Subscribe to RSS
DOI: 10.1055/s-0033-1351313
Gd3+-DTPA-bis (N-methylamine) – Anionic Linear Globular Dendrimer-G1; A More Efficient MRI Contrast Media
Publication History
received 23 January 2013
accepted 28 May 2013
Publication Date:
05 December 2013 (online)
Abstract
By advancing of molecular imaging techniques, magnetic resonance imaging (MRI) is becoming an increasingly important tool in early diagnosis. Researchers have found new ways to increase contrast of MRI images.Therefore some types of drug known as contrast media are produced. Contrast media improve the visibility of internal body structures in MRI images. Gadodiamide (Omniscan®) is one of these contrast media which is produced commercially and used clinically. In this study Gadodiamide was first synthesized and then qualitative and quantitative methods were carried out to ensure the proper synthesis of this drug then to increase the efficiency of this contrast medium use dendrimer that is one kind of nano particle. This dendrimer has a polyethylene glycol (PEG) core and citric acid branches. After dendrimer attached to Gadodiamide to ensure the proper efficient connection between them the stability studies were carried out and cytotoxicity of the drug was evaluated. Finally, after ensuring the non-toxicity of the drug, in vivo studies (injected into mice) MR imaging was performed to examine the impact of synthesis drug on the resolution of image.
The result obtained from this study demonstrated that the attachment of Gadodiamide to dendrimer reduces its cytotoxicity and also improved resolution of image. Also the new contrast media (Gd3+-DTPA- bis [N-methylamine] – Dendrimer) – unlike Omniscan® – is biodegradable and able to enter the HEPG2 cell line. The results confirm the hypothesis that using dendrimer to synthesize this new nano contrast medium increases its effectiveness.
-
References
- 1 Oghabian M, Farahbakhsh N. Potential Use of Nanoparticle Based Contrast Agents in MRI to Detect Selected Molecular Targets. J Biomed Nanotechnol 2010; 6: 3
- 2 Rajan S. MRI Hardware System Component, MRI: A Conceptual Overview. Springer; English 1998: 25-40
- 3 Strijkers G. MRI contrast agents: current status and future perspectives. Anticancer Agents Med Chem 2007; 7: 291-305
- 4 Reddy J, Prasad V. MRI Contrast Agent, Step by Step MRI. Jaypee Brothers Publishers; 2005: 124-133
- 5 Su M, Mühler A, Lao X et al. Tumor characterization with dynamic contrast-enhanced MRI using MR Contrast agents of various molecular weights. J ISMRM. 1998. 39. 259-269
- 6 Bar B, Yacoby I, Benhar I. Killing cancer cells by targeted drug-carrying phage nanomedicines. BMC Biotechnol 2008; 8: 37
- 7 Geraldes C, Laurent S. Classification and basic properties of contrast agents for magnetic resonance imaging. Contrast Media Mol Imaging 2009; 4: 1-23
- 8 Zhang S, Wu K, Sherry AD. A Novel pH Sensitive MRI Contrast Agent. Angew Chem Int Ed Engl 1999; 38: 3192-3194
- 9 Frechet JM, Tomalia DA. Introduction to the Dendritic State. Dendrimers and other dendritic polymers 2002; 1-44
- 10 Amanlou M. Gd3+-DTPA-DG: novel nanosized dual anticancer and molecular imaging agent. Int J Nanomedicine 2011; 6: 747-763
- 11 Klajnert B, Bryszewska M. Dendrimers: properties and applications. Acta Biochim Pol 2001; 48: 199-208
- 12 Jansen J, Meijer E, Ellen M et al. The Dendritic Box: Shape-Selective Liberation of Encapsulated Guests. J Am Chem Soc 1995; 117: 4417-4418
- 13 Watkins M, Sayed-Sweet Y, Klimash W et al. Dendrimers with Hydrophobic Cores and the Formation of Supramolecular Dendrimer-Surfactant Assemblies. Langmuir 1997; 13: 3136-3141
- 14 Hawker C, Wooley K, Fréchet J. Unimolecular micelles and globular amphiphiles: dendritic macromolecules as novel recyclable solubilization agents. Chem Soc Perkin Trans 1993; 1: 1287-1297
- 15 Fischer M, Vögtle F. Dendrimers: From Design to Application – a Progress Report. Angewandte Chemie International 1999; 38: 884-905
- 16 Lee A, MacKay J, Fréchet J et al. Designing dendrimers for biological applications. Nature Biotechnology 2005; 23: 1517-1526
- 17 Namazi H, Adeli M. Dendrimers of citricacid and poly [ethylene glycol] as the new drug-delivery agents. Biomaterials 2005; 26: 1175-1183
- 18 Valk J, Algra P, Hazenherg C et al. A double-blind, comparative study of gadodiamide injection and gadopentetate dimeglumine in MRI of the central nervous system. Neuroradiology 1993; 35: 173-177
- 19 Kobayashi H, Sato N, Hiraga A et al. 3D-micro-MR angiography of mice using macromolecular MR contrast agents with polyamidoamine dendrimer core with reference to their pharmacokinetic properties. Magn Reson Med 2001; 45: 454-460
- 20 Kobayashi H, Kawamotob S, Bernardoc M et al. Delivery of gadolinium-labeled nanoparticles to the sentinel lymph node: Comparison of the sentinel node visualization and estimations of intra-nodal gadolinium concentration by the magnetic resonance imaging. J Control Release 2006; 111: 343-351
- 21 Haririan K, Shafiee Alavidjeh M, Khorramizadeh M et al. Anionic linear-globular dendrimer-cis-platinum [II] conjugates promote cytotoxicity in vitro against different cancer cell lines. Int J Nanomedicine 2010; 5: 63-75
- 22 Emanuele A, Attwood D. Dendrimer-drug interactions. Adv Drug Deliv Rev 2005; 57: 2147-2162
- 23 Jain K, Kesharwani P, Gupta U. Dendrimer toxicity: Let’s meet the challenge. International Journal of Pharmaceutics. Int J Pharm 2010; 394: 122-142
- 24 Namazi H, Adeli M. Novellinear-globularthermoreversible hydrogel ABA type copolymers from dendritic citric acid as the A blocks and poly[ethyleneglycol] as the B block. J European Polymer 2003; 39: 1491-1500
- 25 Shafiee Alavidjeh M, Haririan I, Khorramizadeh M et al. Anionic linear-globular dendrimers: biocompatible hybrid materials with potential uses in nanomedicine. J Materials Science: Materials in Medicine. J Mater Sci Mater Med 2010; 21: 1121-1133
- 26 Max Merkle E, Marshall Dale B, Barboriak D. Gain in Signal-to-Noise for First-Pass Contrast-Enhanced Abdominal MR Angiography at 3 Tesla over Standard 1.5 Tesla: Prediction with a Computer Model. Acad Radiol 2007; 14: 795-803