Photothermal Cancer Therapy Research Articles

Organic nanoparticles based on aza-boron dipyrromethene derivatives for combined photothermal and photodynamic cancer therapy

Cancer is one of the major diseases that threaten human being's health and life. Recently, phototherapy has gained great attention due to the advantages of high selectivity and low toxicity. Nonetheless, the development a single photosensitizer capable of simultaneously achieving photothermal and photodynamic effects remains a great challenge. Aza-boron-dipyrromethene (aza-BODIPY) dyes have been widely studied in biomedical area for their significant absorption in the near infrared region and high fluorescence quantum yield. In this contribution, three aza-BODIPY molecules (TAS-BP, TES-BP and TESO-BP) that conjugated with triphenylamine (TPA) or tetraphenylethylene (TPE) were designed and synthesized. The presence of donor-acceptor-donor pairs within compounds enables the intermolecular electron transfer, leading to the augmentation of near-infrared (NIR) absorbance and the generation of non-radiative heat. The nanoparticles were prepared via the assembly of the related organic compounds with amphiphilic polymer (DSPE-PEG2000), which were named as TAS-BP NPs, TES-BP NPs and TESO-BP NPs, respectively. Importantly, three nanoparticles can generate heat and reactive oxygen species (ROS) simultaneously induced by a single laser (808 nm). The photothermal conversion efficiency of TAS-BP NPs, TES-BP NPs and TESO-BP NPs were determined to be 64.5%, 65.7%, and 53.6%, respectively. Furthermore, the cellular experiments demonstrated the good biocompatibility and outstanding photocytotoxicity of three nanoparticles, and the TES-BP NPs exhibited the highest photodynamic/photothermal synergistic effect. Thus, the as-prepared organic nanomaterials were demonstrated as potential candidates for cancer treatment through phototherapy.

Abstract 4168: Pre-clinical demonstration of Raman spectroscopy-assisted photothermal therapy for prostate cancer

Abstract Prostate cancer (PCa) ranks among the most prevalent malignancies in men. The combination of ultrasound and fine-needle aspiration biopsy has greatly facilitated early diagnosis and expanded the range of treatment options. Traditional treatments primarily involve anti-androgens and androgen deprivation therapy; however, a recurrence occurs in approximately 30% of cases following these interventions. Our current focus is on the exploration of photothermal therapies using nanoparticles for precise tumor ablation. Among these nanoparticles, multiwalled carbon nanotubes (MWCNTs) exhibit unique structural, optical, and thermal properties that make them exceptionally appealing for biomedical applications, especially as a foundation for photothermal therapy. Our platform employs the copper (I)-catalyzed azide alkyne cycloaddition of prostate-specific membrane antigen (PSMA)-targeting peptidomimetic (Glu-urea-Lys) ligand to the MWCNTs. We used confocal microscopy to observe a significantly enhanced binding of the targeted Glu-urea-Lys-MWCNTs to the surfaces of PSMA-expressing LNCaP cells compared to IgG-MWCNTs and to PSMA-null PC3 cells. Raman microscopy further confirmed the increased presence of Glu-urea-Lys-MWCNTs on LNCaP spheroids compared to non-targeting MWCNTs. We also confirmed enhanced photothermal cell ablation in vitro using the targeted MWCNTs. Based on in vitro evidence, we established LNCaP and PC3 xenografts in nu/nu mice and evaluated the therapeutic efficacy. Using fluorescence-based imaging, we observed the enhanced localization of Glu-urea-Lys-MWCNTs within the tumors. Furthermore, we collected the tumors and conducted ex vivo analysis using Raman microscopy for a label-free detection of the targeted MWCNTs, which complemented the fluorescence imaging and laying the foundation for real-time Raman imaging in vivo. Subsequently, we applied photothermal ablation of the tumor xenografts based on a pre-optimized treatment protocol established from COMSOL simulations and prior experiments. This treatment led to complete tumor ablation with minimal recurrence and minimal non-specific damage. In conclusion, we have assessed the effectiveness of our targeted nano-photothermal platform in a pre-clinical model of PCa. Further studies will aid in the transition of photothermal therapy to clinical trials. Moreover, we aim to investigate the role of photothermal therapy in the PCa tumor microenvironment and whether such an approach can trigger post-therapeutic activation of immune responses against the tumor. Ultimately, we anticipate that our nanotherapeutic platform will contribute to a focused therapeutic approach where targeted MWCNT-laser treatment exploits overexpressed tumor markers in conjunction with various irradiation strategies to enhance ablation while minimizing damage to surrounding tissue. Citation Format: Seung Soo Lee, Gabriel Beaudoin, Jun Hui Yeoh, Frederic Leblond, Mark Trifiro, Miltiadis Paliouras. Pre-clinical demonstration of Raman spectroscopy-assisted photothermal therapy for prostate cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 4168.

