{"id":55200,"date":"2024-12-28T14:21:49","date_gmt":"2024-12-28T15:21:49","guid":{"rendered":"https:\/\/peymantaeidi.net\/stem-cell\/?p=55200"},"modified":"2024-12-28T15:36:46","modified_gmt":"2024-12-28T15:36:46","slug":"advancements-in-betulinic-acid-loaded-nanoformulations-for-enhanced-anti-tumor-therapy","status":"publish","type":"post","link":"https:\/\/peymantaeidi.net\/stem-cell\/2024\/12\/28\/advancements-in-betulinic-acid-loaded-nanoformulations-for-enhanced-anti-tumor-therapy\/","title":{"rendered":"Advancements in Betulinic Acid-Loaded Nanoformulations for Enhanced Anti-Tumor Therapy"},"content":{"rendered":"

Ke Wang,1,<\/sup>2,<\/sup>*<\/sup> Jinlu Shang,3,<\/sup>*<\/sup> Chao Tao,1,<\/sup>2,<\/sup>*<\/sup> Mingquan Huang,4<\/sup> Daiqing Wei,5<\/sup> Liuxuan Yang,1<\/sup> Jing Yang,1<\/sup> Qingze Fan,1<\/sup> Qian Ding,6<\/sup> Meiling Zhou1<\/sup> <\/p>\n

1<\/sup>Department of Pharmacy, the Affiliated Hospital, Southwest Medical University, Luzhou, People\u2019s Republic of China; 2<\/sup>Department of Clinical Pharmacy, School of Pharmacy, Southwest Medical University, Luzhou, People\u2019s Republic of China; 3<\/sup>Department of Pharmacy, West China Hospital Sichuan University Jintang Hospital, Chengdu, People\u2019s Republic of China; 4<\/sup>Sichuan Treatment Center for Gynaecologic and Breast Diseases (Breast Surgery), the Affiliated Hospital, Southwest Medical University, Luzhou, People\u2019s Republic of China; 5<\/sup>Department of Orthopaedics, the Affiliated Hospital, Southwest Medical University, Luzhou, People\u2019s Republic of China; 6<\/sup>Department of Clinical Pharmacy, the Third Hospital of Mianyang, Sichuan Mental Health Center, Mianyang, People\u2019s Republic of China<\/p>\n

Correspondence: Meiling Zhou, Department of Pharmacy, the Affiliated Hospital, Southwest Medical University, No. 25, Taiping Street, Luzhou, Sichuan, 646000, People\u2019s Republic of China, Email [email protected]<\/a> Qian Ding, Department of Clinical Pharmacy, the Third Hospital of Mianyang, Sichuan Mental Health Center, No. 190, East Section of Jiannan Road, Mianyang, Sichuan, 621000, People\u2019s Republic of China, Email [email protected]<\/a><\/p>\n

Abstract:<\/strong> Betulinic acid (BA) is a natural compound obtained from plant extracts and is known for its diverse pharmacological effects, including anti-tumor, antibacterial, anti-inflammatory, antiviral, and anti-atherosclerotic properties. Its potential in anti-tumor therapy has garnered considerable attention, particularly for the treatment of breast, lung, and liver cancers. However, the clinical utility of BA is greatly hindered by its poor water solubility, low bioavailability, and off-target toxicity. To address these issues, researchers have developed various BA-loaded nanoformulations, such as nanoparticles, liposomes, micelles, and nanofibers, aiming to improve its solubility and bioavailability, prolong plasma half-life, and enhance targeting ability, thereby augmenting its anti-cancer efficacy. In preparing this review, we conducted extensive searches in well-known databases, including PubMed, Web of Science, and ScienceDirect, using keywords like \u201cbetulinic acid\u201d, \u201cnanoparticles\u201d, \u201cdrug delivery\u201d, \u201ctumor\u201d, and \u201ccancer\u201d, covering the literature from 2014 to 2024. The review provides a comprehensive overview of recent advancements in the application of BA-loaded nano-delivery systems for anti-tumor therapy and offers insights into their future development prospects. <\/p>\n

Keywords:<\/strong> betulinic acid, nanoformulations, anti-tumor, bioavailability, targeting<\/p>\n

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Introduction<\/h2>\n

BA is a naturally occurring pentacyclic triterpenoid of the lupane type, commonly found in the leaves of Syzygium jambos<\/em>, the bark of Betula platyphylla<\/em>, and the seeds of Ziziphus jujuba<\/em>.1<\/a><\/sup> BA can be obtained through three primary methods. The most direct approach is extraction from natural plant sources, though this approach exhibits a relatively low yield.2<\/a><\/sup> The second method is chemical synthesis, where betulin\u2014a structurally similar compound\u2014is often used as a starting material. However, chemical synthesis involves challenges, including harsh reaction conditions and high toxicity.3<\/a><\/sup> Recently, biotransformation has gained increasing attention for BA production due to its environmental compatibility and milder reaction conditions. Through the development of efficient production strains, biotransformation enables the large-scale production of BA.4<\/a><\/sup> Numerous studies have reported the diverse pharmacological effects of BA, encompassing anti-tumor,5<\/a><\/sup> anti-inflammatory,6<\/a><\/sup> bacteriostatic,7<\/a><\/sup> anti-atherosclerosis,8<\/a><\/sup> and anti-osteoporosis activities.9<\/a><\/sup> In 1976, Trumbull et al first reported the activity of BA against lymphocytic leukemia.10<\/a><\/sup> Since then, its therapeutic potential for various cancers\u2014such as lung,11<\/a><\/sup> breast,12<\/a><\/sup> and liver cancers13<\/a><\/sup>\u2014has been widely validated in both in vitro and in vivo studies. Due to its potent anti-tumor activity and favorable safety profile, the US National Cancer Institute has included BA in its rapid development program.14<\/a><\/sup><\/p>\n

Particularly in the field of anti-tumor activity, BA demonstrates inhibitory effects on various types of tumors through mechanisms such as affecting the cell cycle, activating apoptotic pathways, and regulating signaling pathways. Its specific mechanisms include inhibiting the formation of the topoisomerase I-DNA cleavable complexes, thereby preventing their involvement in the apoptotic process;15<\/a><\/sup> inducing tumor cell arrest in the G2\/M phase, suppressing DNA synthesis, and activating the mitochondrial apoptotic pathway;16<\/a><\/sup> promoting tumor necrosis factor-associated apoptosis-inducing ligand production through the p53\/caspase-3 signaling pathway;17<\/a><\/sup> inhibiting vasodilator-stimulated phosphoprotein expression by negatively regulating the NF-\u03baB transcription factors, thereby limiting tumor cell proliferation and migration;18<\/a><\/sup> activating ferritinophagy-proteins in tumor cells to increase intracellular free iron content, augmenting reactive oxygen species (ROS) production through the Fenton reaction, causing lipid peroxidation in tumor cells, thereby inhibiting their proliferation.19<\/a><\/sup> Multiple lines of evidence suggest that BA holds great promise as an anti-cancer agent, but its limited water solubility, low bioavailability, and potential off-target toxicity20<\/a><\/sup> constrain its further application.<\/p>\n

In recent years, nano drug delivery systems (NDDSs) have garnered great interest as a strategy capable of substantially increasing drug bioavailability, improving drug targeting, and reducing side effects.21\u201323<\/a><\/sup> NDDSs involve the combination of drug molecules with a variety of nanocarriers such as nanoparticles, nanofibers, nanotubes, liposomes, and micelles, which not only improve drug stability and bioavailability but also achieve sustained release and targeted delivery of drugs.24<\/a>,25<\/a><\/sup> Currently, extensive research efforts have been devoted to leveraging the advantages of NDDSs to address the shortcomings of BA, aiming to enhance its cellular uptake efficiency, drug accumulation in tumor cells,26<\/a><\/sup> and capability to cross physiological barriers.27<\/a><\/sup> In addition, NDDSs can exploit the distinctive properties of nanocarriers, such as pH sensitivity or temperature sensitivity, to achieve drug release under specific conditions, thereby enhancing anti-tumor effects while mitigating toxicity to normal cells.12<\/a><\/sup><\/p>\n

This review aims to retrospectively review and summarize the recent applications of BA-loaded NDDSs in anti-tumor therapy, with a special focus on how to improve the therapeutic efficacy of BA through nanoformulations. We will also discuss the major challenges existing in current research, including the biocompatibility, stability, and cost-effectiveness of nanocarriers, and look forward to possible future research directions, such as the development of novel nanocarriers and the integration of nanotechnology with targeted therapeutic strategies. Through this review, our goal is to provide a comprehensive and in-depth reference for the research on the nano delivery of BA and other natural drugs, especially in enhancing their potential application in anti-tumor therapy. We believe that with the continuous progress and deeper exploration of nanotechnology, BA-loaded NDDSs will play an increasingly pivotal role in future anti-cancer treatments.<\/p>\n

BA-Loaded Nanoparticles<\/h2>\n

Nanoparticles serve as common carriers in NDDSs, significantly enhancing the aqueous solubility, bioavailability, and plasma half-life of drugs, thereby optimizing their pharmacokinetic properties. Nanoparticles can also be modified by targeting ligands on their surface, thereby improving their specific recognition and action on tumor cells. Currently, a variety of BA-loaded nanoparticles have been developed, including protein nanoparticles, inorganic nanoparticles, polymeric nanoparticles, and other nanoparticles, each with unique advantages (Table 1<\/a>). For instance, Saneja et al24<\/a><\/sup> successfully prepared PLGA-mPEG nanoparticles loaded with BA using the emulsion solvent evaporation method, which considerably extended the plasma half-life of the drug. In another study, Halder et al28<\/a><\/sup> coupled BA with lactoferrin (Lf) to obtain Lf-BAnp. This formulation not only prolonged the release of BA but also facilitated rapid delivery to MDA-MB-231 and HEp-2 cells, resulting in potent anti-proliferative and cytotoxic effects.\n<\/p>\n\n\n\n
<\/a><\/td>\n\n

Table 1<\/strong> Summary of BA-Loaded Nanoparticles<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Protein Nanoparticles<\/h3>\n

Glycosylated zein (G-zein) exhibits excellent solubility, dispersibility, and bioactivity, which can enhance the stability and encapsulation efficiency of active ingredients.49<\/a><\/sup> Peng et al29<\/a><\/sup> successfully prepared G-zein composite nanoparticles loaded with BA (G-zein@BA) using an antisolvent method. G-zein contains abundant hydrophilic groups, and the spatial site-blocking effect introduced by glucose prevents protein aggregation, allowing BA to be tightly encapsulated within G-zein and enhancing its solubility. The interaction between G-zein and BA was facilitated by electrostatic and hydrophobic forces, resulting in an encapsulation efficiency exceeding 80% at a BA concentration of 1 mg\/mL. G-zein@BA not only exhibited superior slow-release properties than free BA but also effectively suppressed the proliferation of HepG2 cells.<\/p>\n

