumococcal Meningitis. Afribary. Retrieved from https://afribary.com/works/formulation-and-characterization-of-novel-pegylated-selfnanoemulsifying-formulations-snefs-for-oral-delivery-of-gentamicin-and-its-possible-use-in-the-treatment-of-pneumococcal-meningitis
EMMANUEL, UMEYOR "Formulation And Characterization Of Novel Pegylated Selfnanoemulsifying Formulations (Snefs) For Oral Delivery Of Gentamicin And Its Possible Use In The Treatment Of Pneumococcal Meningitis" Afribary. Afribary, 13 May. 2021, https://afribary.com/works/formulation-and-characterization-of-novel-pegylated-selfnanoemulsifying-formulations-snefs-for-oral-delivery-of-gentamicin-and-its-possible-use-in-the-treatment-of-pneumococcal-meningitis. Accessed 22 Nov. 2024.
EMMANUEL, UMEYOR . "Formulation And Characterization Of Novel Pegylated Selfnanoemulsifying Formulations (Snefs) For Oral Delivery Of Gentamicin And Its Possible Use In The Treatment Of Pneumococcal Meningitis". Afribary, Afribary, 13 May. 2021. Web. 22 Nov. 2024. < https://afribary.com/works/formulation-and-characterization-of-novel-pegylated-selfnanoemulsifying-formulations-snefs-for-oral-delivery-of-gentamicin-and-its-possible-use-in-the-treatment-of-pneumococcal-meningitis >.
EMMANUEL, UMEYOR . "Formulation And Characterization Of Novel Pegylated Selfnanoemulsifying Formulations (Snefs) For Oral Delivery Of Gentamicin And Its Possible Use In The Treatment Of Pneumococcal Meningitis" Afribary (2021). Accessed November 22, 2024. https://afribary.com/works/formulation-and-characterization-of-novel-pegylated-selfnanoemulsifying-formulations-snefs-for-oral-delivery-of-gentamicin-and-its-possible-use-in-the-treatment-of-pneumococcal-meningitis