A Golgi Apparatus-Targeted Photothermal Agent with Protein Anchoring for Enhanced Cancer Photothermal Therapy.

The Golgi apparatus (GA) is central in shuttling proteins from the endoplasmic reticulum to different cellular areas. Therefore, targeting the GA to precisely destroy its proteins through local heat could induce apoptosis, offering a potential avenue for effective cancer therapy. Herein, a GA-targeted photothermal agent based on protein anchoring is introduced for enhanced photothermal therapy of tumor through the modification of near-infrared molecular dye with maleimide derivative and benzene sulfonamide. The photothermal agent can actively target the GA and covalently anchor to its sulfhydryl proteins, thereby increasing its retention within the GA. Under laser irradiation, the heat generated by the photothermal agent efficiently disrupts sulfhydryl proteins in situ, leading to GA dysfunction and ultimately inducing cell apoptosis. In vivo experiments demonstrate that the photothermal agent can precisely treat tumors and significantly reduce side effects.

Controlled Phase Transition of the Onion-like Carbon Nanostructure for Photothermal Cancer Therapy

Controlled Phase Transition of the Onion-like Carbon Nanostructure for Photothermal Cancer Therapy

Multifunctional iron-apigenin nanocomplex conducting photothermal therapy and triggering augmented immune response for triple negative breast cancer

Triple negative breast cancer (TNBC) presents a formidable challenge due to its low sensitivity to many chemotherapeutic drugs and a relatively low overall survival rate in clinical practice. Photothermal therapy has recently garnered substantial interest in cancer treatment, owing to its swift therapeutic effectiveness and minimal impact on normal cells. Metal-polyphenol nanostructures have recently garnered significant attention as photothermal transduction agents due to their facile preparation and favorable photothermal properties. In this study, we employed a coordinated approach involving Fe3+ and apigenin, a polyphenol compound, to construct the nanostructure (nFeAPG), with the assistance of β-CD and DSPE-PEG facilitating the formation of the complex nanostructure. In vitro research demonstrated that the formed nFeAPG could induce cell death by elevating intracellular oxidative stress, inhibiting antioxidative system, and promoting apoptosis and ferroptosis, and near infrared spectrum irradiation further strengthen the therapeutic outcome. In 4T1 tumor bearing mice, nFeAPG could effectively accumulate into tumor site and exhibit commendable control over tumor growth. Futher analysis demonstrated that nFeAPG ameliorated the suppressed immune microenvironment by augmenting the response of DC cells and T cells. This study underscores that nFeAPG encompasses a multifaceted capacity to combat TNBC, holding promise as a compelling therapeutic strategy for TNBC treatment.

Red blood cell membrane-camouflaged gold-core silica shell nanorods for cancer drug delivery and photothermal therapy