Human serum albumin (HSA) serves as a versatile protein drug carrier, valued for its biocompatibility, biodegradability, and non-immunogenicity.50<\/a><\/sup> The secreted protein acidic and rich in cysteine is often overexpressed in the tumor microenvironment (TME), which exhibits a high affinity for HSA. Therefore, anti-tumor drugs using HSA as a carrier tend to be preferentially taken up by tumor cells.51<\/a><\/sup> Srivari et al5<\/a><\/sup> prepared monomeric albumin-bound BA nanoparticles (ABBns) through a self-assembly method, achieving efficient loading of approximately 85% to 90% of BA onto HSA. Sodium cholate, used as a surfactant, shares structural similarities with BA and possesses a high aggregation number, which enhances the solubility of BA. Moreover, ABBns exhibited selective uptake by A549 cells and demonstrated high cytotoxicity. Bovine serum albumin (BSA) and HSA share up to 76% similarity in their amino acid sequence,52<\/a><\/sup> enabling them to effectively bind various albumin receptors overexpressed on the tumor cell surface, such as gp60 and secreted protein acidic and rich in cysteine, thereby enhancing the cellular uptake and therapeutic efficacy of nanoparticles.53<\/a><\/sup> In their work, Dai et al30<\/a><\/sup> employed self-assembled BSA-poly(L-lactic acid) as a carrier and successfully prepared BA-loaded nanoparticles via a nanoprecipitation method, which significantly prolonged the blood circulation half-life and anti-tumor activity of BA.<\/p>\n

Inorganic Nanoparticles<\/h3>\n

Inorganic nanoparticles, which may contain metal ions such as iron, manganese, and gold, have become a focus of research due to their ability to enhance anti-tumor effects through catalyzing specific Fenton reactions in the TME. For instance, Hussein-Al-Ali et al31<\/a><\/sup> successfully synthesized BA-CS-MNP nanocomposites by coating chitosan (CS) on Fe3<\/sub>O4<\/sub> magnetic nanoparticles (MNPs) and loading with BA. The resulting composites exhibited a significantly reduced average size of 23.6 nm compared to the 39.6 nm of bare MNPs, attributed to the prolonged high-speed stirring of the polymer and drug after mixing. BA-CS-MNP not only extended the release of BA but also exhibited higher tumor inhibition efficiency. In another investigation, Urandur et al12<\/a><\/sup> employed a lyotropic liquid crystalline nanostructures (LCN) strategy to incorporate BA and manganese oxide nanoparticles into a dispersion containing phytantriol, Mn-Oleate complex, and Pluronic F127. Following storage at room temperature under light protection for three days to reach equilibrium, LCN@Mn-BA was obtained after sonication, enabling selective cancer imaging and therapy. LCN@Mn-BA acted as both a fluorophore and a source of manganese (Mn2+<\/sup>), catalyzing Fenton-like reactions to generate hydroxyl radicals within the TME, thereby inducing apoptosis and effectively inhibiting tumor growth. Compared with a free mixture of Mn2+<\/sup> and BA, treatment with LCN@Mn-BA notably decreased tumor cell viability from 40 \u00b1 5% to 17 \u00b1 4%, underscoring its substantial capability to inhibit tumor cell proliferation.<\/p>\n

Targeting mitochondria is also a therapeutic strategy for tumor treatment. Gold nanoparticles (GNP) have been identified as inhibitors of mitochondrial respiration. Ghiulai et al32<\/a><\/sup> successfully synthesized BA-GNP with selective cytotoxicity by grafting BA onto GNP using cysteamine as a linker. BA-GNP downregulated the expression of the anti-apoptotic factor Bcl-2 and upregulated the pro-apoptotic factor Bax, thereby exerting anti-tumor effects. Furthermore, Oladimeji et al33<\/a><\/sup> prepared epigallocatechin gallate (EGCG)-coated gold nanoparticles (AuNPs), followed by grafted BA onto AuNPs via a Steglich esterification reaction. Subsequently, the nanoparticles were further coated with poly-L-lysine-graft-polyethylene glycol (PLL-g-PEG) and conjugated with the lipophilic molecule triphenylphosphine (TPP+<\/sup>), resulting in the formulation T-Au-[PLL-g-PEG]-BA. EGCG exhibits high affinity for the 67 kD laminin receptor on mitochondria, allowing selective uptake of T-Au-[PLL-g-PEG]-BA by 67 kD laminin receptor-overexpressing tumor cells. Cytotoxicity assays conducted on Caco-2, HeLa, and MCF-7 cells revealed that the IC50<\/sub> values of T-Au-[PLL-g-PEG]-BA were 3.12, 3.26, and 13.13 \u03bcM, respectively, while the IC50<\/sub> values of free BA were 9.74, 17.73, and 36.31 \u03bcM, indicating the significant anti-tumor effect of T-Au-[PLL-g-PEG]-BA. Further mechanistic studies demonstrated that T-Au-[PLL-g-PEG]-BA achieved substantial inhibition of cancer cell growth through mitochondrial depolarisation, activation of caspases 3\/7, and blockade of the G0\/G1 phase of the cell cycle.<\/p>\n

Polymeric Nanoparticles<\/h3>\n

Polymeric nanoparticles composed of hydrophobic and hydrophilic fragments, featuring nanoscale size, high volumetric surface area ratio, and tunable pores, have emerged as pivotal materials in drug delivery.54<\/a><\/sup> On this basis, Tao et al35<\/a><\/sup> used Ginkgo biloba Leaves polyprenol and D-\u03b1-tocopherol polyethylene glycol 1000 succinate (Vitamin E-TPGS) to construct a core-shell structure and prepared polymeric nanoparticles co-loaded with BA and low-substituted hydroxyl fullerenol (C60<\/sub>(OH)n<\/sub>). TPGS, with its hydrophilic polar head and lipophilic alkyl tail, enhanced the apparent solubility of BA. These nanoparticles effectively suppressed the proliferation of MHCC97H cells by up-regulating the expression of Caspase-3, Caspase-8, and Caspase-9. Moreover, Dai et al36<\/a><\/sup> prepared cellulose-graft-poly(L-lactic acid) nanoparticles loaded with BA (CE-g-PLLA\/BA NPs), which exhibited excellent biocompatibility. The tumor inhibition rate of mice in the CE-g-PLLA\/BA NPs group reached 79.8%, markedly surpassing the 46.7% observed in the free BA group, demonstrating enhanced anti-tumor activity. Kumar et al37<\/a><\/sup> formulated PLGA nanoparticles loaded with BA (BNP) via an emulsion solvent evaporation method. Compared with free BA, BNP prolonged the half-life of BA, elevated blood concentration, and enhanced oral bioavailability, resulting in significant inhibition of HepG2 proliferation. Further studies revealed that BNP induced cell apoptosis by activating the caspase-mediated mitochondrial apoptotic pathway.13<\/a><\/sup><\/p>\n

Under specific conditions, polymeric nanoparticles can achieve responsive release of BA. Zhang et al38<\/a><\/sup> developed folate (FA) receptor-targeted polymeric prodrug nanoparticles linked by \u03b2-thiopropionate bonds through self-assembly. In the acidic pH of the TME, the \u03b2-thiopropionate bonds undergo hydrolysis, enabling responsive release of BA. In another study, Zhu et al39<\/a><\/sup> utilized ferrocene-modified BA to form host-guest complexes with water-soluble pillar[6]arene and encapsulated glucose oxidase (GOx), resulting in glutathione (GSH)\/ROS dual-responsive supramolecular nanoparticles (GOx@BNPs). Activation of GOx@BNPs by overexpressed GSH and ROS in the TME enhanced the release of BA. Furthermore, GOx catalyzed the conversion of glucose to gluconic acid and H2<\/sub>O2<\/sub>, where H2<\/sub>O2<\/sub> further underwent a Fenton reaction with ferrocene to generate highly active hydroxyl radicals, exerting potent anti-tumor effects. This enables a multimodal synergistic treatment involving chemodynamic therapy (CDT), starvation therapy, and chemotherapy.<\/p>\n

Co-delivery of multiple anti-tumor drugs using polymeric nanoparticles can achieve synergistic effects. Saneja et al40<\/a><\/sup> employed PLGA-mPEG nanoparticles as carriers and co-encapsulated gemcitabine (GEM) and BA to produce combination nanoparticles (GEM + BA NPs). These nanoparticles notably reduced the IC50<\/sub> value against Panc1 cells and displayed significantly higher anti-tumor efficiency compared to the free drugs. In a separate investigation, Dai et al41<\/a><\/sup> initially synthesized 8arm-PEG-BA by coupling BA with eight-arm-polyethylene glycol carboxylic acid (8arm-PEG-COOH) via an esterification reaction. Subsequent conjugation FA and loading with hydroxycamptothecin (HCPT) yielded F-8arm-PEG-BA\/HCPT nanoparticles, which extended the circulation half-life of BA in the bloodstream. Compared with free BA, F-8arm-PEG-BA\/HCPT nanoparticles exhibited a 76.3-fold increase in cytotoxicity against LLC cells and a 102.6-fold increase against A549 cells, showing significant synergistic effects. Moreover, the PEG shell improved the water solubility of the nanoparticles, while the incorporation of FA conferred tumor-targeting capability. Lu et al42<\/a><\/sup> employed ethylenediamine-\u03b3-cyclodextrin (EGCD) as carriers to encapsulate BA, followed by grafting with gelatin to synthesize BA\/GGCD. Using oxidized dextran as a crosslinking agent, BA\/GGCD was crosslinked on the surface of the TiO2<\/sub> precursor to form a hydrogel (BA\/GGNPs) (Figure 1<\/a>). The introduction of \u03b3-cyclodextrin increased the solubility of BA. BA\/GGNPs achieved targeted drug delivery to tumor cells via specific recognition of the RGD sequence, together with the enhanced permeability and retention effect of nanoparticles, resulting in dual-targeting of tumors. In in vivo experiments, BA\/GGNPs exhibited excellent tumor inhibition effects, with minimal tumor volume observed in 4T1 tumor-bearing mice after 14 days of treatment, which was further confirmed by histological analysis of tumor slices.\n<\/p>\n\n\n\n
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Figure 1<\/strong> Schematic illustration depicting the fabrication process of dual-targeted nanoparticles loaded with BA (BA\/GGNPs). ACS Appl Bio Mater.<\/p>\n

Notes:<\/strong> Reprinted from Lu S, Fan X, Wang H et al. Synthesis of gelatin-based dual-targeted nanoparticles of betulinic acid for antitumor therapy. ACS Appl Bio Mater<\/em>. 2020;3(6):3518\u20133525. Copyright 2020, with permission from the American Chemical Society.42<\/a><\/sup>Abbreviations:<\/strong> EGCD: ethylenediamine-\u03b3-cyclodextrin; GGCD: the compound of gelatin grafted with EGCD; BA\/GGNPs: betulinic acid\/gelatin-\u03b3-cyclodextrin nanoparticles.<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Other Nanoparticles<\/h3>\n

The application of green chemistry in NDDSs aims to reduce the utilization of toxic reagents and materials during the preparation process of nanoparticles, thereby minimizing adverse effects on human health and the environment.44<\/a><\/sup> Self-assembled nanoparticles are stable structures spontaneously formed by organic molecules through non-covalent supramolecular forces, such as hydrophilic-hydrophobic interactions, electrostatic interactions, hydrogen bonds, van der Waals forces, and host-guest interactions. In recent years, nanocarriers derived from natural small molecules with self-assembly capabilities can greatly reduce the use of toxic reagents and exhibit remarkable potential in tumor therapy.<\/p>\n

