The effect of molecular weight, drug load, and charge of gelatin-MTX conjugates on growth inhibition of HL-60 leukemia cells
- PMID: 18975058
- DOI: 10.1007/s11095-008-9746-5
The effect of molecular weight, drug load, and charge of gelatin-MTX conjugates on growth inhibition of HL-60 leukemia cells
Abstract
Purpose: Gelatin-methotrexate conjugates (G-MTX) with known molecular weight (MW), drug load, and charge were prepared and evaluated for growth inhibition on leukemia cells.
Methods: Gelatin (34 to 171 kDa) was reacted with a carbodiimide to prepare G-MTX with high (G-MTX-H) and low (G-MTX-L) drug loads. Cationic conjugates were prepared by ethylenediamine modification. MTX:gelatin molar ratios were determined spectrophotometrically. Isoelectric focusing electrophoresis (IEF) and turbidity were used to measure isoelectric points (IEP). Growth inhibition profiles and IC50 values were determined on HL-60 cells using a modified MTT assay.
Results: IC50 values of anionic G-MTX-L (drug loads 0.5:1 to 2.2:1) increased linearly from 46 to 180 nM with MW. But, IC50 values for anionic G-MTX-H (drug loads 7.4:1 to 25:1) showed little, if any, MW dependence and were about two times higher. IC50 values for cationic G-MTX-L ranged from 770 to 2,900 nM and the relationship with MW was non-linear.
Conclusions: The growth inhibition ranking was MTX>anionic G-MTX-L>anionic G-MTX-H>cationic G-MTX-L. High drug load may hinder lysosomal enzyme degradation and drug release and contribute to suppression of the MW effect observed with G-MTX-L. A mechanism change is suggested as the cationic conjugates increase to the highest MW.
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