Lipo-polymeric nano-complexes for dermal delivery of a model protein.

Delivering macromolecules across the skin poses challenges due to the barrier properties of stratum corneum. Different strategies have been reported to cross this barrier, such as chemical penetration enhancers and physical methods like microneedles, sonophoresis, electroporation, laser ablation, etc. Herein, we explored a cationic lipo-polymeric nanocarrier to deliver a model protein across the skin. A cationic amphiphilic lipo-polymer was used to prepare blank nanoplexes, which were subsequently complexed with anionic fluorescein-tagged bovine serum albumin (FITC-BSA). Blank nanoplexes and FITC-BSA complexed nanoplexes showed sizes of 93.72 ± 5.8 (PDI-0.250) and 145.9 ± 3.2 nm (PDI-0.258), respectively, and zeta potentials of 25.6 ± 7.0 mV and 9.17 ± 1.20 mV. In vitro cell culture, and toxicity studies showed optimal use of these nanocarriers, with hemocompatibility data indicating non-toxicity. Ex vivo skin permeation analysis showed a skin permeation rate of 33% after 24 h. The optimized formulation was loaded in a carbopol-based gel that exhibits non-Newtonian flow characteristics with shear-thinning behavior and variable thixotropy. The nanoplexes delivered via gel demonstrated skin permeation of 57% after 24 h in mice skin ex vivo. In vivo skin toxicity testing confirmed the low toxicity profile of these nanocarriers. These results are promising for the transdermal/dermal delivery of macromolecules, such as protein therapeutics, using nanoplexes.

cRGD-modified hybrid lipopolymeric nanoplexes for gene editing in the posterior segment of the eye.

Eye-related diseases, specifically retinal dystrophy (RD) conditions, are the leading cause of blindness worldwide. Gene addition, regulation, or editing could potentially treat such diseases through gene expression regulation. CRISPR/Cas9 gene editing is one of the most prominent and precise gene editing tools which could be employed to edit genes related to the dystrophic condition. However, CRISPR/Cas9 faces in vivo delivery challenges due to its high molecular weight, negative charge, prone to degradation in the presence of nucleases and proteases, poor cellular degradation, etc., which makes it challenging to adopt for therapeutic applications. We developed cRGD-modified lipopolymeric nanoplexes loaded with Cas9 RNPs with a particle size and zeta potential of 175 ±â€¯20 nm and 2.15 ±â€¯0.9 mV, respectively. The cRGD-modified lipopolymeric nanoplexes were stable for 194 h and able to transfect >70 % ARPE-19 and NIH3T3 cells with an Indel frequency of ~40 % for the VEGF-A gene. The cRGD-modified lipopolymeric nanoplexes found good vitreous mobility and could transfection retinal cells in vivo after 48 h of intravitreal injection in Wistar Rats. Moreover, in vivo VEGFA gene editing was ~10 % with minimal toxicities. Collectively, the cRGD-modified lipopolymeric nanoplexes were found to have extreme potential in delivering CRISPR/Cas9 RNPs payload to the retinal tissues for therapeutic applications.

In situ Hydrogels for Effective Treatment of Cancer: Strategies and Polymers Used.

Cancer is a worldwide health ailment with no known boundaries in terms of mortality and occurrence rates, thus is one of the biggest threats to humankind. Hence, there is an absolute need to develop novel therapeutics to bridge the infirmities associated with chemotherapy and conventional surgical methodologies including impairment of normal tissue, compromised drug efficiency and an escalation in side effects. In lieu of this, there's been a surge in curiosity towards development of injectable hydrogels for cancer therapy because local administration of the active pharmaceutical agent offers encouraging advantages such as providing higher effective dose at target site, prolonged retention time of drug, ease of administration, mitigation of dose in vivo ,improved patient compliance. Furthermore, due to its biocompatible nature such systems can significantly reduce the side effects that occur on long-term exposure to chemotherapy. The present review details the most recent advancements in in-situ gel forming polymers (natural and synthetic), polymeric cross-linking methodologies and in-situ gelling mechanisms, focusing on their clinical benefits in cancer therapy.

Novel Therapeutics Involving Antibiotic Polymer Conjugates for Treating Various Ailments: A Review.

Antibiotic polymer conjugates (APCs) are an essential part of polymer therapeutics. These conjugates have been used as an appealing platform for drug delivery. As a delivery vector, the administration route severely impacts the accessibility of antibiotics to their respective target site and therapeutic index. Furthermore, the physicochemical and biological properties of conjugates also correlate distinctly with the route of administration. The APCs delivery methods that have been disclosed so far suffer from significant constraints due to poor technology and constrained administration routes (mainly injections). Leading to promising directions, which include the development of specific characteristics for each polymer carrier, application of novel biodegradable polymers, expansion of traditional drug administration routes through the development of emerging routes, and the development of a rational and systematic methodology for designing administration routes are yet to be explored widely. This review focuses primarily on recent improvements in various routes of administration (dental, topical, and ocular) employing APCs. The mechanism of action, as well as other perspectives, have also been discussed. Moreover, this innovative technology provides a fresh perspective on pharmaceutical science research and offers unique and potential pathways for designing desired APCs.