Intermolecular hydrogen bonding can drive the self-assembly of BA. Li et al27<\/a><\/sup> synthesized BA self-assembling nanoparticles (BA NPs), which can inhibit the Akt\/NF\u03baB-p65 signaling pathway via CB1\/CB2 receptors, arrest the cell cycle at the G0\/G1 phase, and effectively induce apoptosis. In a mouse model of intracranial glioblastoma, BA NPs could effectively cross the blood-brain barrier and significantly prolong the mice\u2019s survival time. Disulfide bond-driven redox-responsive nanoparticles provide a way to link BA with other drugs. \u00d6zdemir et al48<\/a><\/sup> connected porphyrin derivative (P) with BA via a disulfide bond to obtain redox-responsive nanoparticles (NanoP-ss-BA). In the TME, higher concentrations of GSH triggered disulfide bond cleavage, releasing P and BA, and restoring the photoreactivity of P, thereby promoting ROS production. The zeta potential of NanoP-ss-BA was \u201322 mV, which contributes to prolonging its circulation half-life and providing excellent stability under physiological conditions. NanoP-ss-BA demonstrated notable chemotoxicity and phototoxicity against cancer cells, which effectively improved the anti-tumor effect of BA. BA can also form conjugates with other components before self-assembly. For example, Dai et al45<\/a><\/sup> utilized BA as a hydrophobic anti-cancer core to form a conjugate with a hydrophilic shell composed of carboxymethylcellulose (CMC) and PEG-FA and encapsulated HCPT to obtain self-assembled targeted nanoparticles with synergistic anti-tumor effects.<\/p>\n

Through co-assembly strategies, better control over the physical size and morphology of the nanocarriers can be achieved to construct multifunctional nano-delivery platforms for synergistic anti-tumor therapy.55<\/a><\/sup> In this regard, Fu et al46<\/a><\/sup> initially co-assembled oleanolic acid (OA) and BA, and co-encapsulated Cu2+<\/sup> and photosensitizers chlorin e6 (Ce6). Subsequently, the nanoparticles were coated with 4T1 cell membranes to yield CM@OABACe6\/Cu nanoparticles. The wrapping of the tumor cell membranes endowed the nanoparticles with excellent homologous tumor targeting, whereas the combination of BA and Ce6 synergistically provided effective chemotherapy and photodynamic therapy (PDT). Considering that the overexpression of GSH in the tumor site partially scavenges ROS, the introduced Cu2+<\/sup> can deplete GSH through redox reactions, thus reducing the impact on the PDT effect. In addition, Cu2+<\/sup> can undergo a Fenton-like reaction with overexpressed H2<\/sub>O2<\/sub> in the TME, further augmenting the therapeutic effect. Thus, CM@OABACe6\/Cu nanoparticles achieved tumor targeting and triple synergistic treatment involving chemotherapy, PDT, and CDT. As presented in Figure 2A<\/a>, Cheng et al47<\/a><\/sup> coupled BA with water-soluble chitosan oligosaccharide (COS) to synthesize amphiphilic COS-BA. Then, a direct co-assembly strategy was employed to introduce the photosensitizer Ce6, constructing water-soluble carrier-free photochemical therapeutic precursors, COS-BA\/Ce6 nanoparticles. These nano precursors remained in a \u201cdormant\u201d state in normal tissues but could be activated at the tumor site. Additionally, COS exhibited excellent pH responsiveness and could enhance the immune function of the host by modulating immune cell activity. COS-BA\/Ce6 nanoparticles not only enhanced singlet oxygen production but also effectively increased the amount of tumor-derived antigens presented to T cells by combining chemotherapy and PDT. Under the mediation of immune adjuvant anti-PD-L1, COS-BA\/Ce6 nanoparticles effectively activated systemic anti-tumor immune response, achieving efficient synergy among chemotherapy, PDT, and immunotherapy. In in vivo experiments, 4T1 cells were inoculated on both sides of each mouse. When laser irradiation was performed on only one side of the tumor, both chemotherapy and PDT based on COS-BA\/Ce6 nanoparticles effectively activated anti-tumor immunity. After combining with anti-PD-L1 treatment, significant inhibition of the unirradiated side tumors was observed (Figures 2B-2H<\/a>).\n<\/p>\n\n\n\n
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Figure 2<\/strong> (A<\/strong>) Schematic diagram of the preparation process and mechanism of COS-BA\/Ce6 nanoparticles, showcasing triple synergistic treatment involving chemotherapy, PDT, and immunotherapy. (B<\/strong>) Flowchart of COS-BA\/Ce6 nanoparticles-based chemotherapy\/PDT with anti-PD-L1 therapy. (C<\/strong>) Tumor growth curves, (D<\/strong>) mean tumor weights, and (E<\/strong>) excised tumor images of the laser-irradiated side of mice after 14 days of treatment. (F<\/strong>) Tumor growth curves, (G<\/strong>) mean tumor weights, and (H<\/strong>) excised tumor images on the unirradiated side of the mice. *P<\/em> < 0.05, **P<\/em> < 0.01, and ***P<\/em> < 0.001 indicate the statistical significances among groups. Reprinted from Cheng J, Zhao H, Li B et al. Photosensitive pro-drug nanoassemblies harboring a chemotherapeutic dormancy function potentiates cancer immunotherapy. Acta Pharm Sin B.<\/em> 2023;13(2):879\u2013896.47<\/a><\/sup><\/p>\n

Abbreviations:<\/strong> COS: chitosan oligosaccharide; Ce6: chlorin e6; CTL: cytotoxic T lymphocytes; PDT: photodynamic therapy.<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

BA-Loaded Liposomes<\/h2>\n

Liposomes represent a promising drug delivery system constructed based on lipid bilayers. Encapsulation of hydrophobic drugs within the phospholipid bilayer enhances their solubility, stability, and bioavailability. Table 2<\/a> provides an overview of liposomes loaded with BA. Liu et al56<\/a><\/sup> efficiently synthesized PEGylated BA liposomes through the ethanol injection method. The incorporation of PEG facilitated the formation of an aqueous shell and spatial barriers, resulting in enhanced drug accumulation. In vitro release studies demonstrated that PEGylated BA liposomes exhibited sustained drug release. Moreover, cocktail therapy, involving the combination of three or more drugs to reduce resistance, has been explored within liposomal systems. Jin et al11<\/a><\/sup> prepared cocktail liposomes co-loaded with four natural products, including BA, parthenolide, honokiol, and ginsenoside Rh2, which effectively arrested the G2\/M phase of the lung cancer cell cycle. In vivo experiments demonstrated superior tumor inhibition rates with the cocktail liposomes compared to individual agents. Intervention in metabolic pathways also has become a noteworthy strategy in tumor therapy. Wang et al57<\/a><\/sup> utilized a liposomal delivery system to encapsulate BA, yielding BA-NLs for the treatment of colorectal cancer (CRC). Further studies clarified that BA-NLs inhibit key enzymes in glycolysis, including HK2, PFK-1, PEP, and PKM2, as well as key enzymes in fatty acid metabolism, such as ACSL1, CPT1a, and PEP, thereby exerting a therapeutic effect on CRC.\n<\/p>\n\n\n\n
\"\"<\/a><\/td>\n\n

Table 2<\/strong> Summary of BA-Loaded Liposomes<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

It has been observed that temperatures of 41\u201345 \u00b0C can markedly reduce the viability of tumor cells,67<\/a><\/sup> thus rendering hyperthermia a focal point in tumor treatment. Magnetic nanoparticles possess the capability to generate heat under an applied magnetic field, achieving hyperthermia in tumor cells.68<\/a><\/sup> Within this context, Farcas et al58<\/a><\/sup> successfully synthesized magnetic iron oxide nanoparticles coated with citric acid (MIONPs*CA) by the combustion method, using iron nitrate nonahydrate and citric acid monohydrate. Subsequently, they prepared BA-loaded magnetic liposomes (Lip+MIONPs*CA+BA) using a thin-layer hydration method, which possessed superparamagnetic characteristics and heating abilities. Upon exposure to hyperthermia, these magnetic liposomes underwent a phase transition from gel to liquid, effectively releasing BA and MIONPs for anti-tumor purposes. Additionally, under elevated temperature conditions, the nuclear membrane of MDA-MB-231 cells displayed blistering and morphological alterations, and its microtubule assembly was disrupted, demonstrating the regulatory influence of Lip+MIONPs*CA+BA on microtubule assembly. Further cytotoxicity assays indicated the enhanced anti-tumor efficacy of the magnetic liposomes against MDA-MB-231 cells induced by hyperthermia, which exhibited greater sensitivity and selective cytotoxicity compared to MCF7 cells.<\/p>\n

Photothermal therapy (PTT) is a non-invasive, highly controllable, and precise treatment modality with considerable promise. By modifying targeted ligands on the surface of photothermal materials, active accumulation of drugs in the tumor region can be achieved. Upon near-infrared (NIR) light irradiation, these materials can efficiently convert absorbed light energy into heat, thereby inducing tumor cell death.69<\/a><\/sup> Gold-based nanomaterials are promising therapeutic agents owing to their exceptional photothermal response properties. Liu et al59<\/a><\/sup> initially encapsulated BA into liposomes and then seeded Au nanoparticles onto the surface of GSH-modified liposomes via Au-S bonds. Subsequently, they produced gold nanoshell-coated BA liposomes (AuNS-BA-Lips) through the growth of gold nanoshells in a solution containing AuCl3<\/sub> and NaBH4<\/sub>. These constructs exhibited the ability to be heated up to 43 \u00b0C under NIR irradiation and possessed excellent photothermal conversion efficiency. In vitro experiments demonstrated that NIR-excited AuNS-BA-Lips promoted drug uptake by tumor cells, consequently increasing intracellular drug accumulation. Further, in vivo experiments showed that AuNS-BA-Lips exerted remarkably effective anti-tumor effects in mice with tumors, exhibiting an inhibition rate of 83.02%, significantly surpassing the 31.1% inhibition rate observed in the free BA group. These findings suggest that AuNS-BA-Lips possess substantial synergistic therapeutic effects combining chemotherapy and thermotherapy.<\/p>\n

Bimetallic nanomaterials based on gold have garnered significant interest owing to their superior stability and enhanced photothermal conversion capabilities compared to monometallic particles. Liu et al60<\/a><\/sup> used multibranched Au-Pd bimetallic nanoflowers encapsulated with BA liposomes, which provided a high surface area and reactive dendritic tips. The resulting BA-Lips@Pd@Au NFs displayed outstanding photostability and achieved up to 64.6% photothermal conversion efficiency under NIR irradiation, which effectively facilitated their intracellular uptake and demonstrated notable chemo-PTT synergistic therapeutic effects.<\/p>\n

