Research status and trends of nanotechnology in improving photodynamic therapy for hypoxic tumors

doi:10.12307/2026.384

Abstract

Abstract: BACKGROUND: Photodynamic therapy, a novel tumor treatment, is limited by the hypoxic tumor microenvironment. Nanotechnology-based oxygen regulation strategies offer a novel approach to overcoming this bottleneck.
OBJECTIVE: To systematically analyze the current status of nanotechnology research in improving photodynamic therapy for hypoxic solid tumors using bibliometric methods, identify hot topics in the field, and predict future development directions.
METHODS: Using the Web of Science Core Collection database as the data source, we retrieved relevant papers and reviews on the use of nanotechnology in regulating tumor hypoxia and enhancing the efficacy of photodynamic therapy from 2016 to 2025. Visualizations of the Web of Science Core Collection database categories, publication trends, countries, institutions, authors, co-citations, and keywords were analyzed using Excel, CiteSpace, VOSviewer, and Bibliometrix.
RESULTS AND CONCLUSION: A total of 1 879 articles were included, with “nanoscience & nanotechnology” being the core category. The number of articles published in the field of nanotechnology-based photodynamic therapy for hypoxic tumors continued to grow from 2016 to 2022, with a brief decline in 2023 before recovering. China is the leading country in the field of nanotechnology-based photodynamic therapy for hypoxic tumors. The Chinese Academy of Sciences has the highest number of publications, while Liu Zhuang from Soochow University has the highest number of publications. The 2016 publication by ZHOU ZJ et al. in Chemical Society Reviews has the highest total citation count. This research area focuses on cancer treatment and microenvironment-responsive phototherapy strategies using nanomaterials. The keywords “photodynamic therapy” and “nanoparticles” appear most frequently. Bibliometric analysis indicates that nanotechnology has advantages in improving the efficacy of photodynamic therapy for hypoxic tumors. Related research demonstrates good efficacy and safety, and future research is likely to focus on combination strategies with immunotherapy.

Key words: tumor, hypoxia, photodynamic therapy, nanomedicine, bibliometrics, visual analysis

CLC Number:

Dilida·Bahetikelede, Zhou Xin, Wang Xinyi, Zeng Zhihan, Wang Liqiong, Hu Danrong. Research status and trends of nanotechnology in improving photodynamic therapy for hypoxic tumors[J]. Chinese Journal of Tissue Engineering Research, 2026, 30(26): 6952-6960.

Figures/Tables 14

2.4 文献高被引分析高被引文献通常代表该领域的经典研究、突破性成果或者创新思维，分析总结高被引文献的特征，有助于人们发现该领域的研究热点和前沿，更好地探索未来的研究方向。为确定2016-2025年间该领域的高被引文献特征，使用Bibliometrix软件对纳入统计的1 879篇文献进行被引频次统计与分析，得到了引用次数排名前10名的文献[29-38]，如表3所示。其中ZHOU 等[29]在2016年发表于《Chemical Society Reviews》的文献总被引次数高达1 631次，年平均被引次数达到163.10次。在所有被引次数排名前10的文献中，所有文献年平均被引次数均高于80次，这些文献因开创性的理论、方法或发现为后续的研究奠定了坚实的基础，并提供了关键的知识框架和支持，代表了相关领域的核心知识和重要进展。 ZHOU等[29]系统解析了活性氧生成体系在光动力治疗中的关键作用，从光敏剂设计、激发源优化及跨学科策略融合等维度提出活性氧介导的肿瘤治疗的切入点与理论框架。FAN等[30]系统探讨了光动力治疗的核心技术瓶颈，并提出基于近红外光、X射线辐射和内部自发光体系的深度光动力治疗策略。YANG等[31]、CHEN等[32]通过构建二氧化锰(MnO2)基纳米材料调节乏氧肿瘤微环境，从而产生有利于抗肿瘤免疫反应的综合效果。LI 等[33]聚焦于内质网靶向策略，通过精准诱发内质网应激相活性氧生成实现了光动力治疗与光热疗法的协同增效。ZHANG等[34]构建均一固定在金属有机框架上具有高稳定性和类似过氧化氢酶活性的铂纳米颗粒，通过金属有机框架孔道结构实现氧气的可控释放，显著改善了乏氧区域的治疗效果。除此以外，LI等[35]、LI等[36]、DAI等[37]、LIU等[38]分别总结了克服光动力治疗介导的耗氧量和微血管损伤增加肿瘤乏氧的策略、超分子光敏剂设计与开发的最新进展、用于癌症治疗的纳米制剂的最新进展以及影像引导下的乏氧肿瘤精准治疗策略，共同推动了光动力治疗技术的临床应用拓展。 "

