Current Approaches and Pharmaceutical Applications of Colloidosome Drug Delivery Systems

DOI:

https://doi.org/10.37285/ijpsn.2012.5.4.2

Authors

  • S. Pradeep Kumar
  • Prathibha D

Abstract

Recently a number of lipid based systems like lipospheres, liposomes, niosomes, ethosomes, and transferosomes have been developed. The purpose of this review article on colloidosome drug delivery was to compile the focus on the types, properties, fabrication techniques, characterization and stability of colloidosomes. This system also solves the problem of insolubility, instability, rapid degradation and is widely used in specialized areas like protein delivery, gene delivery, targeting to the brain and tumor targeting. In a series of vascular systems, colloidosome represents an advanced tool in drug delivery. Colloidosomes are an emerging vesicular system in drug delivery. Vesicular drug delivery reduces the cost of therapy by improved bioavailability of medication, especially in the case of poorly soluble drugs. Colloidosomes have a great encapsulation efficacy with a wide control over size, permeability, mechanical strength and compatibility.

Downloads

Download data is not yet available.

Metrics

Metrics Loading ...

Keywords:

Colloidosomes, emulsion droplets, fused colloidal particles, microcapsules

Downloads

Published

2013-02-28

How to Cite

1.
Kumar SP, D P. Current Approaches and Pharmaceutical Applications of Colloidosome Drug Delivery Systems. Scopus Indexed [Internet]. 2013 Feb. 28 [cited 2024 Dec. 22];5(4):1832-40. Available from: https://ijpsnonline.com/index.php/ijpsn/article/view/591

Issue

Section

Review Articles

References

Ashby NP, Binks BP and Paunov VN (2004). Bridging interaction between a water drop stabilized by solid particles and a planar oil/water interface. Chem Comm 21: 436-437.

Biju SS, Talegaonkar S, Mishra PR, and Khar RK (2006). Vesicular systems: An overview. Indian J Pharm Sci 68:141-153.

Caruso F, Trau D and Mohwald H (2000). Layer-by-Layer (LbL) encapsulation. Langmuir 16: 1485.

Cayre OJ, PF Noble and VN Paunov (2004). Fabrication of novel colloidosomes microcapsules with gelled aqueous cores. J Mater Chem 14: 3351-3355.

Chanchal D and Swarnlata S (2008). Novel approaches in herbal cosmetics. J Cosmet Dermatol 7: 89-95.

Chein YW (1982). Novel drug delivery systems: Fundamentals, developmental concepts and biomedical assessments. Dekker, New Yark.

Chein YW (1989). Rate-control drug delivery systems; controlled release vs. sustained release. Med Prog Tech 15: 21-46.

Daeyeon Lee and Weitz DA (2009). Nonspherical colloidisomes with multiple compartments from double emulsions. Indian Science 17: 1932-1935.

Dayton Lee and David A.Weitz (2008), Double emulsion–templated nanoparticle colloidosomes with selective permeability. Indian Science 20: 3498-3503.

Dinsmore AD, Hsu MF, Nikolaides MG, Marquez M, Bausch AR, and Weitz DA (2002). Colloidosomes: selectively permeable capsules composed of colloidal particles. Science 298: 1006-1009.

Elsayed MMA, Abdullah OY, Nagar VF and Khalafallah NM (2006). Deformable liposome and ethosome: mechanism of enhanced skin delivery. Int J Pharm 322: 60-66.

Gibbs BF, Kermasha S, Alli I and Mulligan CN (1999). Encapsulation in the food industry: A review. Int J Food Sci Nutr 50: 213-224.

Gu YS, Decker EA and McClements DJ (2007). Formation of colloidosomes by adsorption of small charged oil droplets onto the surface of large oppositely charged oil droplets. Food Hydrocolloids 21: 516-526.

Kim JW, Fernandez-Nieves A, Dan N, Utada AS, Marquez M and Weitz DA (2007). Colloidal assembly route for responsive colloidosomes with tunable permeability. Nano Lett 7: 2876-2880.

Kim JW, Utada AS, Fernandez-Nieves A, Hu Z and Weitz DA (2007). Fabrication of monodisperse gel shells and functional microgels in microfluidic devices, Angewandte Chemie, 46: 1819-1822.

Kim JW and Weltz DA (2009). Colloidosomes having tunable properties and methods for making colloidosomes having tunable properties Nano Lett. 7:2876-80

Laib S. and Routh AF (2008). Fabrication of colloidosomes at low temperature for the encapsulation of thermally sensitive compounds. J Colloid Interface Sci 317: 121-129.

Lee D and Weitz DA (2008). Double emulsion-templated nanoparticle colloidosomes with selective permeability. Adv Mater 20: 3498-3503.

Liu H, Wang C, GAO Q, Liu X and Tong Z (2008). Fabrication of novel core-shell hybrid alginate hydro gel beads. Int J Pharm 351: 104-112.

McClements DJ (2000). Food emulsions: principles, practice and techniques. 2nd Edn., CRC Press USA 632.

Ofoegbu O (2003). Force measurements on nanorods-enriched sintered colloidosomes. Gordon Mckay Labs: Harvard University Summer pp: 2-9.

Olivier J. Cayre, Paul F. Noble and Vaseline N., Paunov, (2004). Fabrication of novel colloid some microcapsules with gelled aqueous cores. J Mater Chem 14: 3351–33.

Paunov VN, P.F. Noble, O.J. Cayre, R.G. Alargova and Velev OD (2005). Fabrication of novel types of colloidosome microcapsules for drug delivery applications. Mater Res Soc Symp Proc 845: 279-283.

Paul F. Noble, Cayre OJ, Alargova RG, Velev OD and Paunov VN (2004). Fabrication of “hairy” colloidosomes with shells of polymeric microrods. J Am Chem Soc 126: 8092-8093

Rawat M and Saraf S (2008). Liposphere: emerging carriers in the delivery of proteins and peptides. Int. J. Pharm. Sci. Nanotechnol 1: 207-214.

Saraf S, Rathi R, Kaur CD and Saraf S (2011). Colloidosomes an advanced vesicular system in drug delivery. Asian Journal of Scientific Research 4: 1-15.

Utada AS, Lorenceau E, Link DR, Kaplan PD, Stone HA, and Weitz DA (2005). "Monodisperse double emulsions generated from a microcapillary device. Science 308: 537-541.

Velev OD, K. Furusawa and K. Nagayama (1996). Assembly of latex particles by using emulsion droplets as templates. 1. Microstructured hollow spheres. Langmuir 12: 2374-2384.

Vyas SP and RK Khar (2002). Targeted and controlled drug delivery- novel carrier systems. 1st Edn. CBS Publisher, New Delhi.

Walstra P (2003). Physical chemistry of foods. 1st Edn. Marcel Decker, New York, 223.

Yates, PD, GV Franks S. Biggs and GJ Jameson, (2005). Heteroaggregation with nanoparticles: effect of particle size ratio on optimum particle dose colloids surface. Physicochem Eng Aspects 255: 85-90.

Most read articles by the same author(s)