The specificity and anti-tumor effect of liposomes on tumor cells can be improved by targeted modifications. Common ligands for targeted modifications include hyaluronic acid (HA), FA, and tumor cell membranes, among others. Wu et al61<\/a><\/sup> prepared HA-modified BA liposomes (HA-BA-L) using electrostatic interactions. In vitro studies revealed that HA-BA-L inhibited the proliferation of both HepG2 and SMMC-7721 cells more effectively compared to free BA or BA liposomes without HA modification, suggesting its targeted anti-tumor effect. Western blotting results suggested that HA-BA-L inhibited HepG2 cell proliferation by down-regulating intracellular ROCK1, IP3, and RAS expression. FA, a commonly utilized targeting ligand, has demonstrated advantages in improving the efficiency of drug delivery in liposomes. Guo et al62<\/a><\/sup> successfully prepared FA-functionalized liposomes (FA-L-BA) with targeting ability using FA-PEG3400-cholesterol conjugate. Toxicity assays on HepG2 cells revealed that FA-L-BA displayed stronger cytotoxicity than non-targeted liposomes, demonstrating its targeted anti-tumor effect. In another study, Li et al63<\/a><\/sup> successfully developed F\/CL@BM by co-encapsulating celastrol (CEL) and BA-loaded micelles into liposomes and introducing FA for targeted modification (Figure 3A<\/a>). FA targeting facilitated drug concentration at the tumor site and sequentially released CEL and BA. CEL can inhibit cancer-associated fibroblasts (CAFs) signal transduction, suppress fibrosis, induce apoptosis in CAFs, and help reverse tumor resistance to BA. Compared with treatment with the free drug, mice in the F\/CL@BM group exhibited a substantial reduction in the number of lung nodules, showing enhanced anti-tumor metastatic effects. Further, in vivo experiments in mice confirmed that F\/CL@BM possessed a stronger ability to inhibit tumor growth and could effectively achieve synergistic anti-tumor effects (Figures 3B-3C<\/a>). Moreover, the strategy of using tumor cell membrane-encapsulated liposomes can effectively combine the advantages of tumor targeting and improved biocompatibility.70<\/a><\/sup> Chen et al64<\/a><\/sup> utilized HeLa cell membranes as highly penetrating targeting ligands, and functionalized BA liposomes exhibited significantly enhanced therapeutic efficacy by specifically targeting homologous tumor cells.\n<\/p>\n\n\n\n
\"\"<\/a><\/td>\n\n

Figure 3<\/strong> (A<\/strong>) Schematic diagram of the assembly and mechanism of FA-coated micelles-in-liposomes encapsulating BA and CEL (F\/CL@BM) for targeted accumulation at tumor sites and induction of apoptosis in tumor-associated fibroblasts and tumor cells. (B<\/strong>) Representative lung tissue sections stained with hematoxylin and eosin (scale bar: 50 \u03bcm). (C<\/strong>) Representative photographs of excised lungs, with tumor nodules circled in yellow. Reprinted from Li C, Wang Z, Zhang Y et al. Efficient sequential co-delivery nanosystem for inhibition of tumor and tumor-associated fibroblast-induced resistance and metastasis. Int J Nanomed<\/em>. 2024;19:1749\u20131766.63<\/a><\/sup><\/p>\n

Abbreviations:<\/strong> ROS: reactive oxygen species; TPGS: Vitamin E derivative D-\u03b1-tocopherol polyethylene glycol 1000 succinate; BM: BA-loaded micelles; SPC: soybean phospholipid; CHOL: cholesterol; CEL: celastrol; DSPE-PEG-FA: 1.2-distearoyl-sn-glycero-3-phosphoethanolamine-N-[methoxy (polyethylene glycol)-2000]-folic acid; CAFs: cancer-associated fibroblasts; CL: liposomes loaded with CEL.<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Targeted anti-tumor effects can also be achieved by taking advantage of the weak acidity of the TME. Wang et al65<\/a><\/sup> prepared pH-responsive BA-loaded liposomes (pH-BA-LP) by encapsulating BA into nano-liposomes and introducing Eudragit S100 as an acid-sensitive component. These liposomes exhibited the ability to suppress tumor growth by modulating the Akt\/TLR signaling pathway, effectively reducing the migration rate of CRC cells and remarkably down-regulating the expression of NFAT1 and NFAT4 proteins. Additionally, pH-BA-LP demonstrated the capability to enhance the proportion of NK cells and CD3+<\/sup> cells in tumor tissues, thus bolstering the autoimmune response and exerting anti-tumor effects.<\/p>\n

BA-Loaded Micelles<\/h2>\n

Polymer micelles are characterized by their small particle size, which enhances drug solubility, as well as high permeability and retention in tumor tissues, thereby mitigating toxicity.71<\/a>,72<\/a><\/sup> Table 3<\/a> presents a summary of micelles loaded with BA. Jin et al73<\/a><\/sup> co-loaded DOX and BA into a pH-sensitive peptide derivatives\/DSPE-PEG2000 micelle system. PEGylation prolonged the blood circulation of DOX\/BA micelles and improved their accumulation at the tumor site. Upon encountering the acidic TME, the micelles underwent a rapid structural transformation, facilitating efficient drug uptake by tumor cells and stimulating anti-tumor activity. The tumor volume of the DOX\/BA micelles group was smaller compared to the free DOX\/BA group, suggesting stronger tumor inhibition. Soluplus\u00ae<\/sup>, an amphiphilic polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol (PVCL-PVA-PEG) graft copolymer, self-assembles to form micelles for drug encapsulation, thereby increasing drug solubility and stability.74<\/a><\/sup> In another study, Qi et al75<\/a><\/sup> prepared Soluplus\u00ae<\/sup>-encapsulated BA micelles (Soluplus\u00ae<\/sup>-BA), where the carbonyl group of Soluplus\u00ae<\/sup> formed a hydrogen bond with the hydroxyl group of BA, significantly enhancing its solubility and stability. At a weight ratio of 14:1 for Soluplus\u00ae<\/sup> and BA, micellar encapsulation reached up to 100%, which effectively avoided drug loss. Soluplus\u00ae<\/sup>-BA markedly enhanced the anti-tumor effect by increasing the accumulation of intracellular ROS in MDA-MB-231 cells, disrupting mitochondrial membrane potential, and inducing DNA double-stranded breaks. In addition, Soluplus\u00ae<\/sup>-BA inhibited angiogenesis through modulation of the HIF-1\/VEGF-FAK signaling pathway, exerting a multi-mechanism anti-breast cancer effect.\n<\/p>\n\n\n\n
\"\"<\/a><\/td>\n\n

Table 3<\/strong> Summary of Micelles Loaded with BA<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

The concentration of GSH in tumor tissues is about 3\u20134 times higher than the normal tissues, facilitating the cleavage of disulfide bonds through redox reactions,80<\/a><\/sup> which enabled precise drug release at tumor sites. Zhang et al76<\/a><\/sup> conjugated BA to PEG polymers via a breakable disulfide bond, successfully preparing a redox-responsive precursor of BA (mPEG2K<\/sub>-SS-BA). This conjugation significantly enhanced the saturated solubility of BA, increasing it to 5.7 mg\/mL, more than 270 times that of free BA. Subsequently, they formulated P-SS-BA\/F68-Cy micelles by self-assembling mPEG2K<\/sub>-SS-BA with F68-Cy copolymer coupled with the NIR reagent Cypate. Such micelles exhibited stable colloids with a low critical aggregation concentration. In the high GSH concentration of the TME, P-SS-BA\/F68-Cy responsively released BA and exhibited a robust photothermal effect under NIR irradiation, achieving dual-responsive drug delivery and thermo-chemo-therapeutic synergistic treatment. In a study conducted by Qu et al,77<\/a><\/sup> PEG5k<\/sup>-BA4<\/sub> was synthesized by conjugating BA to the dendrimeric molecular structure of PEG5k<\/sup> via hydrolyzable ester bonds. Subsequently, they cross-linked thiolated dendrimer PEG5k<\/sup>-Cys4<\/sub>-L8<\/sub>-CA8<\/sub> with PEG5k<\/sup>-BA4<\/sub> via disulfide bonds and loaded paclitaxel (PTX) under O2<\/sub> mediation, resulting in structurally stable, program-responsive cross-linked micelles (PDCM@PTX) for co-delivery of BA and PTX. The disulfide bonds and hydrolyzable ester bonds within PDCM@PTX micelles enable programmed responses to the overexpressed GSH in the TME and esterases in tumor cells, triggering the release of BA and PTX, thereby demonstrating significant therapeutic effects against multidrug-resistant ovarian cancer. Gautam et al78<\/a><\/sup> prepared novel redox-sensitive micelles (PX\/BA-Cys-T-HA) with HA as a targeting ligand, encapsulating BA and PTX, which specifically bound to the CD44 receptor highly expressed on the surface of MDA-MB-231 cells, thereby enhancing micelle uptake (Figures 4A-4B<\/a>). In the TME, characterized by high GSH concentration, the disulfide bond underwent cleavage, leading to aggregation or disassembly of the micelles, thereby promoting the release of BA and PTX. In MDA-MB-231 cells, PX\/BA-Cys-T-HA substantially enhanced cell cycle arrest, improved depolarization of mitochondrial membrane potential, and stimulated the overproduction of ROS. Moreover, in the 4T1 tumor-bearing mouse model, these targeted micelles demonstrated notable tumor growth inhibition (Figures 4C-4D<\/a>).\n<\/p>\n\n\n\n
\"\"<\/a><\/td>\n\n

Figure 4<\/strong> (A<\/strong>) Flowchart illustrating the preparation of PX\/BA-Cys-T-HA micelles. (B<\/strong>) Cellular uptake studies by confocal imaging of FITC-labelled PX\/BA-Cys-T-HA acting on MDA-MB-231 cells after 1 and 6 h (scale bar: 50 \u03bcm). (C<\/strong>) Tumor morphology collected at the end of the in vivo experiment. (D<\/strong>) Tumor volume (mm3<\/sup>) plotted against time (days). ns, not significant; ****P<\/em> < 0.0001 indicate the statistical significances among groups. Reprinted from Gautam S, Marwaha D, Singh N et al. Self-assembled redox-sensitive polymeric nanostructures facilitate the intracellular delivery of paclitaxel for improved breast cancer therapy. Mol Pharm<\/em>. 2023;20(4):1914\u20131932. Copyright 2023, adapted with permission from the American Chemical Society.78<\/a><\/sup><\/p>\n

Abbreviations:<\/strong> TPGS: D-\u03b1-tocopheryl poly(ethylene glycol) succinate; Cys: cystamine; PX: paclitaxel; HA: hyaluronic acid.<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Other Nano-Scale Drug Delivery Systems for BA<\/h2>\n

Other nano-scale drug delivery systems for BA loading encompass nanotubes, nanogels, nanofibers, microcapsules, nanocolloids, and nanosuspensions (Table 4<\/a>). These nanoformulations have demonstrated varying degrees of enhancement in the anti-tumor activity of BA.\n<\/p>\n\n\n\n
\"\"<\/a><\/td>\n\n

Table 4<\/strong> Other Nano-Scale Drug Delivery Systems for BA<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Nanotubes<\/h3>\n

Carbon nanotubes possess a unique three-dimensional tubular structure composed of carbon atoms with sp2<\/a><\/sup> hybridization. Their remarkable characteristics, including ultra-lightweight, high specific surface area, and excellent biocompatibility, position them as innovative nanocarriers in drug delivery.91<\/a><\/sup> In a study performed by Tan et al,81<\/a><\/sup> MWCNT-BA was synthesized by effectively attaching BA to the outer wall of oxidized multiwalled carbon nanotubes (MWCNT-COOH) via \u03c0-\u03c0 stacking, resulting in delayed release of BA. In vitro assays demonstrated that the IC50<\/sub> values of the MWCNT-BA group against A549 and HepG2 cell lines were 2.7 and 11.0 \u03bcg\/mL, respectively, significantly lower than those of 3.5 and 15.0 \u03bcg\/mL in the free BA group, indicating enhanced anti-cancer activity. To improve biocompatibility while preserving the activity of BA, the same team92<\/a><\/sup> further synthesized BA-loaded single-walled carbon nanotubes (SWBA) and coated SWBA with Tween 20 (T20), Tween 80 (T80), PEG, and chitosan (CHI), respectively. Compared with uncoated SWBA, all three surface-modified SWBA, except SWBA-PEG, exhibited slow and sustained drug release characteristics. In toxicity tests on mouse embryonic fibroblasts (3T3), SWBA-T20, SWBA-T80, and SWBA-CHI demonstrated excellent biocompatibility, while SWBA-PEG exhibited relatively higher cytotoxicity. This result is consistent with the drug release patterns of the four biopolymers, confirming the significant influence of drug release and surface coating on the cytotoxicity of nanocarriers.<\/p>\n