Gold core mesoporous silica shell (AuMSS) nanorods are multifunctional nanomedicines that can act simultaneously as photothermal, drug delivery, and bioimaging agents. Nevertheless, it is reported that once administrated, nanoparticles can be coated with blood proteins, forming a protein corona, that directly impacts on nanomedicines’ circulation time, biodistribution, and therapeutic performance. Therefore, it become crucial to develop novel alternatives to improve nanoparticles’ half-life in the bloodstream. In this work, Polyethylenimine (PEI) and Red blood cells (RBC)-derived membranes were combined for the first time to functionalize AuMSS nanorods and simultaneously load acridine orange (AO). The obtained results revealed that the RBC-derived membranes promoted the neutralization of the AuMSS’ surface charge and consequently improved the colloidal stability and biocompatibility of the nanocarriers. Indeed, the in vitro data revealed that PEI/RBC-derived membranes’ functionalization also improved the nanoparticles’ cellular internalization and was capable of mitigating the hemolytic effects of AuMSS and AuMSS/PEI nanorods. In turn, the combinatorial chemo-photothermal therapy mediated by AuMSS/PEI/RBC_AO nanorods was able to completely eliminate HeLa cells, contrasting with the less efficient standalone therapies. Such data reinforce the potential of AuMSS nanomaterials to act simultaneously as photothermal and chemotherapeutic agents.

A Nanographene-Porphyrin Hybrid for Near-Infrared-Ii Phototheranostics.

Photoacoustic imaging (PAI)-guided photothermal therapy (PTT) in the second near-infrared (NIR-II, 1000-1700nm) window has been attracting attention as a promising cancer theranostic platform. Here, it is reported that the π-extended porphyrins fused with one or two nanographene units (NGP-1 and NGP-2) can serve as a new class of NIR-responsive organic agents, displaying absorption extending to ≈1000 and ≈1400nm in the NIR-I and NIR-II windows, respectively. NGP-1 and NGP-2 are dispersed in water through encapsulation into self-assembled nanoparticles (NPs), achieving high photothermal conversion efficiency of 60% and 69%, respectively, under 808 and 1064nm laser irradiation. Moreover, the NIR-II-active NGP-2-NPs demonstrated promising photoacoustic responses, along with high photostability and biocompatibility, enabling PAI and efficient NIR-II PTT of cancer in vivo.

Strength through unity: Alkaline phosphatase-responsive AIEgen nanoprobe for aggregation-enhanced multi-mode imaging and photothermal therapy of metastatic prostate cancer

Strength through unity: Alkaline phosphatase-responsive AIEgen nanoprobe for aggregation-enhanced multi-mode imaging and photothermal therapy of metastatic prostate cancer

Potential Exploration of Biocompatible Carbon-Coated MoSe2 Nanoparticles for Exploration of the Photothermal Potential in the Treatment of Human Choriocarcinoma.

Molybdenum diselenide (MoSe2), as a nano near-infrared absorber, has been widely studied in the field of photothermal therapy of cancer. However, there is little research on its application in the treatment of human choriocarcinoma. In this paper, a new type of carbon-coated MoSe2 (MEC) nanoparticles was prepared by a one-step hydrothermal method. The chemical characterization including SEM, TEM, EDS, XRD, FT-IR, TGA, Roman, and XPS showed that MEC was successfully synthesized. MEC exhibited a high photothermal conversion efficiency (50.97%) and extraordinary photothermal stability under laser irradiation. The cell experiment results showed that MEC had good biocompatibility on normal cells while significant photothermal effect on human choriocarcinoma (JEG-3) cells, achieving a good anticancer effect. The level of reactive oxygen species (ROS) in JEG-3 cells was significantly increased under the combination of MEC nanoparticles and near-infrared radiation. MEC nanoparticles could induce apoptosis of JEG-3 cells in combination with near-infrared radiation. Finally, transcriptomic analysis verified that MEC combined with laser radiation could inhibit DNA replication and induce apoptosis, thus improving its therapeutic effect on human choriocarcinoma. MEC nanoparticles exert an excellent photothermal effect and may become an important candidate drug for the treatment of human choriocarcinoma.

The Down-Shifting Luminescence of Rare-Earth Nanoparticles for Multimodal Imaging and Photothermal Therapy of Breast Cancer.

