Article(id=1193523100521300381, tenantId=1146029695717560320, journalId=1189982191388893191, issueId=1193523095437799732, articleNumber=null, orderNo=null, doi=10.16438/j.0513-4870.2024-0828, pmid=null, cstr=null, oa=null, hot=null, price=null, onlineType=0, articleFormat=0, articleType=null, articleTypeStr=research-article, receivedDate=1724688000000, receivedDateStr=2024-08-27, revisedDate=1731513600000, revisedDateStr=2024-11-14, acceptedDate=null, acceptedDateStr=null, onlineDate=1762487681751, onlineDateStr=2025-11-07, pubDate=1739289600000, pubDateStr=2025-02-12, doiRegisterDate=null, doiRegisterDateStr=null, onlineIssueDate=1762487681751, onlineIssueDateStr=2025-11-07, onlineJustAcceptDate=null, onlineJustAcceptDateStr=null, onlineFirstDate=null, onlineFirstDateStr=null, sourceXml=null, magXml=null, createTime=1762487681751, creator=13701087609, updateTime=1762487681751, updator=13701087609, issue=Issue{id=1193523095437799732, tenantId=1146029695717560320, journalId=1189982191388893191, year='2025', volume='60', issue='2', pageStart='245', pageEnd='532', issueExtLink='null', onlineDate='null', pubDate='null', beforeIssueId=null, nextIssueId=null, price=null, status=1, issueComplete=1, articleOrder=1, issueType=-1, specialIssue=null, createTime=1762487680538, creator=13701087609, updateTime=1764224912893, updator=13701087609, preIssue=null, nextIssue=null, ext={EN=IssueExt(id=1200809576107987438, tenantId=1146029695717560320, journalId=1189982191388893191, issueId=1193523095437799732, language=EN, specialIssueTitle=, coverIllustrator=null, specialIssueEditor=, specialIssueAbout=), CN=IssueExt(id=1200809576107987439, tenantId=1146029695717560320, journalId=1189982191388893191, issueId=1193523095437799732, language=CN, specialIssueTitle=, coverIllustrator=null, specialIssueEditor=, specialIssueAbout=)}, issueFiles=null}, startPage=348, endPage=358, ext={EN=ArticleExt(id=1193523100781347233, articleId=1193523100521300381, tenantId=1146029695717560320, journalId=1189982191388893191, language=EN, title=Biomimetic nanoparticle delivery systems b ased on red blood cell membranes for disease treatment, columnId=1190335348648547107, journalTitle=Acta Pharmaceutica Sinica, columnName=Reviews, runingTitle=null, highlight=null, articleAbstract=
Nanoparticle delivery systems have good application prospects in the field of precision therapy, but the preparation process of nanomaterial has problems such as short in vivo circulation time, easy recognition, and clearance by the immune system in the body. In recent years, biomimetic nanoparticle delivery systems mediated by natural cell membranes have become a research hotspot to address these issues. The natural membrane biomimetic nanoparticle delivery system cleverly integrates the advantages of natural biofilm "autologous" and "artificial" functional carriers by using endogenous cell membranes to modify the surface of nanocarriers, endowing them with characteristics such as tumor targeting, low immunogenicity, and long blood circulation. Currently, biomimetic nanoparticle delivery systems have been used in the treatment of malignant tumors, cardiovascular diseases, bacterial infections, and other diseases. This paper analyzes the development status and current research hotspots of natural cell membrane camouflaged biomimetic nanoparticle delivery systems mainly reviews the latest research progress of red blood cell membrane camouflaged biomimetic nanoparticle delivery systems in the field of disease treatment in recent years. It focuses on exploring the advantages, future development prospects, and limitations of biomimetic nanoparticle delivery systems based on red blood cell membrane camouflage in improving drug delivery, to provide a reference for the in-depth research and development of this system.