Nanogels<\/h3>\n

Hydrogels are multifunctional materials consisting of three-dimensional polymer networks capable of releasing drugs through structural alterations. However, hydrogels typically display poor loading capacity for hydrophobic drugs.93<\/a><\/sup> In contrast, polymer nanoparticles possess high drug-loading efficiency and extended plasma half-life.94<\/a><\/sup> Therefore, combining polymer nanoparticles with hydrogels can substantially improve drug delivery efficiency.<\/p>\n

Dai et al82<\/a><\/sup> initially loaded BA onto CMC to obtain the amphiphilic prodrug CMC-BA, which then self-assembled with HCPT to form nanoparticles. Subsequently, these nanoparticles were further combined with \u03b1-cyclodextrin (\u03b1-CD) to create a cellulose hydrogel drug delivery system (CMC-BA\/HCPT nanoparticles\/\u03b1-CD) by host-guest encapsulation. This hydrogel exhibited thermo-sensitivity, allowing for reversible gel-sol phase transition at specific temperatures, enabling precise control of drug release. In vitro and in vivo investigations demonstrated that the CMC-BA\/HCPT nanoparticles\/\u03b1-CD hydrogel exhibited superior therapeutic efficacy over free drugs with enhanced anti-tumor capabilities. Furthermore, the same team explored the substitution of CMC with 8arm-PEG-COOH, which was coupled with BA through esterification to yield 8arm-PEG-BA. Subsequently, this compound self-assembled with HCPT to form micelles, followed by mixing with \u03b1-CD to prepare a novel injectable supramolecular hydrogel (8arm-PEG-BA\/HCPT hydrogel). In vitro experiments revealed that 8arm-PEG-BA\/HCPT hydrogel exerted the strongest cytotoxicity, attributed to the slow drug release. Additionally, in vivo studies confirmed the enhanced anti-tumor efficacy of this hydrogel compared to free drugs and BA\/HCPT-loaded micelles.83<\/a><\/sup> Thus, injectable hydrogels with unique structures and temperature responsiveness hold promise as potential candidates for the smart delivery of natural drugs.<\/p>\n

Nanofibers<\/h3>\n

In the field of tumor therapy research, Dash et al84<\/a><\/sup> developed nanofibers by coupling PEG with depolymerized BA self-assembled fibers (SA-BA), followed by the introduction of FA to augment targeting ability. The resultant FA-PEG-SA-BA exhibited excellent biocompatibility and could be significantly internalized by FA receptor-overexpressing K562 cells, thereby demonstrating selective cytotoxicity. Further investigations revealed95<\/a><\/sup> that the cytotoxicity of SA-BA was achieved by altering the cellular redox balance, disrupting mitochondrial outer membrane potential, increasing pro-inflammatory cytokine secretion, and enhancing tumor necrosis factor \u03b1-mediated cell death. Additionally, immunocytochemical studies affirmed that SA-BA could activate the expression of caspase-8 and caspase-3, thereby inducing apoptosis in leukemia cell lines.<\/p>\n

In addition to its anti-tumor effects, SA-BA also acts as an immune adjuvant, exerting anti-tumor effects by stimulating macrophages. The same team85<\/a><\/sup> further investigated the immunomodulatory activity of SA-BA. Macrophages pulse-treated with SA-BA exhibited elevated secretion of pro-inflammatory cytokines, enhanced CD4+<\/sup> T-lymphocyte proliferation, significant T-cell stimulating ability, and promoted the production of cytotoxic T-lymphocytes (CTLs). Activated CTLs further demonstrated enhanced tumor cell-killing ability. DOX is a commonly used drug in tumor therapy but exhibits high toxicity to peripheral blood lymphocytes (PBLs). This team96<\/a><\/sup> found that pretreatment with SA-BA significantly decreased pro-inflammatory cytokine levels, improved anti-inflammatory capacity, and protected PBLs from DOX-induced inflammatory responses, thus reducing adverse reactions of DOX. In conclusion, SA-BA not only inhibits tumor cell proliferation but also activates the immune response to suppress tumors while potentially preventing chemotherapy-related serious adverse reactions.<\/p>\n

Microcapsules<\/h3>\n

Nanocapsules\/microcapsules are characterized by high loading capacity, controlled drug release, and targeting ability. Meanwhile, abundant and renewable polysaccharides such as chitosan, alginate, and galactomannan possess excellent biocompatibility and biodegradability. Combining these polysaccharides with nanocapsules\/microcapsules yields polysaccharide-based delivery systems, whose dense outer shells can effectively protect the inner core, thereby improving drug delivery efficiency.97<\/a><\/sup> In this context, Rebou\u00e7as et al86<\/a><\/sup> initially formulated nano-emulsions co-loaded with BA and hesperidin by rotary evaporation method, which were further homogeneously mixed with aqueous solutions of alginate and guar gum polysaccharides to obtain polysaccharide microcapsules. Compared with free drugs, these microcapsules exhibited sustained drug release, selective toxicity against tumor cells, and reduced toxicity to non-tumor cells. This improvement in drug safety underscores the potential of polysaccharide-based microcapsules in the field of drug delivery.<\/p>\n

Nanocolloids<\/h3>\n

Silver nanoparticles (Sil NPs) play an important role in the biomedical field owing to their distinctive physicochemical and biological properties. In particular, Sil NPs exhibit remarkable anti-tumor effects primarily by disrupting the mitochondrial respiratory chain and promoting ROS production.98<\/a><\/sup> Studies have indicated that combining BA with Sil NPs can further potentiate their anti-tumor ability. In a study conducted by Pinzaru et al,87<\/a><\/sup> silver nano colloids (SilCo) were successfully synthesized by continuously stirring a mixture comprising trisodium citrate, sodium lauryl sulfate, and silver nitrate solution at 80 \u00b0C for 30 min. Subsequently, SilCo was loaded with BA to generate SilCo_BA. Cytotoxicity assessments performed on HepG2 cells revealed a cell survival rate of 75.30% in the free BA group, while it decreased to 66.44% in the SilCo_BA group, suggesting an enhanced anti-tumor effect of BA.<\/p>\n

Nanosuspensions<\/h3>\n

Nanosuspensions refer to nano-sized particles composed solely of pure drugs without any matrix materials and represent an effective strategy to improve the bioavailability of natural drugs.99<\/a><\/sup> In this regard, Li et al88<\/a><\/sup> successfully prepared BA nanosuspensions (BA-NS) in a stable amorphous state using an anti-solvent precipitation method. The use of sodium dodecyl sulfate and polyvinyl pyrrolidone K29-32 as stabilizers significantly improved the water solubility of BA. BA-NS exhibited pH-dependent release characteristics, with the release of BA increasing with pH. In addition, BA-NS exhibited enhanced cytotoxicity against HeLa, A549, and HepG2 cells, thereby augmenting the in vitro antiproliferative effect on tumor cells.<\/p>\n

Furthermore, Wang et al89<\/a><\/sup> developed PTX-BA hybrid nanosuspensions (PTX-BA-NP), which co-loaded BA and PTX in the form of nanocrystals. This approach improved the solubility of both drugs and achieved synergistic therapeutic effects against breast cancer. To further investigate the impact of particle size on the anti-breast cancer efficacy of BA-NS, they90<\/a><\/sup> employed the high-pressure homogenization method to prepare BA-NS with particle sizes of 160, 400, and 700 nm, respectively. Results indicated that BA-NS with a size of 160 nm exhibited a superior drug release rate and bioavailability than the larger particle sizes. It was found that BA-NS could be effectively internalized by 4T1 cells, resulting in higher levels of intracellular accumulation. Moreover, the combination of 160 nm-sized BA-NS and Taxol\u00ae<\/sup> demonstrated enhanced anti-tumor ability, effectively exerting a synergistic anti-tumor effect. This series of studies not only confirmed the potential of nanosuspensions in enhancing drug bioavailability but also highlighted the importance of optimizing the anti-tumor activity of nanoparticles by controlling their particle size.<\/p>\n

Summary and Outlook<\/h2>\n

BA holds promising application prospects due to its outstanding anti-tumor activity, but its clinical utilization is greatly hindered by issues such as poor solubility, low bioavailability, and potential off-target toxicity. To overcome these drawbacks, researchers have encapsulated BA into diverse nanocarriers, including nanoparticles, liposomes, polymer micelles, nanotubes, nanogels, nanofibers, and nanosuspensions. These nanoformulations have demonstrated excellent therapeutic effects against a diverse range of tumors, as depicted in Figure 5A<\/a>. Notably, breast cancer (22.97%) and lung cancer (21.67%) have received the most attention, followed by liver cancer (16.22%) and cervical cancer (10.81%). Over the past decade, research on BA-loaded nanoformulations for tumor treatment has continued to progress, as illustrated in Figure 5B<\/a>. These nanoformulations not only substantially enhanced the solubility and bioavailability of BA but also greatly improved its anti-tumor activity through strategies such as controlled release and targeted delivery.\n<\/p>\n\n\n\n
\"\"<\/a><\/td>\n\n

Figure 5<\/strong> (A<\/strong>) Application of BA-loaded nanoscale delivery systems across various tumor types. (B<\/strong>) Annual publication trends of BA-loaded nanoformulations.<\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

This review focuses on strategies to improve the anti-tumor effect of BA through various nanoformulations. Firstly, by conjugating targeting ligands such as FA and HA onto nanocarriers, tumor cells can be specifically identified, enabling precise treatment and reducing damage to normal cells. Secondly, leveraging the unique properties of the TME, such as its acidic pH and high concentration of GSH, allows for the design of stimuli-responsive nanoformulations. These include pH-responsive and redox-responsive systems, enabling tumor site-specific drug release. In addition, the co-delivery of BA with other anti-tumor drugs, combined with different anti-cancer mechanisms, can synergistically enhance anti-tumor effects while mitigating or preventing serious adverse reactions associated with chemotherapy. In recent years, PTT and PDT have emerged as effective anti-tumor modalities, and researchers have developed BA-loaded nanopreparations capable of combining PTT and PDT, resulting in significantly enhanced anti-tumor effects.<\/p>\n

Despite significant progress has been made in these studies, the translation of BA-loaded nanopreparations from laboratory to clinical applications still faces numerous challenges. Firstly, ensuring the safety of nanocarriers remains a critical issue that needs to be addressed during clinical translation. Comprehensive safety and toxicological studies of BA-loaded nanoformulations are crucial, especially research on long-term toxicity, biodistribution, metabolism, and excretion. Furthermore, some studies have focused on in vitro and cell models, lacking sufficient trial data to verify the efficacy and safety of these nanoformulations. Therefore, future investigations should pay more attention to in vivo experimental design, such as monitoring the behavior of nanocarriers using advanced imaging techniques. Moreover, a deeper understanding of the anti-tumor mechanisms of BA and its nanoformulations is needed, encompassing elucidating molecular pathways, therapeutic targets, and interactions with the TME. Such insights can facilitate the development of more precise treatment strategies. Finally, the transition from laboratory to industrial-scale production poses a significant challenge. Addressing the stability of formulations during technology transfer and scale-up production is essential for ensuring consistency and efficacy in large-scale production processes.<\/p>\n