Pharmaceutical Perspective in Wearable Drug Delivery Systems.

Humans have been dealing with health problems for millions of years. Normal health services need well-trained personnel and high-cost diagnostic tests, which forces patients to go to hospitals if medical treatment is required. To address this, prototype testing has been carried out into the wearable drug delivery health care perspectives. Researchers have devised a wide variety of formulations for the treatment of various diseases at home by performing real-time monitoring of different routes of drug administration such as ocular, transdermal, intraoral, intracochlear, and several more. A comprehensive review of the different types of wearable drug delivery systems with respect to their manufacturing, mechanism of action and specifications has been done. In the pharmaceutical context, these devices are technologically well-equipped interfaces for diverse physicochemical signals. Above mentioned information with a broader perspective has also been discussed in this article. Several wearable drug delivery systems have been introduced in the market in recent years. But a lot of testing needs to be conducted to address the numerous obstacles before the wearable devices are successfully launched in the market.

Olive oil and oleic acid-based self nano-emulsifying formulation of omega-3-fatty acids with improved strength, stability, and therapeutics.

AIM: To develop, characterise, and optimise SNEDDS formulation to enhance organoleptics, bioavailability, physical & oxidative-stability, and extend shelf-life of pure Ω-3-fatty acids oil for use in the food fortification industry as nutraceuticals. METHODS: SNEDDS formulations were prepared using a simple stirring technique and optimised based on in-vitro characterisation. RESULTS: The optimised SNEDDS formulation (F3) had a mean diameter of 52.9 ± 0.4 nm, PDI of 0.229 ± 0.02, zeta potential of -17.3 ± 0.1 mV, cloud temperature of 92 ± 0.2 °C, self-emulsification time of 50 ± 0.2 sec, and stable under accelerated stability conditions. Intestinal permeability study on rat ileum depicted absorption of 88.5 ± 0.2% DHA at 5 h for F3 formulation in comparison to 61.5 ± 0.2% for commercial counterpart. F3 formulation exhibited better therapeutics for melamine-induced cognitive dysfunction. CONCLUSIONS: The developed Ω-3-loaded SNEDDS heralds the future for an efficacious, safer, and higher strength formulation intended as a better substitute for currently available formulations.

Development, Characterization and Evaluation of Parenteral Formulation of Diclofenac Sodium.

Diclofenac sodium is a potent NSAID, classified under BCS class II category having a poor aqueous solubility. Recently, its injectable formulation got banned and withdrawn from the market due to its severe nephrotoxicity caused by the use of synthetic surfactant, i.e. Transcutol-P as solubilizer. Therefore, the present study was aimed to prepare Transcutol-P free injectable using Vitamin E TPGS as a biosurfactant which is in list of inactive ingredients by US-FDA. Various cost effective aqueous injectable formulations were prepared by mixed solvency method that were characterized and optimized for different in vitro quality control parameters. Further, ex vivo hemolytic study showed the increased safety (23.4 ± 1.6%) of optimized formulation as compared with its commercial counterpart (100 ± 4.2%) at 75 mg/ml. Furthermore, in vivo acute and sub-acute toxicity study demonstrated an increase in LD50 to 123.75 ± 6.2 mg/kg to that of a commercial counterpart (109.96 ± 5.5 mg/kg). In addition, optimized formulation demonstrated better mean residence time and area under curve when compared with commercial test group, respectively. Moreover, optimized formulation was also evaluated for its therapeutic efficacy. The results obtained from acetic acid-induced writhing test in albino mice showed 78 ± 2.1% protection from writhes after 120 min, whereas the commercial formulation had only 48.3 ± 1.9% protection. Additionally, carrageenan-induced rat paw edema model also confirmed the better anti-inflammatory activity of optimized aqueous injectable formulation than its commercial counterpart. Thus, the developed aqueous injectable formulation of diclofenac is free from toxic Transcutol-P with enhanced safety and therapeutic efficacy.

Polymeric precipitation inhibitor as an effective trigger to convert supersaturated into supersaturable state in vivo.

The supersaturated state of the drug in vivo is thermodynamically unstable resulting in a delayed response and reduced efficacy. The use of polymeric precipitation inhibitor (PPI) has been demonstrated as an effective trigger for the conversion of supersaturated state to supersaturable state for improving solubilization, thermodynamic maintenance of drug concentration and oral absorption of poorly water-soluble compounds. PPI retards drug precipitation and provides a kinetically stabilized supersaturation state for an extended period in gastric and intestinal fluids. However, the selection of appropriate PPI and understanding its mechanism is a challenge for formulating a stable pharmaceutical formulation. The present review is aimed at understanding the intricacies of selecting PPIs and their applications in pharmaceutical formulations.