Interdigitation of lipids for vesosomal formulation of ergotamine tartrate with caffeine: a futuristic trend of intranasal route.

OBJECTIVE: This research work aimed to form vesosomes using combination of two drugs ergotamine (ERG) and caffeine for synergistic activity when given intranasally resulting in faster absorption, steric stability, and controlled release. SIGNIFICANCE: The multicompartment vesicles viz., vesosomes of ERG tartrate proved to increase absorption of drugs post-intranasal administration, bypassing the blood-brain barrier via the olfactory pathway. METHODS: The phospholipids like soya lecithin, cholesterol, and dipalmitoyl phosphatidylcholine (DPPC) were used to form a multicompartment structure called vesosomes using ethanol-induced interdigitation of lipids as the preparation method. RESULTS: The formulation showed low particle size (PS) of 315.48 ± 14.27 nm with zeta potential (ZP) of -21.78 ± 4.72 mV, higher % EE of 91.13 ± 1.29%, and controlled release kinetics, when assessed for in-vitro and ex-vivo studies as 97.64 ± 5.13% and 82.25 ± 3.27% release, respectively. Vesosomes displayed several advantages over liposomes like improved stability against phospholipase-induced enzymatic degradation and higher brain uptake 3.41-fold increase of ERG via the olfactory pathway. CONCLUSIONS: The stable vesosomes prepared using interdigitation of saturated phospholipids proved to be a viable option for ERG when administered intranasally for better absorption and bioavailability coupled with ease of administration gaining wider patient acceptance.

Vesosomes as multicompartment vesicles formulated of ergotamine (ERG) and caffeine for synergistic action in migraine treatment.Ethanol induced for interdigitation of lipids in vesosomes preparation exhibited nano-size, good colloidal stability, better encapsulation efficiency, and controlled release profile.ERG vesosomes demonstrated stability against phospholipase-induced enzymatic degradation.

Use of 3D applicator for intranasal microneedle arrays for combinational therapy in migraine.

The objective of current research work was to fabricate dissolving microneedles combining ergotamine and caffeine for synergistic action using controlled release kinetics with better permeability. The method of preparation for microneedles utilized multiple emulsion (w/o/w) approach by solvent-diffusion-evaporation process wherein the nano-emulsion of ergotamine and caffeine prepared using PLGA polymer and PVA as a stabilizer. The PLGA nanospheres were further loaded in polymer matrix of PVA and PVP K-90 and the final mixture poured in sterile silicon molds of microneedles. The PLGA nanospheres exhibited particle size in narrow range of 280.34 ± 6.61 to 416.0 ± 9.67 nm and good colloidal stability with negative zeta potential ranging between -19.08 ± 8.77 to -22.49 ± 8.09 mV. Higher entrapment efficiency (86.21 ± 4.52 %) for ergotamine and controlled release pattern (49.79 ± 4.16 % at 48 h) displayed by PLGA nanospheres. Similarly, the dissolving microneedles loaded with PLGA nanospheres showed controlled release pattern for in-vitro and ex-vivo drug release studies with 52.01 ± 5.71 % for ERM and 87.04 ± 2.44 % for CFE at 48 h whereas ex-vivo release studies illustrated similar results of 51.08 ± 3.56 % for ERM and 69.2 ± 2.16 % for CFE. The anti-hyperalgesic capability of microneedles was verified by the acetic acid writhing test, and the non-toxicity of synthetic microneedles was confirmed by histopathology and serotonin toxicity studies. The novel 3D applicator effectively delivered the microneedle array into the nasal cavity for systemic action. Therefore, the fabricated rapid dissolving microneedles combining two drugs ergotamine and caffeine with use of 3D applicator proved to be a coherent technique for intranasal delivery of ergotamine in the treatment of migraine.

Self-Assembled Lipid Polymer Hybrid Nanoparticles Using Combinational Drugs for Migraine Via Intranasal Route.

The objective of the current research study was to formulate the PEGylated lipid polymer hybrid nanoparticles of ergotamine and caffeine for intranasal administration with higher entrapment efficiency, better permeability, desirable controlled release pattern, and significant brain uptake in animal studies. A single-step nanoprecipitation method was employed in the processing of self-assembled hybrid nanoparticles constituting polymer PLGA, lipids soya lecithin, and DPPC with PEGylation using polyethylene glycol (PEG-2000). The optimal lipid/polymer weight ratio of 15% w/w showed lower particle size of 239.46 ± 2.31 nm with good colloidal stability depicted by zeta potential (- 18.36 ± 6.59 mV), higher entrapment efficiency of 86.88 ± 1.67%, and controlled release profile when evaluated for in vitro and ex vivo studies as 97.12 ± 2.79% and 75.13 ± 5.62% release, respectively, for 48 h. The formulation showed long-term serum stability when incubated in bovine serum albumin and displayed high brain uptake (4.35-fold) offering significant permeability in the brain post-intranasal administration via olfactory route. Histopathological investigations and serotonin toxicity studies in animals confirmed the safe and non-toxic nature of the formulation while the acetic acid writhing test proved the anti-hyperalgesic activity. The PEGylated lipid polymer hybrid nanoparticles of ergotamine and caffeine showed synergistic activity with efficacious higher anti-migraine potential.

Advances in Stem Cell Therapy for Brain Diseases via the Intranasal Route.

Stem cell therapy efficiently targets the brain for most neurological disorders like migraine, Parkinsonism, schizophrenia, Alzheimer's disease, and brain injury. The major obstacles in potential brain targeting are the physiological barriers like blood-brain-barrier and bloodcerebrospinal fluid barrier. The conventional injectable route or direct transplantation of stem cells results in brain injury and is less feasible clinically. The alternative to these invasive routes is the intranasal route that is non-invasive, easily repeatable technique and highly effective in brain targeting without crossing the blood-brain barrier. Extensive research has been undertaken for the delivery of stem cells to the brain via the intranasal route that holds great potential in overcoming the existing barriers. Nanotechnology is emerging as a novel interdisciplinary field in the arena of stem cell research. The combination of nanotechnology coupled with stem cell therapy has led to synergistic outcomes in diagnostic and therapeutic applications of neurological diseases. This review provides insights into stem cell-based nanotherapy for brain targeting via the intranasal route.