References

[1] LI XS, LOVELL JF, YOON JY, et al. Clinical Development and Potential of Photothermal and Photodynamic Therapies for Cancer. Nat Rev Clin Oncol. 2020;17:657-674.
[2] HU DR, LI YC, LI R, et al. Recent Advances in Reactive Oxygen Species (Ros)-Responsive Drug Delivery Systems for Photodynamic Therapy of Cancer. Acta Pharm Sin B. 2024;14:5106-5131.
[3] ZHANG HC, CUI MH, TANG DS, et al. Localization of Cancer Cells for Subsequent Robust Photodynamic Therapy by Ros Responsive Polymeric Nanoparticles with Anti-Metastasis Complexes Nami-A. Adv Mater. 2024;36:2310298.
[4] DIRAK M, YENICI CM, KOLEMEN S. Recent Advances in Organelle-Targeted Organic Photosensitizers for Efficient Photodynamic Therapy. Coord Chem Rev. 2024;506:215710.
[5] WU X, FAN Y, WANG K, et al. NIR-II Imaging-Guided Precise Photodynamic Therapy for Augmenting Tumor-Starvation Therapy by Glucose Metabolism Reprogramming Interference. SCI BULL. 2024;69: 1263-1274.
[6] TANG Y, LI Y, LI B, et al. Oxygen-Independent Organic Photosensitizer with Ultralow-Power Nir Photoexcitation for Tumor-Specific Photodynamic Therapy. Nat Commun. 2024;15:2530.
[7] HU DR, PAN M, YU Y, et al. Application of Nanotechnology for Enhancing Photodynamic Therapy Via Ameliorating, Neglecting, or Exploiting Tumor Hypoxia. View. 2020;1:e6.
[8] HU DR, CHEN LJ, QU Y, et al. Oxygen-Generating Hybrid Polymeric Nanoparticles with Encapsulated Doxorubicin and Chlorin E6 for Trimodal Imaging-Guided Combined Chemo-Photodynamic Therapy. Theranostics 2018;8:1558-1574.
[9] SUN Y, ZHAO D, WANG G, et al. Recent Progress of Hypoxia-Modulated Multifunctional Nanomedicines to Enhance Photodynamic Therapy: Opportunities, Challenges, and Future Development. Acta Pharm Sin B. 2020;10: 1382-1396.
[10] HUANG L, ZHAO SJ, WU JS, et al. Photodynamic Therapy for Hypoxic Tumors: Advances and Perspectives. Coord Chem Rev.2021;438:213888.
[11] LI XT, CHEN L, HUANG MT, et al. Innovative Strategies for Photodynamic Therapy against Hypoxic Tumor. Asian J Pharm Sci. 2023;18: 100775.
[12] WAN Y, FU LH, LI C, et al. Conquering the Hypoxia Limitation for Photodynamic Therapy. Adv Mater. 2021;33:2103978.
[13] WEI JP, LI JC, SUN D, et al. A Novel Theranostic Nanoplatform Based on Pd@Pt-Peg-Ce6 for Enhanced Photodynamic Therapy by Modulating Tumor Hypoxia Microenvironment. Adv Funct Mater. 2018;28:1706310.
[14] REN Q, YU N, WANG L, et al. Nanoarchitectonics with Metal-Organic Frameworks and Platinum Nanozymes with Improved Oxygen Evolution for Enhanced Sonodynamic/Chemo-Therapy. J Colloid Interface Sci. 2022;614:147-159.
[15] CHEN H, TIAN J, HE W, et al. H2O2-Activatable and O2-Evolving Nanoparticles for Highly Efficient and Selective Photodynamic Therapy against Hypoxic Tumor Cells. J Am Chem Soc. 2015;137: 1539-1547.