Nanotheranostic agents capable of simultaneously enabling real-time tracking and precise treatment at tumor sites play an increasingly pivotal role in the field of medicine. In this article, we report a novel near-infrared-II window (NIR-II) emitting downconversion rare-earth nanoparticles (RENPs) to improve image-guided therapy for breast cancer. The developed α-NaErF4@NaYF4 nanoparticles (α-Er NPs) have a diameter of approximately 24.1 nm and exhibit superior biocompatibility and negligible toxicity. RENPs exhibit superior imaging quality and photothermal conversion efficiency in the NIR-II range compared to clinically approved indocyanine green (ICG). Under 808 nm laser irradiation, the α-Er NPs achieve significant tumor imaging performance and photothermal effects in vivo in a mouse model of breast cancer. Simultaneously, it combines X-ray computed tomography (CT) and ultrasound (US) tri-modal imaging to guide therapy for cancer. The integration of NIR-II imaging technology and RENPs establishes a promising foundation for future medical applications.

Bioorthogonal "Click and Release" Reaction-Triggered Aggregation of Gold Nanoparticles Combined with Released Lonidamine for Enhanced Cancer Photothermal Therapy.

Cancer has been the most deadly disease, and 13 million cancer casualties are estimated to occur each year by 2030. Gold nanoparticles (AuNPs)-based photothermal therapy (PTT) has attracted great interest due to its high spatiotemporal controllability and noninvasiveness. Due to the trade-off between particle size and photothermal efficiency of AuNPs, rational design is needed to realize aggregation of AuNPs into larger particles with desirable NIR adsorption in tumor site. Exploiting the bioorthogonal "Click and Release" (BCR) reaction between iminosydnone and cycloalkyne, aggregation of AuNPs can be achieved and attractively accompanied by the release of chemotherapeutic drug purposed to photothermal synergizing. We synthesize iminosydnone-lonidamine (ImLND) as a prodrug and choose dibenzocyclooctyne (DBCO) as the trigger of BCR reaction. A PEGylated AuNPs-based two-component nanoplatform consisting of prodrug-loaded AuNPs-ImLND and tumor-targeting peptide RGD-conjugated AuNPs-DBCO-RGD is designed. In the therapeutic regimen, AuNPs-DBCO-RGD are intravenously injected first for tumor-specific enrichment and retention. Once the arrival of AuNPs-ImLND injected later at tumor site, highly photothermally active nanoaggregates of AuNPs are formed via the BCR reaction between ImLND and DBCO. The simultaneous release of lonidamine further enhanced the therapeutic performance by sensitizing cancer cells to PTT.

Bioorthogonal “Click and Release” Reaction‐Triggered Aggregation of Gold Nanoparticles Combined with Released Lonidamine for Enhanced Cancer Photothermal Therapy

AbstractCancer has been the most deadly disease, and 13 million cancer casualties are estimated to occur each year by 2030. Gold nanoparticles (AuNPs)‐based photothermal therapy (PTT) has attracted great interest due to its high spatiotemporal controllability and noninvasiveness. Due to the trade‐off between particle size and photothermal efficiency of AuNPs, rational design is needed to realize aggregation of AuNPs into larger particles with desirable NIR adsorption in tumor site. Exploiting the bioorthogonal “Click and Release” (BCR) reaction between iminosydnone and cycloalkyne, aggregation of AuNPs can be achieved and attractively accompanied by the release of chemotherapeutic drug purposed to photothermal synergizing. We synthesize iminosydnone‐lonidamine (ImLND) as a prodrug and choose dibenzocyclooctyne (DBCO) as the trigger of BCR reaction. A PEGylated AuNPs‐based two‐component nanoplatform consisting of prodrug‐loaded AuNPs‐ImLND and tumor‐targeting peptide RGD‐conjugated AuNPs‐DBCO‐RGD is designed. In the therapeutic regimen, AuNPs‐DBCO‐RGD are intravenously injected first for tumor‐specific enrichment and retention. Once the arrival of AuNPs‐ImLND injected later at tumor site, highly photothermally active nanoaggregates of AuNPs are formed via the BCR reaction between ImLND and DBCO. The simultaneous release of lonidamine further enhanced the therapeutic performance by sensitizing cancer cells to PTT.

Image-Guided Photothermal and Immune Therapy of Tumors via Melanin-Producing Genetically Engineered Bacteria.