, correspAuthors=Xiao-liang REN, Mei-ling CHEN, authorNote=null, correspAuthorsNote=null, copyrightStatement=Copyright ©2025 Acta Pharmaceutica Sinica. All rights reserved., copyrightOwner=null, extLink=null, articleAbsUrl=null, sourceXml=null, magXml=null, pdfUrl=null, pdf=null, pdfFileSize=null, pdfExtLink=null, richHtmlUrl=null, mobilePdfUrl=null, reviewReport=null, pdfFirstPage=null, abstractGraph=null, abstractGraphContent=null, abstractVideo=null, citation=null, cebUrl=null, magXmlContent=null, mapNumber=null, authorCompany=null, fund=null, authors=null, authorsList=Chen-xia GAO, Yan-yu XIAO, Yu-xue-yuan CHEN, Xiao-liang REN, Mei-ling CHEN), CN=ArticleExt(id=1193523263482594270, articleId=1193523100521300381, tenantId=1146029695717560320, journalId=1189982191388893191, language=CN, title=红细胞膜伪装的仿生纳米递送系统在疾病治疗中的应用, columnId=1190335349655180086, journalTitle=药学学报, columnName=综述, runingTitle=null, highlight=null, articleAbstract=
纳米递送系统在精准治疗领域具有良好的应用前景, 但纳米材料在制备过程中存在体内循环时间较短, 易被机体内免疫系统识别、清除等问题。近年来为解决这些问题, 由天然细胞膜介导的仿生纳米递送系统已成为研究热点。天然膜仿生递送系统使用机体内源性细胞膜对纳米载体表面进行包覆修饰, 巧妙地将天然生物膜“自体”性质和“人工”功能载体的优势相融合, 赋予其肿瘤靶向性、低免疫原性和血液长循环等特点。目前仿生纳米递送系统已用于治疗恶性肿瘤、心血管疾病、细菌感染等多种疾病。本文对天然细胞膜伪装的仿生纳米递送系统的发展状况与当前的研究热点进行分析, 综述了近年来红细胞膜伪装的仿生纳米递送系统在疾病治疗领域的最新研究进展, 重点探讨基于红细胞膜伪装的仿生纳米递送系统在改善药物递送方面的优势作用, 未来发展前景及局限性, 以期为该系统的深入研究与开发提供参考。
, correspAuthors=任晓亮, 陈美玲, authorNote=null, correspAuthorsNote=
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Composition of natural cell membrane bionic nanodelivery system , figureFileSmall=LHvgxDiLWlZqQeRBDh/q+g==, figureFileBig=iENB2xXXyPm9WHPi6xUFnA==, tableContent=null), ArticleFig(id=1194709018145956049, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=EN, label=null, caption=null, figureFileSmall=ja20R/IudhbZ4EB1MC1S5g==, figureFileBig=znmvQd6eUg4Ajjx/Cp/W6A==, tableContent=null), ArticleFig(id=1194709018309533908, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=CN, label=Figure 2, caption=
Construction and application of biomimetic nanodelivery system for erythrocyte membrane , figureFileSmall=ja20R/IudhbZ4EB1MC1S5g==, figureFileBig=znmvQd6eUg4Ajjx/Cp/W6A==, tableContent=null), ArticleFig(id=1194709018401808599, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=EN, label=null, caption=null, figureFileSmall=null, figureFileBig=null, tableContent=
| Therapy | Application | RBCM-NPs | Therapeutic agent | Function | Ref. |
| CT | Breast cancer | iRGD-RM-(DOX/MSNs) | DOX | High drug content, targeted delivery | [2] |
| | PTX-NP-EM | PTX | High drug content, long circulation | [15] |
| | RBC-4T1@DOX/CS-NPs | DOX | Targeted delivery | [18] |
| | ECM/Tel | Tel | High drug content, long circulation, targeted delivery | [19] |
| Liver cancer | GACS-Cur@RBCm | Cur | Enhance immune escape ability, targeted delivery | [20] |
| | PDC@RBC-NPs | DOX | Enhance immune escape ability, long circulation | [21] |
| | 5-FU-C-NPs-NEs | 5-FU | Long circulation | [22] |
| Lung cancer | RBCm-OM/PLGA | OM | Enhance immune escape ability, long circulation | [23] |
| | R-RBC@GEF-NPs | GEF | Enhance immune escape ability, targeted delivery, targeting imaging | [24] |