Future directions also entail the exploration of innovative nanocarrier designs and the development of novel targeting molecules to enhance the efficiency and safety of anti-tumor therapies. Interdisciplinary collaboration, combined with the latest advancements in medicinal chemistry, nanotechnology, and molecular biology, will provide a strong impetus to overcome existing challenges. For instance, medicinal chemistry can contribute to designing more effective targeting ligands and prodrugs, nanotechnology can improve drug loading and release profiles, and molecular biology can help identify precise molecular targets, allowing for highly specific tumor targeting. Additionally, artificial intelligence holds significant potential in advancing nanomedicine, especially in the design and optimization of nanodrugs for tumor therapy. Through predictive modeling, artificial intelligence can rapidly estimate tumor cell uptake and drug release efficiency based on the physicochemical properties of nanomedicines, perform high-speed analysis on complex biological datasets, and generate optimized design schemes, thereby accelerating the research process. Collectively, these interdisciplinary approaches can optimize the design of nano-delivery systems and accelerate their clinical applications.<\/p>\n

Since studies on BA-loaded NDDSs are still in their early stages, much of the reported data primarily come from in vitro and animal models, with a lack of clinical research data. Therefore, this review is based mainly on existing preclinical research findings, and the clinical translational applicability of these systems needs to be further verified. While this review covers various types of NDDSs, the differing designs, synthesis methods, and efficacy evaluation criteria of these systems make it challenging to directly compare their effects, which may result in the advantages and disadvantages of different systems not yet fully revealed.<\/p>\n

In summary, BA-loaded nano-delivery systems demonstrate broad prospects in the field of anti-tumor research owing to their unique therapeutic advantages. Through continuous technological innovation and in-depth research, it is expected that these nano-delivery strategies will be successfully translated into practical clinical applications in the near future, offering more effective and safer therapeutic options for tumor patients.<\/p>\n<\/div>\n

\n

Data Sharing Statement<\/h2>\n

Data will be made available on request.<\/p>\n

Funding<\/h2>\n

This work was supported by the Luzhou Municipal People\u2019s Government-Southwest Medical University Science and Technology Strategic Cooperation Project [grant number 2023LZXNYDJ004] and the National Natural Science Foundation of China [grant number 82104083].<\/p>\n

Disclosure<\/h2>\n

The authors declare no conflicts of interest in this work.<\/p>\n

References<\/h2>\n

1.<\/a> Banerjee S, Banerjee S, Bishayee A, et al. Cellular and molecular mechanisms underlying the potential of betulinic acid in cancer prevention and treatment. Phytomedicine<\/em>. 2024;132:155858. doi:10.1016\/j.phymed.2024.155858<\/p>\n

2.<\/a> Lou H, Li H, Zhang S, Lu H, Chen Q. A review on preparation of betulinic acid and its biological activities. Molecules<\/em>. 2021;26(18):5583. doi:10.3390\/molecules26185583<\/p>\n

3.<\/a> Jiang W, Li X, Dong S, Zhou W. Betulinic acid in the treatment of tumour diseases: application and research progress. Biomed Pharmacother<\/em>. 2021;142:111990. doi:10.1016\/j.biopha.2021.111990<\/p>\n

4.<\/a> Jin C, Zhang J, Song H, Cao Y. Boosting the biosynthesis of betulinic acid and related triterpenoids in Yarrowia lipolytica via multimodular metabolic engineering. Microb Cell Fact<\/em>. 2019;18(1):77. doi:10.1186\/s12934-019-1127-8<\/p>\n

5.<\/a> Srivari Y, Chatterjee P. Factors influencing the fabrication of albumin-bound drug nanoparticles (ABDns): part I. albumin-bound betulinic acid nanoparticles (ABBns). J Microencapsul<\/em>. 2016;33(8):689\u2013701. doi:10.1080\/02652048.2016.1222005<\/p>\n

6.<\/a> Sosa-Gutierrez DS, Toro-Vazquez JF, Cano-Sarmiento C, et al. Betulinic acid nanogels: rheological, microstructural characterization and evaluation of their anti-inflammatory activity. Curr Drug Deliv<\/em>. 2021;18(2):212\u2013223. doi:10.2174\/1567201817999200817154003<\/p>\n

7.<\/a> Wang C, Chen H, Wu Z, Jhan Y, Shyu C, Chou C. Antibacterial and synergistic activity of pentacyclic triterpenoids isolated from alstonia scholaris. Molecules<\/em>. 2016;21(2):139. doi:10.3390\/molecules21020139<\/p>\n

8.<\/a> Zhang J, Almoallim HS, Alharbi SA, Yang B. Anti-atherosclerotic activity of betulinic acid loaded polyvinyl alcohol\/methylacrylate grafted lignin polymer in high fat diet induced atherosclerosis model rats. Arab J Chem<\/em>. 2021;14(2):102934. doi:10.1016\/j.arabjc.2020.102934<\/p>\n

9.<\/a> Sardar A, Gautam S, Sinha S, et al. Nanoparticles of naturally occurring PPAR-\u03b3 inhibitor betulinic acid ameliorates bone marrow adiposity and pathological bone loss in ovariectomized rats via Wnt\/\u03b2-catenin pathway. Life Sci<\/em>. 2022;309:121020. doi:10.1016\/j.lfs.2022.121020<\/p>\n

10.<\/a> Trumbull ER, Bianchi E, Eckert DJ, Wiedhopf RM, Cole JR. Tumor inhibitory agents from Vauquelinia corymbosa(Rosaceae). J Pharm Sci<\/em>. 1976;65(9):1407\u20131408. doi:10.1002\/jps.2600650938<\/p>\n

11.<\/a> Jin X, Yang Q, Cai N, Zhang Z. A cocktail of betulinic acid, parthenolide, honokiol and ginsenoside Rh2 in liposome systems for lung cancer treatment. Nanomedicine<\/em>. 2020;15(1):41\u201354. doi:10.2217\/nnm-2018-0479<\/p>\n

12.<\/a> Urandur S, Banala VT, Shukla RP, et al. Theranostic lyotropic liquid crystalline nanostructures for selective breast cancer imaging and therapy. Acta Biomater<\/em>. 2020;113:522\u2013540. doi:10.1016\/j.actbio.2020.06.023<\/p>\n

13.<\/a> Kumar P, Gautam AK, Kumar U, et al. Mechanistic exploration of the activities of poly(lactic-co-glycolic acid)-loaded nanoparticles of betulinic acid against hepatocellular carcinoma at cellular and molecular levels. Arch Physiol Biochem<\/em>. 2022;128(3):836\u2013848. doi:10.1080\/13813455.2020.1733024<\/p>\n

14.<\/a> Ali\u2010Seyed M, Jantan I, Vijayaraghavan K, Bukhari SNA. Betulinic acid: recent advances in chemical modifications, effective delivery, and molecular mechanisms of a promising anticancer therapy. Chem Biol Drug Des<\/em>. 2016;87(4):517\u2013536. doi:10.1111\/cbdd.12682<\/p>\n

15.<\/a> Ganguly A, Das B, Roy A, et al. Betulinic acid, a catalytic inhibitor of topoisomerase I, inhibits reactive oxygen species-mediated apoptotic topoisomerase I-DNA cleavable complex formation in prostate cancer cells but does not affect the process of cell death. Cancer Res<\/em>. 2007;67(24):11848\u201311858. doi:10.1158\/0008-5472.CAN-07-1615<\/p>\n

16.<\/a> Sun Y, Song C, Viernstein H, Unger F, Liang Z. Apoptosis of human breast cancer cells induced by microencapsulated betulinic acid from sour jujube fruits through the mitochondria transduction pathway. Food Chem<\/em>. 2013;138(2\u20133):1998\u20132007. doi:10.1016\/j.foodchem.2012.10.079<\/p>\n

17.<\/a> Xu Y, Li J, Li Q, Feng Y, Pan F. Betulinic acid promotes TRAIL function on liver cancer progression inhibition through p53\/caspase-3 signaling activation. Biomed Pharmacother<\/em>. 2017;88:349\u2013358. doi:10.1016\/j.biopha.2017.01.034<\/p>\n

18.<\/a> Chen X, Yuan X, Zhang Z, et al. Betulinic acid inhibits cell proliferation and migration in gastric cancer by targeting the NF-\u03baB\/VASP pathway. Eur J Pharmacol<\/em>. 2020;889:173493. doi:10.1016\/j.ejphar.2020.173493<\/p>\n

19.<\/a> Xiu Z, Zhu Y, Li S, et al. Betulinic acid inhibits growth of hepatoma cells through activating the NCOA4-mediated ferritinophagy pathway. J Funct Foods<\/em>. 2023;102:105441. doi:10.1016\/j.jff.2023.105441<\/p>\n

20.<\/a> Dai L, Li D, Cheng J, et al. Water soluble multiarm-polyethylene glycol-betulinic acid prodrugs: design, synthesis, and in vivo effectiveness. Polym Chem<\/em>. 2014;5(19):5775\u20135783. doi:10.1039\/c4py00648h<\/p>\n

21.<\/a> Yin W, Li Y, Gu Y, Luo M. Nanoengineered targeting strategy for cancer immunotherapy. Acta Pharmacol Sin<\/em>. 2020;41(7):902\u2013910. doi:10.1038\/s41401-020-0417-3<\/p>\n

22.<\/a> Li J, Qiang H, Yang W, et al. Oral insulin delivery by epithelium microenvironment-adaptive nanoparticles. J Control Release<\/em>. 2022;341:31\u201343. doi:10.1016\/j.jconrel.2021.11.020<\/p>\n

23.<\/a> Zhang Z, Liang X, Yang X, Liu Y, Zhou X, Li C. Advances in nanodelivery systems based on metabolism reprogramming strategies for enhanced tumor therapy. ACS Appl Mater Interfaces<\/em>. 2024;16(6):6689\u20136708. doi:10.1021\/acsami.3c15686<\/p>\n

24.<\/a> Saneja A, Kumar R, Singh A, et al. Development and evaluation of long-circulating nanoparticles loaded with betulinic acid for improved anti-tumor efficacy. Int J Pharm<\/em>. 2017;531(1):153\u2013166. doi:10.1016\/j.ijpharm.2017.08.076<\/p>\n

25.<\/a> Yang J, Zhang R, Wang F, et al. Red blood cell membrane-camouflaged prednisolone acetate-loaded PLGA nanoparticles for kidney-targeted drug delivery. J Drug Deliv Sci Technol<\/em>. 2023;86:104693. doi:10.1016\/j.jddst.2023.104693<\/p>\n

26.<\/a> Liu Y, Zhang X, Luo L, et al. Gold-nanobranched-shell based drug vehicles with ultrahigh photothermal efficiency for chemo-photothermal therapy. Nanomedicine<\/em>. 2019;18:303\u2013314. doi:10.1016\/j.nano.2018.09.015<\/p>\n

27.<\/a> Li Y, Wang Y, Gao L, et al. Betulinic acid self-assembled nanoparticles for effective treatment of glioblastoma. J Nanobiotechnology<\/em>. 2022;20(1):39. doi:10.1186\/s12951-022-01238-7<\/p>\n

28.<\/a> Halder A, Jethwa M, Mukherjee P, et al. Lactoferrin-tethered betulinic acid nanoparticles promote rapid delivery and cell death in triple negative breast and laryngeal cancer cells. Artif Cells Nanomed Biotechnol<\/em>. 2020;48(1):1362\u20131371. doi:10.1080\/21691401.2020.1850465<\/p>\n

