Magnetic lamellar hydroxyapatite (ML-HA) nanoparticles were synthesized by a template-assisted selfassembly process. The as-prepared ML-HA nanoparticles self-assembled under different conditions were characterized by XRD, TEM, cytotoxicity assessment, and DNA-loading and transfection efficiency measurements.
We found that the structure and morphology of ML-HA were controlled by self-assembly conditions. The ML-HA synthesized in this work exhibited good biocompatibility. The DNA-loading capacity and z-potential of ML-HA were much lower in comparison to bare lamellar HA (L-HA) without magnetic nanoparticles. Despite that, the ML-HA with good lamellar structure showed 47% higher transfection efficiency than L-HA. Results suggested that the ordered lamellar structure is a key factor in controlling transfection efficiency and magnetization is an effective way of improving the transfection efficiency of lamellar HA. Mechanisms were proposed to interpret these experimental results. It is demonstrated that the ML-HA may be a promising gene vector to deliver DNA into the cells effectively and safely.

1 T. Welzel, "Transfection of cells with custom-made calcium phosphate nanoparticles coated with DNA" 14 : 2213-2217, 2004

2 A. Li, "The use of layered double hydroxides as DNA vaccine delivery vector for enhancement of antimelanoma immune response" 32 : 469-477, 2011

3 J. Jin, "The inhibition of lamellar hydroxyapatite and lamellar magnetic hydroxyapatite on the migration and adhesion of breast cancer cells" 25 : 1025-1031, 2014

4 B. -Q. Lu, "Synthesis and characterization of magnetic iron oxide/calcium silicate mesoporous nanocomposites as a promising vehicle for drug delivery" 4 : 6968-6973, 2012

5 G. Zuo, "Synthesis and characterization of laminated hydroxyapatite/chitosan nanocomposites" 64 : 2126-2128, 2010

6 G. Zuo, "Synthesis and characterization of a lamellar hydroxyapatite/DNA nanohybrid" 126 : 470-475, 2011

7 M. J. Masarudin, "Successful transfer of plasmid DNA into in vitro cells transfected with an inorganic plasmideMg/Al-LDH nanobiocomposite material as a vector for gene expression" 20 : 045602-, 2009

8 M. Kawase, "Protective effect of montmorillonite on plasmid DNA in oral gene delivery into small intestine" 27 : 2049-2051, 2004

9 G. Zuo, "Preparation and characterization of a novel laminated magnetic hydroxyapatite for application on gene delivery" 68 : 225-227, 2012

10 C. Perez, "Poly(lactic acid)-poly(ethylene glycol) nanoparticles as new carriers for the delivery of plasmid DNA" 75 : 211-224, 2001

11 H. -C. Wu, "Novel magnetic hydroxyapatite nanoparticles as non-viral vectors for the glial cell line-derived neurotrophic factor gene" 20 : 67-77, 2010

12 D. Olton, "Nanostructured calcium phosphates (NanoCaPs) for non-viral gene delivery:Influence of the synthesis parameters on transfection efficiency" 28 : 1267-1279, 2007

13 H. Tian, "Nanoparticles for gene delivery" 9 : 2034-2044, 2013

14 F. H. Lin, "Modified montmorillonite as vector for gene delivery" 27 : 3333-3338, 2006

15 F. Scherer, "Magnetofection: enhancing and targeting gene delivery by magnetic force in vitro and in vivo" 9 : 102-109, 2002

16 F. Chen, "Magnetic nanocomposite of hydroxyapatite ultrathin nanosheets/Fe3O4 nanoparticles: microwaveassisted rapid synthesis and application in pH-responsive drug release" 1 : 1074-1081, 2013

17 F. Caruso, "Magnetic coreeshell particles:preparation of magnetite multilayers on polymer latex microspheres" 11 : 950-953, 1999

18 L. Huang, "Liposomal gene delivery: a complex package" 15 : 620-, 1997

19 Z. P. Xu, "Layered double hydroxide nanoparticles as cellular delivery vectors of supercoiled plasmid DNA" 2 : 163-174, 2007

20 J. H. Choy, "Inorganic-biomolecular hybrid nanomaterials as a genetic molecular code system" 16 : 1181-1189, 2004

21 Z. P. Xu, "Inorganic nanoparticles as carriers for efficient cellular delivery" 61 : 1027-1040, 2006

22 J. H. Choy, "Inorganic layered double hydroxides as nonviral vectors" 39 : 4042-4045, 2000

23 M. T. Calejo, "In vitro cytotoxicity of a thermoresponsive gel system combining ethyl(hydroxyethyl) cellulose and lysine-based surfactants" 102 : 682-686, 2013

24 J. Dobson, "Gene therapy progress and prospects: magnetic nanoparticle-based gene delivery" 13 : 283-287, 2006

25 H. Hu, "Functionalized layered double hydroxide nanoparticles conjugated with disulfide-linked polycation brushes for advanced gene delivery" 24 : 968-978, 2013

26 J. Klesing, "Freeze-dried cationic calcium phosphate nanorods as versatile carriers of nucleic acids (DNA, siRNA)" 22 : 199-204, 2012

27 K. Ladewig, "Efficient siRNA delivery to mammalian cells using layered double hydroxide nanoparticles" 31 : 1821-1829, 2010

28 N. Vlachy, "Determining the cytotoxicity of catanionic surfactant mixtures on HeLa cells" 70 : 278-280, 2009

29 N. Lewinski, "Cytotoxicity of nanoparticles" 4 : 26-49, 2008

30 K. Ladewig, "Controlled preparation of layered double hydroxide nanoparticles and their application as gene delivery vehicles" 48 : 280-289, 2010

31 S. Li, "Cellular uptake and gene delivery using layered double hydroxide nanoparticles" 1 : 61-68, 2013

32 H. Bi, "Carbon fiber aerogel made from raw cotton: a novel, efficient and recyclable sorbent for oils and organic solvents" 25 : 5916-5921, 2013

33 Y. Liang, "Biocompatible core-shell nanoparticle-based surface-enhanced Raman scattering probes for detection of DNA related to HIV gene using silica-coated magnetic nanoparticles as separation tools" 72 : 443-449, 2007

34 Y. Liu, "An efficient calcium phosphate nanoparticle-based nonviral vector for gene delivery" 6 : 721-727, 2011

35 J. Wang, "Amino-functionalized Fe3O4@SiO2 coreeshell magnetic nanomaterial as a novel adsorbent for aqueous heavy metals removal" 349 : 293-299, 2010