| | iRINP | ICA | Enhance immune escape ability, increasessolubility | [25] |
| | REMAIN | MiR-126-3p | Enhance immune escape ability, long circulation | [26] |
| | UMNP | UA | Enhance immune escape ability, targeted delivery, increases solubility | [27] |
| Colorectal cancer | RSV-NPs@RBCm | RSV | Enhance immune escape ability, enhanced tumor tissue penetration | [28] |
| | PLGA/SK (+) @RBCm and PLGA/SK (-) @RBCm | Shikonin | Long circulation, enhanced tumor tissue penetration | [29] |
| Ervical cancer | DOX@ZIF-8@eM-cRGD | DOX | Long circulation, enhanced tumor tissue penetration | [30] |
| PTT | Breast cancer | SPN@RBCM | SPN | Enhance immune escape ability, long circulation | [16] |
| Liver cancer | HNP@RBCM-cRGD | HNP | Long circulation, targeted delivery | [31] |
| | RHAuNCs-miRNA | miRNA | Long circulation, sustained-release | [32] |
| | CuS@RBCs | | Long circulation, enhanced tumor accumulation | [33] |
| Lung cancer | DRBCM-BNF | | Enhance immune escape ability, CT imaging | [34] |
| | Cyp-MNC@RBCs | Cyp | Enhanced tumor accumulation | [35] |
| SDT | Breast cancer | RBC-mTNPs@AQ4N | AQ4N | Enhance immune escape ability | [36] |
| GET | Ervical cancer | CM-PQDs/DNA | | Sustained-release effect | [37] |
| CT/PTT | Breast cancer | DOX@IRP@RBC NPs | DOX, IR780 | Enhance immune escape ability, long circulation | [38] |
| | MoS2-RBC-DOX | DOX | Enhance immune escape ability | [39] |
| | Fe-PDA-EPI@FA-RBCm | EPI | Targeted delivery | [40] |
| | MSNR@DOX&ICG@RBCM | DOX, ICG | Enhance immune escape ability | [41] |
| Liver cancer | DIRNPs | DOX, ICG | Long circulation, targeted delivery | [42] |
| Cervical cancer | WID@M-FA NPs | DOX, ICG | Long circulation | [43] |
| | RmGIB NPs | GA, ICG | Long circulation | [44] |
| | GID@RF NPs | DOX, ICG | Enhance immune escape ability, long circulation | [45] |
| | PCDI@M | Cs-6, IND | Targeted delivery | [46] |
| PTT/PDT | Breast cancer | Ce6@DiR-M NPs | Ce6, DiR | Long circulation | [47] |
| | cRGD-RBC@mTHPC/TAT-IR820 | | Long circulation, targeted delivery | [48] |
| | PMRCR NPs | | Targeted delivery | [49] |
| Cervical cancer | ZNPC-ICG@RBC | ZNPC, ICG | Enhance immune escape ability, long circulation, enhanced tumor accumulation | [50] |
| CT/PDT | Breast cancer | ARISP | ICG, Sal | Enhance immune escape ability, long circulation | [51] |
| Lung cancer | HA&RBCm-LCNPs | PTX, IR780 | Long circulation, enhanced tumor accumulation | [52] |
| Colorectal cancer | HNPOC | Oxa | Long circulation, targeted delivery | [53] |
| | PLGA/GCC@FR | CQP | Long circulation, targeted delivery | [54] |
| IMT/PTT | Breast cancer | RBCm/PAAV-SNO/IR1061+1-MT NPs | IR1061, 1-MT | Long circulation, controlled-release | [17] |
| | RDIR1048 | | Enhance immune escape ability, long circulation, targeted delivery | [55] |
| CDT/CT/PTT | Breast cancer | HCPT@Cu/ZIF@PDA | HCPT | Enhance immune escape ability, long circulation | [56] |
| | RM-Cu/P@DOX | DOX | Long circulation, targeted delivery | [57] |
| CDT/PTT | Liver cancer | FGIR | | Long circulation | [58] |
| IMT/CT | Melanoma | RBC-NPs | Hgp | Long circulation | [59] |
