Selective Binding pH Responsive Liposomes with Phenylboronic Acid for Drug Delivery

doi:10.19894/j.issn.1000-0518.220385

Chinese Journal of Applied Chemistry ›› 2023, Vol. 40 ›› Issue (6): 860-870.DOI: 10.19894/j.issn.1000-0518.220385

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Selective Binding pH Responsive Liposomes with Phenylboronic Acid for Drug Delivery

Xin-Tao XIE¹^,², Sang-Ni JIANG¹^,², Xi-Fei YU¹^,²()

^1.Laboratory of Polymer Composites Engineering，Changchun Institute of Applied Chemistry，Chinese Academy of Science，Changchun 130022，China
^2.University of Science and Technology of China，Hefei 230026，China

Received:2022-11-24 Accepted:2023-03-13 Published:2023-06-01 Online:2023-06-27
Contact: Xi-Fei YU
About author:xfyu@ciac.ac.cn
Supported by:
the National Natural Science Foundation of China(21674109)

1. .pdf(124KB)

Abstract

Abstract:

A polyethylene glycol （PEG） derivative PBA-PEG-SA， which connects phenylboronic acid （PBA） with an amide bond at one end and stearic acid （SA） with an ester bond at the other end， is synthesized by substitution reaction and esterification reaction. And a liposome with pH response characteristics is prepared by co-assembly of PBA-PEG-SA with distearyl choline phosphate （DSCP） and cholesterol （CH）. When PBA-PEG-SA， cholesterol and DSCP are assembled at a mass ratio of 1∶3∶10， the particle size of the prepared liposome is 115 nm， and it could maintain good particle size stability within 20 d. In addition， the liposome has good biocompatibility. When the concentration reaches 800 μg/mL， the survival rate of mouse embryonic fibroblast （NIH-3T3）and hepatoma cell （HepG2） can reach more than 90%. At the same time， after loading doxorubicin （Dox）， compared with DSCP liposomes （Lip/Dox）， Fru/PBA/Lip/Dox liposomes modified with PBA and coated with Fru can effectively enhance the cytotoxicity of HepG2， reduce the toxicity to normal cells NIH-3T3， and improve the endocytosis of cells to drug-loaded liposomes due to the selective binding of phenylboronic acid and fructose. Therefore， the liposomes co-assembled by DSCP and PBA-PEG-SA have good pH response performance and enhance the enrichment ability of liposomes in tumor tissue， which will have good application prospects in the field of tumor therapy.

Key words: pH response, Phenylboronic acid, Co-assembled liposomes, Drug delivery

CLC Number:

O632

Xin-Tao XIE, Sang-Ni JIANG, Xi-Fei YU. Selective Binding pH Responsive Liposomes with Phenylboronic Acid for Drug Delivery[J]. Chinese Journal of Applied Chemistry, 2023, 40(6): 860-870.

Figures/Tables 8

Fig.1 Schematic illustration of pH responsive liposome administration based on selective binding of phenylboronic acid

Fig.2 1H NMR （A） and FT-IR （B） spectra of PBA-PEG-SA and PEG-SA

Table 1 The size， PDI and Zeta potential of Lip， PEG/Lip， Fru/PEG/Lip， PBA/Lip and Fru/PBA/Lip

Sample	Size/nm	PDI	Zeta potential/mV
Lip	120.0±0.6	0.08±0.02	-11.6±2.1
PEG/Lip	114.4±0.5	0.15±0.06	-13.2±1.2
Fru/PEG/Lip	/	/	-12.9±1.5
PBA/Lip	116.7±1.2	0.16±0.04	-12.6±1.7
Fru/PBA/Lip	115.4±0.9	0.15±0.05	-16.8±1.9

Table 2 The DLC and DLE of Lip， PEG/Lip， PBA/Lip and Fru/PBA/Lip

Sample	DLC/%	DLE/%
Lip	15.5±1.7	87.5±5.3
PEG/Lip	18.2±2.1	89.6±6.3
PBA/Lip	18.6±2.8	91.2±4.2
Fru/PBA/Lip	18.6±2.8	91.2±4.2

Fig.4 （A） The particle size change of Fru/PBA/Lip/Dox liposomes within 20 d；（B） The drug release curve of Fru/PBA/Lip/Dox liposomes in vitro in buffer solution with pH=6.5 and 7.4

Fig.5 Cell survival rates of Lip，PEG/Lip，PBA/Lip and Fru/PBA/Lip liposomes in NIH-3T3 cells （A） and HepG2 cells （B）， respectively； Hemolysis phenomenon （C） and corresponding hemolysis percentage （D） after incubating mice red blood cells with different concentrations of PEG/Lip and Fru/PBA/Lip liposomes for 2 h

Fig.6 Cell survival rates of Lip/Dox， PEG/Lip/Dox， PBA/Lip/Dox and Fru/PBA/Lip/Dox liposomes in NIH-3T3 cells （A） and HepG2 cells （B）， respectively； The intracellular fluorescence intensity （C） and average fluorescence intensity （D） of PBA/Lip/Dox and Fru/PBA/Lip/Dox liposomes incubated with NIH-3T3 cells and HepG2 cells for 4 h were analyzed by flow cytometry； Fluorescence microscopy of Lip/Dox （i）， PEG/Lip/Dox （ii）， PBA/Lip/Dox （iii） and Fru/PBA/Lip/Dox （iv） liposomes incubated in NIH-3T3 cells （E） and HepG2 cells （F） for 4 h， respectively（scale bar： 20 μm）

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Selective Binding pH Responsive Liposomes with Phenylboronic Acid for Drug Delivery

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