Page 73 - 《精细化工》2022年第3期

P. 73

第 3 期杜梦，等: 无载体水溶性聚卟啉纳米粒用于肿瘤的光动力治疗 ·495·

[27] EI Khouly M E, KANG E S, KAY K Y, et al. Silicon- [33] GUAN M R, GE J C, WU J Y, et al. Fullerene/photosensitizer
phthalocyanine-cored fullerene dendrimers: Synthesis and prolonged nanovesicles as highly efficient and clearable phototheranostics with
charge-separated states wim dendrimer generations[J]. Chemistry-A enhanced tumor accumulation for cancer therapy[J]. Biomaterials,
European Journal, 2007, 13(10): 2854-2863. 2016, 103: 75-85.
[28] MALDASEED S, MACHACEK M, ALFADLY W, et al. Water- [34] ZHENG N, XIE D, WANG C S, et al. Water-soluble, zwitterionic
soluble non-aggregating zincphthalocyanine and in vitro studies for poly-photosensitizers as carrier-free, photosensitizer-self-delivery
photodynamic therapy[J]. Chemical Communications, 2013, 49(95): system for in vivo photodynamic therapy[J]. ACS Applied Materials
11149-11151. & Interfaces, 2019, 11(47): 44007-44017.
[29] WU C ( 吴川 ). Synthesis and properties of porphyrin-cored [35] ZHENG N, ZHANG Z Y, KUANG J, et al. Poly (photosensitizers)
polypeptide as drug carrier for photodynamic theropy[D]. Zhenjiang: nanoparticles for enhanced in vivo photodynamic therapy by
Jiangsu University (江苏大学), 2016. interrupting the π-π stacking and extending circulation time[J]. ACS
[30] SHEN X M, ZHENG B Y, HUANG X R, et al. The first silicon( ) Ⅳ Applied Materials & Interfaces, 2019, 11(20): 18224-18232.
phthalocyanine-nucleoside conjugates with high photodynamic [36] HE J N, ZHENG N, XIE D, et al. Multicomponent polymerization
activity[J]. Dalton Transactions, 2013, 42(29): 10398-10403. toward biodegradable polymers with diverse responsiveness in tumor
[31] MITSUJNAGA M, OGAWA M, KOSAKA N, et al. Cancer microenvironments[J]. Polymer Chemistry, 2020, 11(6): 1198-1210.
cell-selective in vivo near infrared photoimmunotherapy targeting [37] WANG W H (王维虎), HE J N (何俊男), ZHENG Y B (郑玉斌),
specific membrane molecules[J]. Nature Medicine, 2011, 17(12): et al. Copper-catalyzed, three-component polymerization for the
1685-1691. synthesis of polyphosphonylamidines[J]. Acta Polymerica Sinica (高
[32] JIN J Q, ZHU Y C, ZHANG Z H, et al. Enhancing the efficacy of 分子学报), 2021, 52(9): 1129-1137.
photodynamic therapy through a porphyrin/poss alternating [38] BAI J P (白景佩), XU X (徐翔), ZHENG Y B (郑玉斌), et al.
copolymer[J]. Angewandte Chemie International Edition, 2018, Relationship between structure and singlet oxygen yield of poly-
57(50): 16354-16358. porphyrin[J]. Fine Chemicals (精细化工), 2021, 38(7): 1380-1385.