| | lCUR-DOX@RBC NPs | DOX | Enhance immune escape ability, enhanced tumor accumulation | [60] |
| Breast cancer | HR-UCAD | DOX | Enhance immune escape ability, targeted delivery | [61] |
| CST/PTT | Breast cancer | AMS+-Gox@TSL@[RBC-CC-TSL]M | | Enhance immune escape ability | [62] |
| IIT/CDT/CST | Breast cancer | Cu-CaO2/GOx@FRs | | Targeted delivery | [63] |
| PTT/RT | Lung cancer | RBCM-BNF | | Improved biocompatibility | [64] |
| IMT/PDT | Melanoma | M@AP NPs | P2-PPh3,
poly (I: C) | Enhanced tumor accumulation | [65] |
), ArticleFig(id=1194709018531832026, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=CN, label=Table 1, caption=
Application of RBCM-NPs in tumor therapy. CT: Chemotherapy; PTX: Paclitaxel; DOX: Doxorubicin; Tel: Telmisartan; Cur: Curcumin; 5-FU: 5- Fluorouracil; OM: Obatoclax mesylate; GEF: Gefitinib; ICA: Icariin; UA: Ursolic acid; RSV: Resveratrol; PTT: Photothermal therapy; SPN: Semiconducting conjugated polymer nanoparticles; HNP: Human black hair-derived nanoparticles; SDT: Sonodynamic therapy; GET: Gene therapy; EPI: Epirubicin; ICG: Indocyanine green; GA: Gambogic acid; IND: Indomethacin; PDT: Photodynamic therapy; CQP: Chloroquine phosphate; IMT: Immunotherapy; CDT: Chemodynamic therapy; HCPT: 10-Hydroxycamptothecin; CST: Cancer starvation therapy; IIT: Ion interference therapy; RT: Radio therapy
, figureFileSmall=null, figureFileBig=null, tableContent=
| Therapy | Application | RBCM-NPs | Therapeutic agent | Function | Ref. |
| CT | Breast cancer | iRGD-RM-(DOX/MSNs) | DOX | High drug content, targeted delivery | [2] |
| | PTX-NP-EM | PTX | High drug content, long circulation | [15] |
| | RBC-4T1@DOX/CS-NPs | DOX | Targeted delivery | [18] |
| | ECM/Tel | Tel | High drug content, long circulation, targeted delivery | [19] |
| Liver cancer | GACS-Cur@RBCm | Cur | Enhance immune escape ability, targeted delivery | [20] |
| | PDC@RBC-NPs | DOX | Enhance immune escape ability, long circulation | [21] |
| | 5-FU-C-NPs-NEs | 5-FU | Long circulation | [22] |
| Lung cancer | RBCm-OM/PLGA | OM | Enhance immune escape ability, long circulation | [23] |
| | R-RBC@GEF-NPs | GEF | Enhance immune escape ability, targeted delivery, targeting imaging | [24] |
| | iRINP | ICA | Enhance immune escape ability, increasessolubility | [25] |
| | REMAIN | MiR-126-3p | Enhance immune escape ability, long circulation | [26] |
| | UMNP | UA | Enhance immune escape ability, targeted delivery, increases solubility | [27] |
| Colorectal cancer | RSV-NPs@RBCm | RSV | Enhance immune escape ability, enhanced tumor tissue penetration | [28] |
| | PLGA/SK (+) @RBCm and PLGA/SK (-) @RBCm | Shikonin | Long circulation, enhanced tumor tissue penetration | [29] |
| Ervical cancer | DOX@ZIF-8@eM-cRGD | DOX | Long circulation, enhanced tumor tissue penetration | [30] |
| PTT | Breast cancer | SPN@RBCM | SPN | Enhance immune escape ability, long circulation | [16] |
| Liver cancer | HNP@RBCM-cRGD | HNP | Long circulation, targeted delivery | [31] |
| | RHAuNCs-miRNA | miRNA | Long circulation, sustained-release | [32] |
| | CuS@RBCs | | Long circulation, enhanced tumor accumulation | [33] |