29.<\/a> Peng F, Jin Y, Wang K, Wang X, Xiao Y, Xu H. Glycosylated zein composite nanoparticles for efficient delivery of betulinic acid: fabrication, characterization, and in vitro release properties. Foods<\/em>. 2022;11(17):2589. doi:10.3390\/foods11172589<\/p>\n

30.<\/a> Dai L, Li C, Liu K, et al. Self-assembled serum albumin-poly(L-lactic acid) nanoparticles: a novel nanoparticle platform for drug delivery in cancer. RSC Adv<\/em>. 2015;5(20):15612\u201315620. doi:10.1039\/c4ra16346j<\/p>\n

31.<\/a> Hussein-Al-Ali SH, Arulselvan P, Fakurazi S, Hussein MZ. The in vitro therapeutic activity of betulinic acid nanocomposite on breast cancer cells (MCF-7) and normal fibroblast cell (3T3). J Mater Sci<\/em>. 2014;49(23):8171\u20138182. doi:10.1007\/s10853-014-8526-3<\/p>\n

32.<\/a> Ghiulai R, Mioc A, Racoviceanu R, et al. The anti-melanoma effect of betulinic acid functionalized gold nanoparticles: a mechanistic in vitro approach. Pharmaceuticals<\/em>. 2022;15(11):1362. doi:10.3390\/ph15111362<\/p>\n

33.<\/a> Oladimeji O, Akinyelu J, Daniels A, Singh M. Modified gold nanoparticles for efficient delivery of betulinic acid to cancer cell mitochondria. Int J Mol Sci<\/em>. 2021;22(10):5072. doi:10.3390\/ijms22105072<\/p>\n

34.<\/a> Tan E, Dan\u0131\u015fman\u2011Kal\u0131ndemirta\u015f F, Karaku\u015f S. Effective drug combinations of betulinic acid and ceranib-2 loaded Zn:MnO2<\/sub> doped-polymeric nanocarriers against PC-3 prostate cancer cells. Colloids Surf B<\/em>. 2023;225:113278. doi:10.1016\/j.colsurfb.2023.113278<\/p>\n

35.<\/a> Tao R, Wang C, Lu Y, et al. Characterization and cytotoxicity of polyprenol lipid and vitamin E-TPGS hybrid nanoparticles for betulinic acid and low-substituted hydroxyl fullerenol in MHCC97H and L02 Cells. Int J Nanomed<\/em>. 2020;15:2733\u20132749. doi:10.2147\/IJN.S249773<\/p>\n

36.<\/a> Dai L, Yang T, He J, et al. Cellulose-graft-poly(L<\/sub>-lactic acid) nanoparticles for efficient delivery of anti-cancer drugs. J Mater Chem B<\/em>. 2014;2(39):6749\u20136757. doi:10.1039\/c4tb00956h<\/p>\n

37.<\/a> Kumar P, Singh AK, Raj V, et al. Poly(lactic-co-glycolic acid)-loaded nanoparticles of betulinic acid for improved treatment of hepatic cancer: characterization, in vitro and in vivo evaluations. Int J Nanomed<\/em>. 2018;13:975\u2013990. doi:10.2147\/IJN.S157391<\/p>\n

38.<\/a> Zhang H, Zhou T, Yu Q, et al. pH-Sensitive betulinic acid polymer prodrug nanoparticles for efficient and targeted cancer cells treatment. Int J Polym Mater<\/em>. 2020;69(10):659\u2013668. doi:10.1080\/00914037.2019.1596916<\/p>\n

39.<\/a> Zhu P, Luo W, Qian J, et al. GSH\/ROS dual-responsive supramolecular nanoparticles based on pillar[6]arene and betulinic acid prodrug for chemo-chemodynamic combination therapy. Molecules<\/em>. 2021;26(19):5900. doi:10.3390\/molecules26195900<\/p>\n

40.<\/a> Saneja A, Kumar R, Mintoo MJ, et al. Gemcitabine and betulinic acid co-encapsulated PLGA-PEG polymer nanoparticles for improved efficacy of cancer chemotherapy. Mater Sci Eng C-Mater<\/em>. 2019;98:764\u2013771. doi:10.1016\/j.msec.2019.01.026<\/p>\n

41.<\/a> Dai L, Cao X, Liu K, et al. Self-assembled targeted folate-conjugated eight-arm-polyethylene glycol-betulinic acid nanoparticles for co-delivery of anticancer drugs. J Mater Chem B<\/em>. 2015;3(18):3754\u20133766. doi:10.1039\/c5tb00042d<\/p>\n

42.<\/a> Lu S, Fan X, Wang H, et al. Synthesis of gelatin-based dual-targeted nanoparticles of betulinic acid for antitumor therapy. ACS Appl Bio Mater<\/em>. 2020;3(6):3518\u20133525. doi:10.1021\/acsabm.9b01204<\/p>\n

43.<\/a> Dai L, Si C. Cellulose-graft-poly(methyl methacrylate) nanoparticles with high biocompatibility for hydrophobic anti-cancer drug delivery. Mater Lett<\/em>. 2017;207:213\u2013216. doi:10.1016\/j.matlet.2017.07.090<\/p>\n

44.<\/a> Dai L, Liu K, Si C, et al. Ginsenoside nanoparticle: a new green drug delivery system. J Mater Chem B<\/em>. 2016;4(3):529\u2013538. doi:10.1039\/c5tb02305j<\/p>\n

45.<\/a> Dai L, Liu K, Si C, He J, Lei J, Guo L. A novel self-assembled targeted nanoparticle platform based on carboxymethylcellulose co-delivery of anticancer drugs. J Mater Chem B<\/em>. 2015;3(32):6605\u20136617. doi:10.1039\/c5tb00900f<\/p>\n

46.<\/a> Fu S, Wang M, Li B, et al. Bionic natural small molecule co-assemblies towards targeted and synergistic Chemo\/PDT\/CDT. Biomater Res<\/em>. 2023;27(1):43. doi:10.1186\/s40824-023-00380-z<\/p>\n

47.<\/a> Cheng J, Zhao H, Li B, et al. Photosensitive pro-drug nanoassemblies harboring a chemotherapeutic dormancy function potentiates cancer immunotherapy. Acta Pharm Sin B<\/em>. 2023;13(2):879\u2013896. doi:10.1016\/j.apsb.2022.06.008<\/p>\n

48.<\/a> \u00d6zdemir Z, Yang M, Kim G, et al. Redox-responsive nanoparticles self-assembled from porphyrin-betulinic acid conjugates for chemo- and photodynamic therapy. Dyes Pigm<\/em>. 2021;190:109307. doi:10.1016\/j.dyepig.2021.109307<\/p>\n

49.<\/a> Chang Y, Jiao Y, Li D, Liu X, Han H. Glycosylated zein as a novel nanodelivery vehicle for lutein. Food Chem<\/em>. 2021;376:131927. doi:10.1016\/j.foodchem.2021.131927<\/p>\n

50.<\/a> Elzoghby AO, Samy WM, Elgindy NA. Albumin-based nanoparticles as potential controlled release drug delivery systems. J Control Release<\/em>. 2012;157(2):168\u2013182. doi:10.1016\/j.jconrel.2011.07.031<\/p>\n

51.<\/a> Zheng B, Chen Y, Niu L, et al. Modulating the tumoral SPARC content to enhance albumin-based drug delivery for cancer therapy. J Control Release<\/em>. 2024;366:596\u2013610. doi:10.1016\/j.jconrel.2023.12.057<\/p>\n

52.<\/a> Gupta R, Paul K. Investigating the serum albumin binding behavior of naphthalimide based fluorophore conjugates: spectroscopic and molecular docking approach. ChemMedChem<\/em>. 2024;19(15):e202400114. doi:10.1002\/cmdc.202400114<\/p>\n

53.<\/a> Tan T, Yang Q, Chen D, et al. Chondroitin sulfate-mediated albumin Corona nanoparticles for the treatment of breast cancer. Asian J Pharm Sci<\/em>. 2021;16(4):508\u2013518. doi:10.1016\/j.ajps.2021.03.004<\/p>\n

54.<\/a> Adhikari C. Polymer nanoparticles-preparations, applications and future insights: a concise review. Polym-Plast Technol<\/em>. 2021;60(18):1996\u20132024. doi:10.1080\/25740881.2021.1939715<\/p>\n

55.<\/a> Cheng J, Zhao H, Wang J, Han Y, Yang X. Bioactive natural small molecule-tuned coassembly of photosensitive drugs for highly efficient synergistic and enhanced type I photochemotherapy. ACS Appl Mater Inter<\/em>. 2020;12(39):43488\u201343500. doi:10.1021\/acsami.0c13164<\/p>\n

56.<\/a> Liu Y, Gao D, Zhang X, et al. Antitumor drug effect of betulinic acid mediated by polyethylene glycol modified liposomes. Mater Sci Eng C-Mater<\/em>. 2016;64:124\u2013132. doi:10.1016\/j.msec.2016.03.080<\/p>\n

57.<\/a> Wang G, Yu Y, Wang Y, Zhu Z, Yin P, Xu K. Effects and mechanisms of fatty acid metabolism\u2011mediated glycolysis regulated by betulinic acid\u2011loaded nanoliposomes in colorectal cancer. Oncol Rep<\/em>. 2020;44(6):2595\u20132609. doi:10.3892\/or.2020.7787<\/p>\n

58.<\/a> Farcas CG, Dehelean C, Pinzaru IA, et al. Thermosensitive betulinic acid-loaded magnetoliposomes: a promising antitumor potential for highly aggressive human breast adenocarcinoma cells under hyperthermic conditions. Int J Nanomed<\/em>. 2020;15:8175\u20138200. doi:10.2147\/IJN.S269630<\/p>\n

59.<\/a> Liu Y, Zhang X, Liu Z, et al. Gold nanoshell-based betulinic acid liposomes for synergistic chemo-photothermal therapy. Nanomedicine<\/em>. 2017;13(6):1891\u20131900. doi:10.1016\/j.nano.2017.03.012<\/p>\n

60.<\/a> Liu Y, Zhang X, Luo L, et al. Self-assembly of stimuli-responsive Au\u2013Pd bimetallic nanoflowers based on betulinic acid liposomes for synergistic chemo-photothermal cancer therapy. ACS Biomater Sci Eng<\/em>. 2018;4(8):2911\u20132921. doi:10.1021\/acsbiomaterials.8b00766<\/p>\n

61.<\/a> Wu X, Wei Z, Feng H, et al. Targeting effect of betulinic acid liposome modified by hyaluronic acid on hepatoma cells in vitro. J Pharm Sci<\/em>. 2022;111(11):3047\u20133053. doi:10.1016\/j.xphs.2022.06.015<\/p>\n

62.<\/a> Guo B, Xu D, Liu X, Yi J. Enzymatic synthesis and in vitro evaluation of folate-functionalized liposomes. Drug Des Devel Ther<\/em>. 2017;11:1839\u20131847. doi:10.2147\/DDDT.S132841<\/p>\n

63.<\/a> Li C, Wang Z, Zhang Y, et al. Efficient sequential co-delivery nanosystem for inhibition of tumor and tumor-associated fibroblast-induced resistance and metastasis. Int J Nanomed<\/em>. 2024;19:1749\u20131766. doi:10.2147\/IJN.S427783<\/p>\n

64.<\/a> Chen X, Lu S, Gong F, Sui X, Liu T, Wang T. Research on the synthesis of nanoparticles of betulinic acid and their targeting antitumor activity. J Biomed Mater Res B<\/em>. 2022;110(8):1789\u20131795. doi:10.1002\/jbm.b.35036<\/p>\n

