TY - JOUR
T1 - Enriching lipid nanovesicles with short-chain glucosylceramide improves doxorubicin delivery and efficacy in solid tumors
AU - Van Lummel, Menno
AU - Van Blitterswijk, Wim J.
AU - Vink, Stefan R.
AU - Veldman, Robert Jan
AU - Van Der Valk, Martin A.
AU - Schipper, Debby
AU - Dicheva, Bilyana M.
AU - Eggermont, Alexander M.M.
AU - Ten Hagen, Timo L.M.
AU - Verheij, Marcel
AU - Koning, Gerben A.
PY - 2011/1
Y1 - 2011/1
N2 - For amphiphilic anticancer drugs, such as the anthracyclin doxorubicin (Dox), uptake by tumor cells involves slow diffusion across the plasma membrane, a limiting factor in clinical oncology. Previously, we discovered that preinsertion of short-chain sphingolipids such as N-octanoyl-glucosylceramide (GC) in the tumor cell membrane enhances cellular Dox uptake. In the present study, we apply this strategy in vitro and in vivo by coadministering GC and Dox in a lipid nanovesicle (LNV). GC enrichment of Dox-LNVs strongly enhanced in vitro cytotoxicity toward B16 melanoma and A431 carcinoma, as evidenced by 6-fold decreased IC50 values compared with Dox-LNVs. This correlated with enhanced cellular Dox uptake observed by confocal microscopy. Intravital optical imaging in window chamber-bearing mice with orthotopically implanted B16 melanoma demonstrated enhanced GC-mediated Dox delivery to tumor cells. Treatment of nude mice bearing human A431 xenografts with 6 mg/kg GC-Dox-LNVs almost doubled the tumor growth delay compared with Dox-LNVs. A second administration of 5 mg/kg after 3 d induced even 3-fold delay in tumor growth, while no systemic toxicity was found. GC-enriched Dox-LNVs displayed superior in vitro and in vivo antitumor activity, without systemic toxicity. This new drug delivery concept, aiming at increased membrane permeability for amphiphilic drugs, provides an opportunity to improve cancer chemotherapy.
AB - For amphiphilic anticancer drugs, such as the anthracyclin doxorubicin (Dox), uptake by tumor cells involves slow diffusion across the plasma membrane, a limiting factor in clinical oncology. Previously, we discovered that preinsertion of short-chain sphingolipids such as N-octanoyl-glucosylceramide (GC) in the tumor cell membrane enhances cellular Dox uptake. In the present study, we apply this strategy in vitro and in vivo by coadministering GC and Dox in a lipid nanovesicle (LNV). GC enrichment of Dox-LNVs strongly enhanced in vitro cytotoxicity toward B16 melanoma and A431 carcinoma, as evidenced by 6-fold decreased IC50 values compared with Dox-LNVs. This correlated with enhanced cellular Dox uptake observed by confocal microscopy. Intravital optical imaging in window chamber-bearing mice with orthotopically implanted B16 melanoma demonstrated enhanced GC-mediated Dox delivery to tumor cells. Treatment of nude mice bearing human A431 xenografts with 6 mg/kg GC-Dox-LNVs almost doubled the tumor growth delay compared with Dox-LNVs. A second administration of 5 mg/kg after 3 d induced even 3-fold delay in tumor growth, while no systemic toxicity was found. GC-enriched Dox-LNVs displayed superior in vitro and in vivo antitumor activity, without systemic toxicity. This new drug delivery concept, aiming at increased membrane permeability for amphiphilic drugs, provides an opportunity to improve cancer chemotherapy.
KW - Cell membrane permeability
KW - Chemotherapy
KW - Liposome
KW - Nanomedicine
KW - Short-chain sphingolipid
UR - http://www.scopus.com/inward/record.url?scp=79251547946&partnerID=8YFLogxK
U2 - 10.1096/fj.10-163709
DO - 10.1096/fj.10-163709
M3 - Article
C2 - 20876209
AN - SCOPUS:79251547946
SN - 0892-6638
VL - 25
SP - 280
EP - 289
JO - FASEB Journal
JF - FASEB Journal
IS - 1
ER -