| Lung cancer | DRBCM-BNF | | Enhance immune escape ability, CT imaging | [34] |
| | Cyp-MNC@RBCs | Cyp | Enhanced tumor accumulation | [35] |
| SDT | Breast cancer | RBC-mTNPs@AQ4N | AQ4N | Enhance immune escape ability | [36] |
| GET | Ervical cancer | CM-PQDs/DNA | | Sustained-release effect | [37] |
| CT/PTT | Breast cancer | DOX@IRP@RBC NPs | DOX, IR780 | Enhance immune escape ability, long circulation | [38] |
| | MoS2-RBC-DOX | DOX | Enhance immune escape ability | [39] |
| | Fe-PDA-EPI@FA-RBCm | EPI | Targeted delivery | [40] |
| | MSNR@DOX&ICG@RBCM | DOX, ICG | Enhance immune escape ability | [41] |
| Liver cancer | DIRNPs | DOX, ICG | Long circulation, targeted delivery | [42] |
| Cervical cancer | WID@M-FA NPs | DOX, ICG | Long circulation | [43] |
| | RmGIB NPs | GA, ICG | Long circulation | [44] |
| | GID@RF NPs | DOX, ICG | Enhance immune escape ability, long circulation | [45] |
| | PCDI@M | Cs-6, IND | Targeted delivery | [46] |
| PTT/PDT | Breast cancer | Ce6@DiR-M NPs | Ce6, DiR | Long circulation | [47] |
| | cRGD-RBC@mTHPC/TAT-IR820 | | Long circulation, targeted delivery | [48] |
| | PMRCR NPs | | Targeted delivery | [49] |
| Cervical cancer | ZNPC-ICG@RBC | ZNPC, ICG | Enhance immune escape ability, long circulation, enhanced tumor accumulation | [50] |
| CT/PDT | Breast cancer | ARISP | ICG, Sal | Enhance immune escape ability, long circulation | [51] |
| Lung cancer | HA&RBCm-LCNPs | PTX, IR780 | Long circulation, enhanced tumor accumulation | [52] |
| Colorectal cancer | HNPOC | Oxa | Long circulation, targeted delivery | [53] |
| | PLGA/GCC@FR | CQP | Long circulation, targeted delivery | [54] |
| IMT/PTT | Breast cancer | RBCm/PAAV-SNO/IR1061+1-MT NPs | IR1061, 1-MT | Long circulation, controlled-release | [17] |
| | RDIR1048 | | Enhance immune escape ability, long circulation, targeted delivery | [55] |
| CDT/CT/PTT | Breast cancer | HCPT@Cu/ZIF@PDA | HCPT | Enhance immune escape ability, long circulation | [56] |
| | RM-Cu/P@DOX | DOX | Long circulation, targeted delivery | [57] |
| CDT/PTT | Liver cancer | FGIR | | Long circulation | [58] |
| IMT/CT | Melanoma | RBC-NPs | Hgp | Long circulation | [59] |
| | lCUR-DOX@RBC NPs | DOX | Enhance immune escape ability, enhanced tumor accumulation | [60] |
| Breast cancer | HR-UCAD | DOX | Enhance immune escape ability, targeted delivery | [61] |
| CST/PTT | Breast cancer | AMS+-Gox@TSL@[RBC-CC-TSL]M | | Enhance immune escape ability | [62] |
| IIT/CDT/CST | Breast cancer | Cu-CaO2/GOx@FRs | | Targeted delivery | [63] |
| PTT/RT | Lung cancer | RBCM-BNF | | Improved biocompatibility | [64] |
| IMT/PDT | Melanoma | M@AP NPs | P2-PPh3,
poly (I: C) | Enhanced tumor accumulation | [65] |
), ArticleFig(id=1194709018682826974, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=EN, label=null, caption=null, figureFileSmall=null, figureFileBig=null, tableContent=
| RBCM-NPs | Application | Core material | Function | Ref. |
| RBC@Fe3O4 | Anti-bacterial infection | Fe3O4, RBCM | Adsorption of bacterial toxins | [75] |
| RBCM-NW-G | Anti-bacterial infection | AuAg-G, PDA, RBCM | Drug delivery | [76] |