Photothermal therapy (PTT) is a new treatment modality for tumors. However, the efficient delivery of photothermal agents into tumors remains difficult, especially in hypoxic tumor regions. In this study, an approach to deliver melanin, a natural photothermal agent, into tumors using genetically engineered bacteria for image-guided photothermal and immune therapy is developed. An Escherichia coli MG1655 is transformed with a recombinant plasmid harboring a tyrosinase gene to produce melanin nanoparticles. Melanin-producing genetically engineered bacteria (MG1655-M) are systemically administered to 4T1 tumor-bearing mice. The tumor-targeting properties of MG1655-M in the hypoxic environment integrate the properties of hypoxia targeting, photoacoustic imaging, and photothermal therapeutic agents in an "all-in-one" manner. This eliminates the need for post-modification to achieve image-guided hypoxia-targeted cancer photothermal therapy. Tumor growth is significantly suppressed by irradiating the tumor with an 808nm laser. Furthermore, strong antitumor immunity is triggered by PTT, thereby producing long-term immune memory effects that effectively inhibit tumor metastasis and recurrence. This work proposes a new photothermal and immune therapy guided by an "all-in-one" melanin-producing genetically engineered bacteria, which can offer broad potential applications in cancer treatment.

IR780-based diffuse fluorescence tomography for cancer detection.

IR780 iodide is a commercially available targeted near-infrared contrast agent for in vivo imaging and cancer photodynamic or photothermal therapy, whereas the accumulation, dynamics, and retention of IR780 in biological tissue, especially in tumor is still under-explored. Diffuse fluorescence tomography (DFT) can be used for localization and quantification of the three-dimensional distribution of NIR fluorophores. Herein, a homemade DFT imaging system combined with tumor-targeted IR780 was utilized for cancer imaging and pharmacokinetic evaluation. The aim of this study is to comprehensively assess the biochemical and pharmacokinetic characteristics of IR780 with the aid of DFT imaging. The optimal IR780 concentration (20 μg/mL) was achieved first. Subsequently, the good biocompatibility and cellar uptake of IR780 was demonstrated through the mouse acute toxic test and cell assay. In vivo, DFT imaging effectively identified various subcutaneous tumors and revealed the long-term retention of IR780 in tumors and rapid metabolism in the liver. Ex vivo imaging indicated IR780 was mainly concentrated in tumor and lung with significantly different from the distribution in other organs. DFT imaging allowed sensitive tumor detection and pharmacokinetic rates analysis. Simultaneously, the kinetics of IR780 in tumors and liver provided more valuable information for application and development of IR780.

Light Absorption Analysis and Optimization of Ag@TiO2 Core-Shell Nanospheroid and Nanorod.

For photothermal therapy of cancer, it is necessary to find Ag @TiO2 core-shell nanoparticles that can freely tune the resonance wavelength within the near-infrared biological window. In this paper, the finite element method and the size-dependent refractive index of metal nanoparticles were used to theoretically investigate the effects of the core material, core length, core aspect ratio, shell thickness, refractive index of the surrounding medium, and the particle orientation on the light absorption properties of Ag@TiO2 core-shell nanospheroid and nanorod. The calculations show that the position and intensity of the light absorption resonance peaks can be freely tuned within the first and second biological windows by changing the above-mentioned parameters. Two laser wavelengths commonly used in photothermal therapy, 808 nm (first biological window) and 1064 nm (second biological window), were selected to optimize the core length and aspect ratio of Ag@TiO2 core-shell nanospheroid and nanorod. It was found that the optimized Ag@TiO2 core-shell nanospheroid has a stronger light absorption capacity at the laser wavelengths of 808 nm and 1064 nm. The optimized Ag@TiO2 core-shell nanoparticles can be used as ideal therapeutic agents in photothermal therapy.

Facile Synthesis of Novel Ti2C Nano Bipyramids for Photothermal and Photodynamic Therapy of Breast Cancer.