（上接第 479 页） Environmental Science (环境科学), 2021, 42(2): 883-890.
[76] WEN S H, CHEN L, LI W Q, et al. Insight into the characteristics, [86] IKHLAQ A, JAVED F, AKRAM A, et al. Synergic catalytic
removal, and toxicity of effluent organic matter from a pharmaceutical ozonation and electroflocculation process for the treatment of
wastewater treatment plant during catalytic ozonation[J]. Scientific veterinary pharmaceutical wastewater in a hybrid reactor[J]. Journal
Reports, 2018, 8(1): 9581. of Water Process Engineering, 2020, 38: 101597.
[77] YANG W L, WANG T, WU J. Preparation of Ni xO-Fe xO/ceramsite [87] MA F J (马富军), LI X Y (李新洋), ZONG B Y (宗博洋), et al.
catalyst and its application in advanced treatment of pharmaceutical Study on electrochemical heterogeneous catalytic ozonation process
wastewater[J]. American Journal of Chemical Engineering, 2020, for treatment of amantadine pharmaceutical wastewater[J]. China
8(4): 96-96. Environmental Science (中国环境科学), 2018, 38(10) : 3713-3719.
[78] MALIK S, KHAN S, GHOSH P, et al. Treatment of pharmaceutical [88] ZHAN J H, LI Z X, YU G, et al. Enhanced treatment of
industrial wastewater by nano-catalyzed ozonation in a semi-batch pharmaceutical wastewater by combining three-dimensional
reactor for improved biodegradability[J]. Science of the Total electrochemical process with ozonation to in situ regenerate granular
Environment, 2019, 678: 114-122. activated carbon particle electrodes[J]. Separation and Purification
[79] JI Y P, PAN Z C, YUAN D H, et al. Advanced treatment of the Technology, 2018, 208: 12-18.
antibiotic production wastewater by ozone/zero-valent iron [89] ESPEJO A, AGUINACO A, AMATA A M, et al. Some ozone
process[J]. Clean-Soil, Air, Water: A Journal of Sustainability and advanced oxidation processes to improve the biological removal of
Environmental Safety, 2018, 46(3): 1700661-1700666. selected pharmaceutical contaminants from urban wastewater[J].
[80] HUANG Y X, JIANG J W, MA L M, et al. Iron foam combined Journal of Environmental Science and Health. Part A, Toxic/Hazardous
ozonation for enhanced treatment of pharmaceutical wastewater[J]. Substances & Environmental Engineering, 2014, 49(4): 410-421.
Environmental Research, 2020, 183: 109205. [90] MARQUEZ G, RODRIGUEZ E M, MALDONADO M I, et al.
[81] ALPATOVA A L, DAVIES S H, MASTEN S J. Hybrid ozonation- Integration of ozone and solar TiO 2-photocatalytic oxidation for the
ceramic membrane filtration of surface waters: The effect of water degradation of selected pharmaceutical compounds in water and
characteristics on permeate flux and the removal of DBP precursors, wastewater[J]. Separation and Purification Technology, 2014, 136:
dicloxacillin and ceftazidime[J]. Separation and Purification Technology, 18-26.
2013, 107(4): 179-186. [91] YANG W L (杨文玲), WANG T (王坦). Advanced treatment of
[82] FUJIOKA T, HOANG A T, OKUDA T, et al. Water reclamation pharmaceutical wastewater by catalytic ozonation-MBR combined
using a ceramic nanofiltration membrane and surface flushing with process[J]. Applied Chemical Industry (应用化工), 2021, 50(3):
ozonated water[J]. International Journal of Environmental Research 708-711.
and Public Health, 2018, 15(4): 799. [92] LI X K (李新凯), YANG L (杨磊). Advanced treatment of antibiotics
[83] CHEN L, LI J B, FU W Y, et al. Ceramic membrane based hybrid wastewater by ICB and catalytic ozonation[J]. China Water &
process for the upgrade of rural water treatment plants: A pilot Wastewater (中国给水排水), 2017, 33(9): 89-91.
study[J]. Water Environment Research: A research publication of the [93] WEI J (魏健), HE J Y (何锦垚), SONG Y H (宋永会), et al.
Water Environment Federation, 2021, 93(1): 75-83. Advanced treatment of antibiotic wastewater by catalytic ozonation
[84] FAN X J, TAO Y, WANG L Y, et al. Performance of an integrated combined with BAF process and an analysis of the bacterial
process combining ozonation with ceramic membrane ultra-filtration community structures[J]. Acta Scientiae Circumstantiae (环境科学学
for advanced treatment of drinking water[J]. Desalination, 2014, 报), 2020, 40(6) : 2090-2100.
335(1): 47-54. [94] YANG L Y, SHENG M S, LI Y J, et al. A hybrid process of Fe-based
[85] XIE X Y (谢新月), XU J J (许建军), ZHANG S H (张少华), et al. catalytic ozonation and biodegradation for the treatment of industrial
Characteristics and removal mechanism of an electro-hybrid wastewater reverse osmosis concentrate[J]. Chemosphere, 2020, 238:
ozonation-coagulation system in the treatment of organic matters[J]. 124639.

68 69 70 71 72 73 74 75 76 77 78