| RBC(IR780)-PFC(O2) | Anti-bacterial infection | PFC, IR780, RBCM | Neutralization of pore-forming toxins | [77] |
| P-RL | Anti-Escherichia coli infection | Lip, RBCM, PMB | Neutralize internal and external toxins | [78] |
| RPTR-701Ns | Methicillin-resistant Staphylococcus aureus infection | PTR-701Ns, RBCM | Neutralization of exotoxins | [79] |
| RBCDVL | Methicillin-resistant Staphylococcus aureus infection | VAN, Lip, DAPT, RBCM | Targeted delivery | [80] |
| RM-PL | Broad-spectrum detoxification | PL, RBCM | Neutralization of pore-forming toxins | [81] |
| PEM-ARM | Prevention of Plasmodium infection | Lip-ARM, RBCM, CLIPPKF | Blockade of CDP-Cho mediated Phosphatidylcholine synthesis | [82] |
| AB@LRM NPs | Anti-Pseudomonas aeruginosa infection | BPQD, AM, RBCM | Targeted delivery | [83] |
), ArticleFig(id=1194709018791878879, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=CN, label=Table 2, caption=
Application of RBCM-NPs in the treatment of bacterial infection. PMB: Polymyxin B; DAPT: Daptomycin; AM: Antibiotics amikacin
, figureFileSmall=null, figureFileBig=null, tableContent=
| RBCM-NPs | Application | Core material | Function | Ref. |
| RBC@Fe3O4 | Anti-bacterial infection | Fe3O4, RBCM | Adsorption of bacterial toxins | [75] |
| RBCM-NW-G | Anti-bacterial infection | AuAg-G, PDA, RBCM | Drug delivery | [76] |
| RBC(IR780)-PFC(O2) | Anti-bacterial infection | PFC, IR780, RBCM | Neutralization of pore-forming toxins | [77] |
| P-RL | Anti-Escherichia coli infection | Lip, RBCM, PMB | Neutralize internal and external toxins | [78] |
| RPTR-701Ns | Methicillin-resistant Staphylococcus aureus infection | PTR-701Ns, RBCM | Neutralization of exotoxins | [79] |
| RBCDVL | Methicillin-resistant Staphylococcus aureus infection | VAN, Lip, DAPT, RBCM | Targeted delivery | [80] |
| RM-PL | Broad-spectrum detoxification | PL, RBCM | Neutralization of pore-forming toxins | [81] |
| PEM-ARM | Prevention of Plasmodium infection | Lip-ARM, RBCM, CLIPPKF | Blockade of CDP-Cho mediated Phosphatidylcholine synthesis | [82] |
| AB@LRM NPs | Anti-Pseudomonas aeruginosa infection | BPQD, AM, RBCM | Targeted delivery | [83] |
), ArticleFig(id=1194709018879959265, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=EN, label=null, caption=null, figureFileSmall=null, figureFileBig=null, tableContent=
| Application | RBCM-NPs | Therapeutic agent | Function | Ref. |
| Alzheimer's disease | TGN-RBC-NPs-Cur | Cur | Overcoming the blood-brain barrier, targeted delivery | [87] |
| PDA-CQD/RBC | | Overcoming the blood-brain barrier, enhance immune escape ability, targeted delivery | [88] |
| RVG/TPP-RSV NPs | RSV | Overcoming the blood-brain barrier, targeted delivery | [94] |
| T807/TPP-RBC-NP | Cur | Overcoming the blood-brain barrier, targeted delivery | [95] |
| CuXO@EM-K | CuXO | Enhance immune escape ability, long circulation, targeted delivery | [96] |
| AFPS/CTAB@RBC | H2S | Enhance drug stability | [97] |
| TR-ZRA | | Overcoming the blood-brain barrier | [98] |
| CQD-Ce-RBC | | Overcoming the blood-brain barrier, enhance immune escape ability | [99] |