65.<\/a> Wang G, Yang Y, Yi D, et al. Eudragit S100 prepared pH-responsive liposomes-loaded betulinic acid against colorectal cancer in vitro and in vivo. J Liposome Res<\/em>. 2022;32(3):250\u2013264. doi:10.1080\/08982104.2021.1999974<\/p>\n

66.<\/a> Shu Q, Wu J, Chen Q. Synthesis, characterization of liposomes modified with biosurfactant MEL-A loading betulinic acid and its anticancer effect in HepG2 cell. Molecules<\/em>. 2019;24(21):3939. doi:10.3390\/molecules24213939<\/p>\n

67.<\/a> Rodr\u00edguez-Luccioni HL, Latorre-Esteves M, M\u00e9ndez-Vega J, et al. Enhanced reduction in cell viability by hyperthermia induced by magnetic nanoparticles. Int J Nanomed<\/em>. 2011;6:373\u2013380. doi:10.2147\/IJN.S14613<\/p>\n

68.<\/a> Farzin A, Etesami SA, Quint J, Memic A, Tamayol A. Magnetic nanoparticles in cancer therapy and diagnosis. Adv Healthc Mater<\/em>. 2020;9(9):e1901058. doi:10.1002\/adhm.201901058<\/p>\n

69.<\/a> Li J, Zhang W, Ji W, et al. Near infrared photothermal conversion materials: mechanism, preparation, and photothermal cancer therapy applications. J Mater Chem B<\/em>. 2021;9(38):7909\u20137926. doi:10.1039\/d1tb01310f<\/p>\n

70.<\/a> Zhang W, Huang X. Stem cell membrane-camouflaged targeted delivery system in tumor. Mater Today Bio<\/em>. 2022;16:100377. doi:10.1016\/j.mtbio.2022.100377<\/p>\n

71.<\/a> Lin M, Dai Y, Xia F, Zhang X. Advances in non-covalent crosslinked polymer micelles for biomedical applications. Mater Sci Eng C-Mater<\/em>. 2021;119:111626. doi:10.1016\/j.msec.2020.111626<\/p>\n

72.<\/a> Biswas S, Kumari P, Lakhani PM, Ghosh B. Recent advances in polymeric micelles for anti-cancer drug delivery. Eur J Pharm Sci<\/em>. 2016;83:184\u2013202. doi:10.1016\/j.ejps.2015.12.031<\/p>\n

73.<\/a> Jin X, Zhou J, Zhang Z, Lv H. Doxorubicin combined with betulinic acid or lonidamine in RGD ligand-targeted pH-sensitive micellar system for ovarian cancer treatment. Int J Pharm<\/em>. 2019;571:118751. doi:10.1016\/j.ijpharm.2019.118751<\/p>\n

74.<\/a> Hou J, Sun E, Sun C, et al. Improved oral bioavailability and anticancer efficacy on breast cancer of paclitaxel via Novel Soluplus\u00ae<\/sup>\u2014Solutol\u00ae<\/sup> HS15 binary mixed micelles system. Int J Pharm<\/em>. 2016;512(1):186\u2013193. doi:10.1016\/j.ijpharm.2016.08.045<\/p>\n

75.<\/a> Qi X, Gao C, Yin C, Fan J, Wu X, Guo C. Improved anticancer activity of betulinic acid on breast cancer through a grafted copolymer-based micelles system. Drug Deliv<\/em>. 2021;28(1):1962\u20131971. doi:10.1080\/10717544.2021.1979125<\/p>\n

76.<\/a> Zhang Y, Zhou H, Zhang Z, et al. Redox\/NIR dual-responsive PEG-betulinic acid\/pluronic-cypate prodrug micelles for chemophotothermal therapy. Colloids Surf A<\/em>. 2021;609:125662. doi:10.1016\/j.colsurfa.2020.125662<\/p>\n

77.<\/a> Qu H, Yang J, Li S, et al. Programmed-response cross-linked nanocarrier for multidrug-resistant ovarian cancer treatment. J Control Release<\/em>. 2023;357:274\u2013286. doi:10.1016\/j.jconrel.2023.03.031<\/p>\n

78.<\/a> Gautam S, Marwaha D, Singh N, et al. Self-assembled redox-sensitive polymeric nanostructures facilitate the intracellular delivery of paclitaxel for improved breast cancer therapy. Mol Pharm<\/em>. 2023;20(4):1914\u20131932. doi:10.1021\/acs.molpharmaceut.2c00673<\/p>\n

79.<\/a> Lomkova EA, Chytil P, Janou\u0161kov\u00e1 O, et al. Biodegradable micellar HPMA-based polymer-drug conjugates with betulinic acid for passive tumor targeting. Biomacromolecules<\/em>. 2016;17(11):3493\u20133507. doi:10.1021\/acs.biomac.6b00947<\/p>\n

80.<\/a> Lei W, Sun C, Jiang T, et al. Polydopamine-coated mesoporous silica nanoparticles for multi-responsive drug delivery and combined chemo-photothermal therapy. Mater Sci Eng C-Mater<\/em>. 2019;105:110103. doi:10.1016\/j.msec.2019.110103<\/p>\n

81.<\/a> Tan JM, Karthivashan G, Arulselvan P, Fakurazi S, Hussein MZ. Characterization and in vitro studies of the anticancer effect of oxidized carbon nanotubes functionalized with betulinic acid. Drug Des Devel Ther<\/em>. 2014;8:2333\u20132343. doi:10.2147\/DDDT.S70650<\/p>\n

82.<\/a> Dai L, Liu R, Hu L, Wang J, Si C. Self-assembled PEG-carboxymethylcellulose nanoparticles\/\u03b1-cyclodextrin hydrogels for injectable and thermosensitive drug delivery. RSC Adv<\/em>. 2017;7(5):2905\u20132912. doi:10.1039\/c6ra25793c<\/p>\n

83.<\/a> Dai L, Liu K, Wang L, et al. Injectable and thermosensitive supramolecular hydrogels by inclusion complexation between binary-drug loaded micelles and \u03b1-cyclodextrin. Mater Sci Eng C-Mater<\/em>. 2017;76:966\u2013974. doi:10.1016\/j.msec.2017.03.151<\/p>\n

84.<\/a> Dash SK, Dash SS, Chattopadhyay S, et al. Folate decorated delivery of self assembled betulinic acid nano fibers: a biocompatible anti-leukemic therapy. RSC Adv<\/em>. 2015;5(31):24144\u201324157. doi:10.1039\/C5RA01076D<\/p>\n

85.<\/a> Dash SK, Chattopadhyay S, Tripathy S, et al. Self-assembled betulinic acid augments immunomodulatory activity associates with IgG response. Biomed Pharmacother<\/em>. 2015;75:205\u2013217. doi:10.1016\/j.biopha.2015.07.033<\/p>\n

86.<\/a> Rebou\u00e7as LM, Sousa ACC, Sampaio CG, et al. Microcapsules based on alginate and guar gum for co-delivery of hydrophobic antitumor bioactives. Carbohydr Polym<\/em>. 2023;301(Pt A):120310. doi:10.1016\/j.carbpol.2022.120310<\/p>\n

87.<\/a> Pinzaru I, Sarau C, Coricovac D, et al. Silver nanocolloids loaded with betulinic acid with enhanced antitumor potential: physicochemical characterization and in vitro evaluation. Nanomaterials<\/em>. 2021;11(1):152. doi:10.3390\/nano11010152<\/p>\n

88.<\/a> Li S, Zhang J, Fang Y, et al. Enhancing betulinic acid dissolution rate and improving antitumor activity via nanosuspension constructed by anti-solvent technique. Drug Des Devel Ther<\/em>. 2020;14:243\u2013256. doi:10.2147\/DDDT.S233851<\/p>\n

89.<\/a> Wang R, Yang M, Li G, et al. Paclitaxel-betulinic acid hybrid nanosuspensions for enhanced anti-breast cancer activity. Colloids Surf B<\/em>. 2019;174:270\u2013279. doi:10.1016\/j.colsurfb.2018.11.029<\/p>\n

90.<\/a> Wang R, Wang X, Jia X, Wang H, Li W, Li J. Impacts of particle size on the cytotoxicity, cellular internalization, pharmacokinetics and biodistribution of betulinic acid nanosuspensions in combined chemotherapy. Int J Pharm<\/em>. 2020;588:119799. doi:10.1016\/j.ijpharm.2020.119799<\/p>\n

91.<\/a> Mehra NK, Jain NK. Multifunctional hybrid-carbon nanotubes: new horizon in drug delivery and targeting. J Drug Target<\/em>. 2016;24(4):294\u2013308. doi:10.3109\/1061186X.2015.1055571<\/p>\n

92.<\/a> Tan JM, Karthivashan G, Abd Gani S, Fakurazi S, Hussein MZ. Biocompatible polymers coated on carboxylated nanotubes functionalized with betulinic acid for effective drug delivery. J Mater Sci<\/em>. 2016;27(2):26. doi:10.1007\/s10856-015-5635-8<\/p>\n

93.<\/a> Merino S, Mart\u00edn C, Kostarelos K, Prato M, V\u00e1zquez E. Nanocomposite hydrogels: 3D polymer\u2013nanoparticle synergies for on-demand drug delivery. ACS Nano<\/em>. 2015;9(5):4686\u20134697. doi:10.1021\/acsnano.5b01433<\/p>\n

94.<\/a> Ahmed A, Sarwar S, Hu Y, et al. Surface-modified polymeric nanoparticles for drug delivery to cancer cells. Expert Opin Drug Deliv<\/em>. 2021;18(1):1\u201324. doi:10.1080\/17425247.2020.1822321<\/p>\n

95.<\/a> Dash SK, Chattopadhyay S, Dash SS, et al. Self assembled nano fibers of betulinic acid: a selective inducer for ROS\/TNF-alpha pathway mediated leukemic cell death. Bioorg Chem<\/em>. 2015;63:85\u2013100. doi:10.1016\/j.bioorg.2015.09.006<\/p>\n

96.<\/a> Dash SK, Chattopadhyay S, Ghosh T, et al. Self-assembled betulinic acid protects doxorubicin induced apoptosis followed by reduction of ROS\u2013TNF-\u03b1\u2013caspase-3 activity. Biomed Pharmacother<\/em>. 2015;72:144\u2013157. doi:10.1016\/j.biopha.2015.04.017<\/p>\n

97.<\/a> Meng Q, Zhong S, Gao Y, Cui X. Advances in polysaccharide-based nano\/microcapsules for biomedical applications: a review. Int J Biol Macromol<\/em>. 2022;220:878\u2013891. doi:10.1016\/j.ijbiomac.2022.08.129<\/p>\n

98.<\/a> Ahmadian E, Dizaj SM, Rahimpour E, et al. Effect of silver nanoparticles in the induction of apoptosis on human hepatocellular carcinoma (HepG2) cell line. Mater Sci Eng C-Mater<\/em>. 2018;93:465\u2013471. doi:10.1016\/j.msec.2018.08.027<\/p>\n

99.<\/a> Ma Y, Cong Z, Gao P, Wang Y. Nanosuspensions technology as a master key for nature products drug delivery and In vivo fate. Eur J Pharm Sci<\/em>. 2023;185:106425. doi:10.1016\/j.ejps.2023.106425<\/p>\n<\/div><\/div>\n","protected":false},"excerpt":{"rendered":"

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