PURPOSE: To evaluate the growth and adhesion characteristics in vitro of genetically modified, basic fibroblast growth factor-producing fibroblasts on platinum detachable coils. MATERIALS AND METHODS: Coils of two sizes were coated with laminin, poly-L-lysine, fibronectin, and type I and type IV collagen and were cultured with basic fibroblast growth factor-secreting fibroblasts. Type I collagen strands were inserted in the lumen of some coils. Cellular proliferation and adherence during passage of coils through microcatheters were studied with both light and scanning electron microscopy. Growth factor concentration in the culture medium was measured. RESULTS: Rapid cellular proliferation was noted on all coated coils except those coated with type IV collagen. Proliferation on uncoated coils was slightly slower than on most coated coils, although confluent cell layers were present on uncoated larger-diameter coils within 48 hours. Cells had a marked propensity to grow between the primary coil windings into the coil lumen, except in coils that contained collagen filaments. Passage through microcatheters caused widespread stripping of cells from the outer surface of coils, especially the uncoated samples. Viable cells remained in the coil lumen. Supernatant contained high concentrations of growth factor. CONCLUSION: Platinum embolic coils are a promising mechanism of cell delivery for stimulation of scar formation or other desirable biologic effects.
PURPOSE: To evaluate the growth and adhesion characteristics in vitro of genetically modified, basic fibroblast growth factor-producing fibroblasts on platinum detachable coils. MATERIALS AND METHODS: Coils of two sizes were coated with laminin, poly-L-lysine, fibronectin, and type I and type IV collagen and were cultured with basic fibroblast growth factor-secreting fibroblasts. Type I collagen strands were inserted in the lumen of some coils. Cellular proliferation and adherence during passage of coils through microcatheters were studied with both light and scanning electron microscopy. Growth factor concentration in the culture medium was measured. RESULTS: Rapid cellular proliferation was noted on all coated coils except those coated with type IV collagen. Proliferation on uncoated coils was slightly slower than on most coated coils, although confluent cell layers were present on uncoated larger-diameter coils within 48 hours. Cells had a marked propensity to grow between the primary coil windings into the coil lumen, except in coils that contained collagen filaments. Passage through microcatheters caused widespread stripping of cells from the outer surface of coils, especially the uncoated samples. Viable cells remained in the coil lumen. Supernatant contained high concentrations of growth factor. CONCLUSION:Platinumembolic coils are a promising mechanism of cell delivery for stimulation of scar formation or other desirable biologic effects.
Authors: Daying Dai; Yong Hong Ding; Mark A Danielson; Ramanathan Kadirvel; Debra A Lewis; Harry J Cloft; David F Kallmes Journal: AJNR Am J Neuroradiol Date: 2005 Nov-Dec Impact factor: 3.825
Authors: Y Murayama; F Viñuela; Y Suzuki; Y Akiba; A Ulihoa; G R Duckwiler; Y P Gobin; H V Vinters; M Iwaki; T Abe Journal: AJNR Am J Neuroradiol Date: 1999 Nov-Dec Impact factor: 3.825
Authors: T Liebig; H Henkes; S Fischer; W Weber; E Miloslavski; W Mariushi; S Brew; D Kühne Journal: Interv Neuroradiol Date: 2004-10-22 Impact factor: 1.610
Authors: F J Hans; T Krings; W Möller-Hartmann; R Thiex; J Pfeffer; K Scherer; A Brunn; H Dreeskamp; K P Stein; A Meetz; J M Gilsbach; A Thron Journal: Neuroradiology Date: 2003-05-22 Impact factor: 2.804