[16] JIANG W, ZHANG Z, WANG Q, et al.Tumor Reoxygenation and Blood Perfusion Enhanced Photodynamic Therapy Using Ultrathin Graphdiyne Oxide Nanosheets. Nano Lett. 2019;19:
4060-4067.
[17] BROEKGAARDEN M, WEIJER R, KREKORIAN M, et al. Inhibition of Hypoxia-Inducible Factor 1 with Acriflavine Sensitizes Hypoxic Tumor Cells to Photodynamic Therapy with Zinc Phthalocyanine-Encapsulating Cationic Liposomes. Nano Res. 2016;9:1639.
[18] LIU S, FENG G, TANG BZ, et al. Recent Advances of Aie Light-up Probes for Photodynamic Therapy. Chem Sci. 2021;12: 6488-6506.
[19] HAMBLIN MR. Upconversion in Photodynamic Therapy: Plumbing the Depths. Dalton T. 2018; 47:8571-8580.
[20] ZHU H, LI J, QI X, et al. Oxygenic Hybrid Semiconducting Nanoparticles for Enhanced Photodynamic Therapy. Nano Lett. 2018;18: 586-594.
[21] LEE D, KWON S, JANG SY, et al. Overcoming the Obstacles of Current Photodynamic Therapy in Tumors Using Nanoparticles. Bioact Mater. 2022;8:20-34.
[22] TIAN J, DING L, XU HJ, et al. Cell-Specific and Ph-Activatable Rubyrin-Loaded Nanoparticles for Highly Selective near-Infrared Photodynamic Therapy against Cancer. J Am Chem Soc. 2013; 135:18850-18858.
[23] AKRAM MW, RAZIQ F, FAKHAR-E-ALAM M, et al. Tailoring of Au-Tio2 Nanoparticles Conjugated with Doxorubicin for Their Synergistic Response and Photodynamic Therapy Applications. J Photochem Photobiol A Chem. 2019;384:112040.
[24] CHEN Y, YANG Y, DU S, et al. Mitochondria-Targeting Upconversion Nanoparticles@MOF for Multiple-Enhanced Photodynamic Therapy in Hypoxic Tumor. ACS Appl Mater Interfaces. 2023;15:35884-35894.
[25] NINKOV A, FRANK JR, MAGGIO LA. Bibliometrics: Methods for Studying Academic Publishing. Perspect Med Educ. 2022;11:173-176.
[26] 高俊宽. 文献计量学方法在科学评价中的应用探讨[J]. 图书情报知识,2005(2):14-17.
[27] 崔丽丽. 基于作者-主题关联的学科知识网络中核心作者影响力研究[D]. 武汉:华中师范大学,2022.
[28] JIANG S, LIU Y, ZHENG H, et al. Evolutionary Patterns and Research Frontiers in Neoadjuvant Immunotherapy: A Bibliometric Analysis. Int J Surg. 2023;109:2774-2783.
[29] ZHOU Z, SONG J, NIE L, et al. Reactive Oxygen Species Generating Systems Meeting Challenges of Photodynamic Cancer Therapy. Chem Soc Rev. 2016;45:6597-6626.
[30] FAN W, HUANG P, CHEN X. Overcoming the Achilles’ Heel of Photodynamic Therapy. Chem Soc Rev. 2016;45:6488-6519.
[31] YANG G, XU L, CHAO Y, et al. Hollow Mno2 as a Tumor-Microenvironment-Responsive Biodegradable Nano-Platform for Combination Therapy Favoring Antitumor Immune Responses. Nat Commun. 2017;8:902.
[32] CHEN Q, FENG LZ, LIU JJ, et al. Intelligent Albumin-Mno2 Nanoparticles as Ph-/H2o2-Responsive Dissociable Nanocarriers to Modulate Tumor Hypoxia for Effective Combination Therapy. Adv Mater. 2016;28:7129.
[33] LI W, YANG J, LUO L, et al. Targeting Photodynamic and Photothermal Therapy to the Endoplasmic Reticulum Enhances Immunogenic Cancer Cell Death. Nat Commun. 2019;10:3349.
