Gene/Protein
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Drug
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Compound
Pivot Concepts:
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Target Concepts:
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Query: UMLS:C0019204 (
hepatocellular carcinoma
)
71,386
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Chemoembolization has become the preferred treatment for patients with inoperable, hypervascular hepatic malignancies in the Far East, but controversial elsewhere. In vivo microscopy in addition to other experimental procedures are used in this presentation to better understand the mechanisms involved in chemoembolization. In chemoembolization Lipiodol acts as a contrast material, a vehicle for chemotherapy and an embolic agent. Although not optimal, Lipiodol injected into the hepatic artery, traverses the peribiliary plexus to the portal veins resulting in a dual embolization. Chemoembolization creates ischemia, slows arterial flow and increases the contact time between the infusate and the neoplasms, increasing the tumor cell kill. However, the vascular occlusion also produces infarction and fibrosis compounding the already existing cirrhosis frequently associated with
hepatocellular carcinoma
. Lipiodol/ethanol (3:1) injected into the segmental or lobar hepatic artery supplying the neoplasm also gains access to the associated portal venous branches causing focal ablation. This preoperative approach is easier to perform than direct portal vein occlusion, with less parenchymal damage and comparable hypertrophy of the remnant liver frequently necessary for adequate hepatic function following resection. Polymer-drug conjugates, e.g. PG-
TXL
, have considerable potential for intra-arterial delivery especially with the dramatic increase in concentration of the drug in the tumor and its efficacy. Using in vivo microscopy especially with green fluorescent protein (GFP) gene as an efficient and non-toxic tumor cell marker, the events leading to hepatic metastases can be documented which will serve to better evaluate these varied techniques of chemoembolization.
...
PMID:Hepatic chemoembolization: clinical and experimental correlation. 1092 54
Human
hepatocellular carcinoma
(
HCC
) is one of the major causes of death worldwide. Targeted uptake of therapeutic agent in the cell-, tissue- or disease-specific manner represents a potential technology for the treatment of
HCC
. A new docetaxel-loaded
hepatoma
-targeted solid lipid nanoparticle (tSLN) was designed and prepared with galactosylated dioleoylphosphatidyl ethanolamine. The cellular cytotoxicity, cellular uptake, subcellular localization, in vivo toxicity, therapeutic effect, biodistribution and histology of tSLNs were investigated. The tSLNs showed the particle size about 120nm with encapsulation efficiency >90%, a low burst effect within the first day and a sustained release for the next 29 days in vitro. Cytotoxicity of tSLNs against
hepatocellular carcinoma
cell line BEL7402 was superior to
Taxotere
and non-targeted SLNs (nSLNs). The tSLNs also showed better tolerant and antitumor efficacy in murine model bearing
hepatoma
compared with
Taxotere
or nSLNs. The studies on cellular uptake and biodistribution indicated that the better antitumor efficacy of tSLNs was attributed to both the increased accumulation of drug in tumor and more cellular uptake by
hepatoma
cells. The histology demonstrated that tSLNs had no detrimental effect on both healthy liver and liver with fibrosis. These results implied that this targeted nanocarrier of docetaxel could enhance its antitumor effect in vivo with low systemic toxicity for the treatment of locally advanced and metastatic
HCC
.
...
PMID:The performance of docetaxel-loaded solid lipid nanoparticles targeted to hepatocellular carcinoma. 1885 81
Mesoporous silica nanomaterial is one of the most promising candidates as drug carrier for cancer therapy. Herein, in vitro and in vivo study of silica nanorattle (SN) with mesoporous and rattle-type structure as a drug delivery system was first reported. Hydrophobic antitumor drug docetaxel (Dtxl) was loaded into the PEGylated silica nanorattle (SN-PEG) with a diameter of 125 nm via electrostatic absorption. In human liver cancer cell Hep-G2, the half-maximum inhibiting concentration (IC(50)) of silica nanorattle encapsulated docetaxel (SN-PEG-Dtxl) was only 7% of that of free Dtxl at 72 h. In vivo toxicity assessment showed that both nanocarrier of silica nanorattle (40 mg/kg, single dose) and SN-PEG-Dtxl (20 mg/kg of Dtxl, three doses) had low systematic toxicity in healthy ICR mice. The SN-PEG-Dtxl (20 mg/kg, intravenously) showed greater antitumor activity with about 15% enhanced tumor inhibition rate compared with
Taxotere
on the marine
hepatocarcinoma
22 subcutaneous model. The results prove that the SN-PEG-Dtxl has low toxicity and high therapy efficacy, which provides convincing evidence for the silica nanorattle as a promising candidate for a drug delivery system.
...
PMID:In vivo delivery of silica nanorattle encapsulated docetaxel for liver cancer therapy with low toxicity and high efficacy. 2097 87
