Appraisal terpenoids rich Boswellia carterri ethyl acetate extract in binary cyclodextrin oligomer nano complex for improving respiratory distress.

Boswellia carterii (BC) resins plants have a long historical background as a treatment for inflammation, as indicated by information originating from multiple countries. Twenty-seven diterpenoids have been identified in ethyl acetate and total methanol BC, comprising seventeen boscartins of the cembrane-type diterpenoids and ten boscartols of the prenylaromadendrane-type diterpenoids. Moreover, twenty-one known triterpenoids have also been found, encompassing nine tirucallane-type, six ursane-type, four oleanane-type, and two lupane-type. The cembrane-type diterpenoids hold a significant position in pharmaceutical chemistry and related industries due to their captivating biological characteristics and promising pharmacological potentials. Extraction of BC, creation and assessment of nano sponges loaded with either B. carterii plant extract or DEX, are the subjects of our current investigation. With the use of ultrasound-assisted synthesis, nano sponges were produced. The entrapment efficiency (EE%) of medications in nano sponges was examined using spectrophotometry. Nano sponges were characterized using a number of methods. Within nano sponges, the EE% of medicines varied between 98.52 ± 0.07 and 99.64 ± 1.40%. The nano sponges' particle sizes varied from 105.9 ± 15.9 to 166.8 ± 26.3 nm. Drugs released from nano sponges using the Korsmeyer-Peppas concept. In respiratory distressed rats, the effects of BC plant extract, DEX salt and their nano formulations (D1, D5, P1 and P1), were tested. Treatment significantly reduced ICAM-1, LTB4, and ILß 4 levels and improved histopathologic profiles, when compared to the positive control group. Boswellia extract and its nano sponge formulation P1 showed promising therapeutic effects. The effect of P1 may be due to synergism between both the extract and the formulation. This effect was achieved by blocking both ICAM-1 and LTB4 pathways, therefore counteracting the effects of talc powder.

Corrigendum to "Quercitrin loaded cyclodextrin based nanosponge as a promising approach for management of lung cancer and COVID-19" [J. Drug Deliv. Sci. Technol. 77 (2022) 103921].

[This corrects the article DOI: 10.1016/j.jddst.2022.103921.].

Effectuation of loading a natural acetyl carnosine derivative within a promising cross-linked cyclodextrin spongey-like nanospheres on Physicochemical characterization and release behavior.

This study centered on the ability of the cross-linked nano-sponge system to load the drug and to improve its physicochemical and dissolution properties. A spectrophotometric method was used to determine the wavelength of maximum absorbance of the drug. The ultrasonic-assisted synthesis method was used for nano-sponge preparation. Solution-state interactions, encapsulation efficiency and production yield, and in-vitro release were also investigated. Nano-sponges were characterized by Transmission Electron-Microscopy (TEM), Scanning Electron-Microscopy (SEM), Fourier Transform-Infrared Spectroscopy (FT-IR), Differential Scanning Calorimetry (DSC), and X-Ray Diffractometry (X-RD) studies. The maximum absorption wavelength of N-acetyl-L-carnosine was found to be at 210 nm. Solution-state interaction studies revealed a bathochromic shift. The production yield of nano-sponges ranged from 59.58% to 72.54%. In-vitro release study showed a sustained drug release for 228 hours. TEM images showed regular spherical shapes and sizes of nano-sponges. Their average particle size ranged from 28 nm to 79.2 nm. DSC data documented the drug-polymer interactions. FT-IR determined the presence of functional groups. X-RD showed the physicochemical characteristics of nano-sponges. Proving successful development of N-acetyl-L-carnosine polymeric nano-sponge system with a suitable drug delivery over an extended period beside a noticeable improvement in the physicochemical characterization.