[34] ZHANG Y, WANG F, LIU C, et al. Nanozyme Decorated Metal-Organic Frameworks for Enhanced Photodynamic Therapy. ACS Nano. 2018;12:651-661.
[35] LI XS, KWON N, GUO T, et al. Innovative Strategies for Hypoxic-Tumor Photodynamic Therapy. Angew Chem-Int Edit. 2018;57:11522-11531.
[36] LI X, LEE S, YOON J. Supramolecular Photosensitizers Rejuvenate Photodynamic Therapy. Chem Soc Rev. 2018;47:1174-1188.
[37] DAI Y, XU C, SUN X, et al. Nanoparticle Design Strategies for Enhanced Anticancer Therapy by Exploiting the Tumour Microenvironment. Chem Soc Rev. 2017;46:3830-3852.
[38] LIU JN, BU WB, SHI JL. Chemical Design and Synthesis of Functionalized Probes for Imaging and Treating Tumor Hypoxia. Chem Rev. 2017;117: 6160-6224.
[39] 常金霞, 刘羽飞, 牛少辉,等. 巨噬细胞极化在组织修复过程中的可视化分析[J]. 中国组织工程研究,2025,29(7):1486-1496.
[40] 黄文彬, 王冰璐, 步一,等. 关键词共引分析的科学计量方法研究[J]. 情报资料工作,2018(2): 37-42.
[41] KOLARIKOVA M, HOSIKOVA B, DILENKO H, et al. Photodynamic Therapy: Innovative Approaches for Antibacterial and Anticancer Treatments. Med Res Rev. 2023;43:717-774.
[42] JI B, WEI M, YANG B. Recent Advances in Nanomedicines for Photodynamic Therapy (Pdt)-Driven Cancer Immunotherapy. Theranostics. 2022;12:434-458.
[43] LIN T, ZHAO X, ZHAO S, et al. O2-Generating Mno2 Nanoparticles for Enhanced Photodynamic Therapy of Bladder Cancer by Ameliorating Hypoxia. Theranostics. 2018;8:990-1004.
[44] XU T, MA Y, YUAN Q, et al. Enhanced Ferroptosis by Oxygen-Boosted Phototherapy Based on a 2-in-1 Nanoplatform of Ferrous Hemoglobin for Tumor Synergistic Therapy. ACS Nano. 2020;14: 3414-3425.
[45] SEMENZA GL. Targeting Hif-1 for Cancer Therapy. Nat Rev Cancer. 2003;3:721-732.
[46] SUN B, BTE RAHMAT JN, ZHANG Y. Advanced Techniques for Performing Photodynamic Therapy in Deep-Seated Tissues. Biomaterials. 2022;291:121875.
[47] HE L, YU X, LI W. Recent Progress and Trends in X-Ray-Induced Photodynamic Therapy with Low Radiation Doses. ACS Nano.2022;16:19691-19721.
[48] CHEN JJ, ZHOU Q, CAO WW. Multifunctional Porphyrin-Based Sonosensitizers for Sonodynamic Therapy. Adv Funct Mater. 2024;34:2405844.
[49] OVERCHUK M, WEERSINK RA, WILSON BC, et al. Photodynamic and Photothermal Therapies: Synergy Opportunities for Nanomedicine. ACS Nano. 2023;17:7979-8003.
[50] YU Z, LI Q, WANG J, et al. Reactive Oxygen Species-Related Nanoparticle Toxicity in the Biomedical Field. Nanoscale Res Lett. 2020;15:115.
[51] HUA S, DE MATOS MBC, METSELAAR JM, et al. Current Trends and Challenges in the Clinical Translation of Nanoparticulate Nanomedicines: Pathways for Translational Development and Commercialization. Front Pharmacol. 2018;9:790.
[52] PARK K. The Beginning of the End of the Nanomedicine Hype. J Controlled Release. 2019; 305:221-222.
[53] ALGORRI JF, OCHOA M, ROLDÁN-VARONA P, et al.
Light Technology for Efficient and Effective Photodynamic Therapy: A Critical Review. Cancers. 2021;13:3484.