Development of dry powder inhalers involves powder recrystallization, formulation, dispersion, delivery, and deposition of the therapeutic agent in different regions of the airways in prophylaxis/ treatment/ diagnosis of pulmonary and systemic disorders. Conventional powder production by crystallization and milling has many limitations resulting into development of alternative techniques to overcome the problems. In the last decade many patents have been filed claiming improvement in aerosol performance of dry powder inhalers through the use of (i) incorporation of fines of carrier particles to occupy active sites on the surface and use of hydrophobic carriers to facilitate deaggregation through reduced surface energy and particle interaction (ii) reducing aerodynamic diameters through particle engineering and incorporating drug into porous or low particle density, and/or (iii) preparing less cohesive and adhesive particles through corrugated surfaces, low bulk density, reduced surface energy and particle interaction and hydrophobic additives. Moisture within dry powder inhaler (DPI) products has also been shown to influence aerosol performance via capillary force and electrostatic interaction. Better understanding of particle forces and surface energy has been achieved by the use of sophisticated analytical techniques. Understanding the intricacies of particle shape and surface properties influencing specific lung deposition has been further facilitated by the availability of newer and advanced softwares. A critical review of recent patents claiming different approaches to improve lung deposition of dry powder inhalers will help in deciding the focus of the research in the area of technological gaps.
The treatment of brain disorders is the greatest challenge because of a variety of formidable obstacles in effective drug delivery and maintaining therapeutic concentrations in the brain for a prolonged period. The brain is a delicate organ, and evolution built very efficient ways to protect it. The same mechanisms that protect it against intrusive chemicals can also frustrate therapeutic interventions. Approximately, 100% of large molecule drugs and >98% of small molecule drugs do not cross the blood-brain barrier (BBB). Many advanced and effective approaches to brain delivery of drugs have emerged in recent years. Intranasal drug delivery is one of the important delivery options for brain targeting, as the brain and nose compartments are connected to each other via the olfactory/trigeminal route and via peripheral circulation. Realization of nose to brain transport and the therapeutic viability of this route can be traced from the ancient times and has been investigated for rapid and effective transport in the last two decades. Many patents have been filed in recent past, claiming enhanced delivery of intranasally administered therapeutics to the brain via olfactory/trigeminal neural pathways, use of novel devices for targeted delivery to olfactory region etc. Various models have been designed and studied by scientists to establish the qualitative and quantitative transport through nasal mucosa to brain. The development of nasal drug products for brain targeting is still faced with enormous challenges. A better understanding in terms of properties of the drug candidate, nose to brain transport mechanism, and transport to and within the brain is of utmost importance. A critical review of recent patents claiming different approaches for enhanced brain delivery through the nasal route will help in determining the focus of this promising area of research.
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