| PB/RBC | PBNP | Overcoming the blood-brain barrier | [100] |
| Parkinson's disease | RVG29-RBCm/Cur-NCs | Cur | Overcoming the blood-brain barrier, long circulation, targeted delivery | [89] |
| RBCM/UCMG | | Overcoming the blood-brain barrier, enhance immune escape ability, targeted delivery | [101] |
| Traumatic brain injury | C3/SS31-RBCNLCs | Ola | Targeted delivery | [102] |
| Autism spectrum disorder | SCM@RAPA | RAPA | Overcoming the blood-brain barrier | [103] |
| Thrombus | T-RBC-DTC NPs | Tirofiban | Long circulation, targeted delivery | [93] |
| PM/RM@PLGA@P/R | Rg1 | Enhance immune escape ability, targeted delivery | [104] |
| RGD-RBCM@PPUNPs | UK | Enhance immune escape ability | [105] |
| USIO/UK@EM | UK | Extended half-life | [106] |
| Atherosclerosis | RBC/LFP@PMMP | Prednisolone, LFP | Long circulation | [107] |
| RBC@P-LVTNPs | | Enhance immune escape ability | [108] |
| CXCR2 [RBC-P] NPs | CXCR2 | Long circulation | [109] |
), ArticleFig(id=1194709019043537123, tenantId=1146029695717560320, journalId=1189982191388893191, articleId=1193523100521300381, language=CN, label=Table 3, caption=
Application of RBCM-NPs in the treatment of other diseases. PBNP: Prussian blue nanoparticles. RAPA: Rapamycin; UK: Urokinase; LFP: Lipid-specific fluorophore
, figureFileSmall=null, figureFileBig=null, tableContent=
| Application | RBCM-NPs | Therapeutic agent | Function | Ref. |
| Alzheimer's disease | TGN-RBC-NPs-Cur | Cur | Overcoming the blood-brain barrier, targeted delivery | [87] |
| PDA-CQD/RBC | | Overcoming the blood-brain barrier, enhance immune escape ability, targeted delivery | [88] |
| RVG/TPP-RSV NPs | RSV | Overcoming the blood-brain barrier, targeted delivery | [94] |
| T807/TPP-RBC-NP | Cur | Overcoming the blood-brain barrier, targeted delivery | [95] |
| CuXO@EM-K | CuXO | Enhance immune escape ability, long circulation, targeted delivery | [96] |
| AFPS/CTAB@RBC | H2S | Enhance drug stability | [97] |
| TR-ZRA | | Overcoming the blood-brain barrier | [98] |
| CQD-Ce-RBC | | Overcoming the blood-brain barrier, enhance immune escape ability | [99] |
| PB/RBC | PBNP | Overcoming the blood-brain barrier | [100] |
| Parkinson's disease | RVG29-RBCm/Cur-NCs | Cur | Overcoming the blood-brain barrier, long circulation, targeted delivery | [89] |
| RBCM/UCMG | | Overcoming the blood-brain barrier, enhance immune escape ability, targeted delivery | [101] |
| Traumatic brain injury | C3/SS31-RBCNLCs | Ola | Targeted delivery | [102] |
| Autism spectrum disorder | SCM@RAPA | RAPA | Overcoming the blood-brain barrier | [103] |
| Thrombus | T-RBC-DTC NPs | Tirofiban | Long circulation, targeted delivery | [93] |
| PM/RM@PLGA@P/R | Rg1 | Enhance immune escape ability, targeted delivery | [104] |
| RGD-RBCM@PPUNPs | UK | Enhance immune escape ability | [105] |
| USIO/UK@EM | UK | Extended half-life | [106] |
| Atherosclerosis | RBC/LFP@PMMP | Prednisolone, LFP | Long circulation | [107] |
| RBC@P-LVTNPs | | Enhance immune escape ability | [108] |
| CXCR2 [RBC-P] NPs | CXCR2 | Long circulation | [109] |
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