Photo-responsive synergetic therapeutics achieved significant attraction in cancer theranostic due to the versatile characteristics of nanomaterials. There have been substantial efforts in developing the simplest nano-design with exceptional synergistic properties and multifunctionalities. In this work, biocompatible Ti2C MXene nano bipyramids (MNBPs) were synthesized by hydrothermal method with dual functionalities of photothermal and photodynamic therapies. The MNBPs shape was obtained from two-dimensional (2D) Ti2C nanosheets by controlling the temperature of the reaction mixture. The structure of these Ti2C MNBPs was characterized by a high-resolution transmission electron microscope, scanning electron microscope, atomic force microscope, X-ray photoelectron spectroscopy, and X-ray diffraction. The Ti2C NBPs have shown exceptional photothermal properties with increased temperature to 72.3 °C under 808 nm laser irradiation. The designed nano bipyramids demonstrated excellent cellular uptake and biocompatibility. The Ti2C NBP has established a remarkable photothermal therapy (PTT) effect against 4T1 breast cancer cells. Moreover, Ti2C NBPs showed a profound response to UV light (6 mW/cm2) and produced reactive oxygen species, making them useful for photodynamic therapy (PDT). These in-vitro studies pave a new path to tune the properties of photo-responsive MXene nanosheets, indicating a potential use in biomedical applications.

PH-responsive upconversion mesoporous silica nanospheres for combined multimodal diagnostic imaging and targeted photodynamic and photothermal cancer therapy

pH-responsive upconversion mesoporous silica nanospheres for combined multimodal diagnostic imaging and targeted photodynamic and photothermal cancer therapy

Graphene Nanocomposites in the Treatment of Pancreatic Cancer

The application value of titanium dioxide (TiO2)/graphene nanocomposites in photothermal therapy of pancreatic cancer (PC) was explored. Using scale graphite as raw material, graphene was obtained by Hummer oxidation method and hydrazine hydrate reduction method, and then TiO2/graphene nanocomposites were prepared by ultrasonic heating. Scanning electron microscopy (SEM), X-ray diffraction (XRD), and degraded methyl orange solution were adopted to detect the surface structure, particle size, element morphology, and photocatalytic activity under different composite ratios, different sonication times, and different heating temperatures. Human normal pancreatic ductal epithelial cell line HPDE6-C7 and human metastatic PC cell AsPC-1 were adopted as research models. The cytotoxicity of TiO2/graphene nanocomposites and the killing effect of photothermal therapy based on TiO2/graphene nanocomposites were analyzed by water soluble tetrazolium salt colorimetric assay (WST-1) and methyl thiazolyl tetrazolium salt colorimetric assay (MTT). The results suggested that when the ratio of graphene to TiO2 was 50:1, the ultrasonic time was 100 min, and the heating temperature was 200 °C, TiO2 was better attached to the surface of graphene, the distribution of particles was relatively more uniform, and the concentration of methyl orange was relatively lowest. The XRD pattern showed that the diffraction peak of the doped TiO2/graphene nanocomposite was basically the same as that of the pure TiO2. When the ultrasonic time was 100 min, the diffraction peak intensity in the XRD pattern was the largest. As for AsPC-1 cells, the cell viability was obviously lower than 0.1/1/10/100 μm/mL when the concentration of TiO2/graphene nanocomposites was 500 μm/mL (P <0.05). For HPDE6-C7 cells, when the concentration of TiO2/graphene nanocomposites was 100 and 500 μm/mL, the cell viability was obviously lower than 0.1/1/10 μm/mL (P <0.05), and 500 μm/mL was the lowest. The cell killing rate in group D was clearly higher as against groups A, B, and C (P <0.05). Graphene: The optimal preparation conditions of TiO2/graphene nanocomposites are 50:1, 100 min of ultrasound time, and 200 μC of composite temperature. The photothermal therapy based on TiO2/graphene nanocomposites can effectively kill PC cells, and has a good potential in the field of hyperthermia for pancreatic tumors.

Hypoxia-triggered degradable porphyrinic covalent organic framework for synergetic photodynamic and photothermal therapy of cancer

Nanomedicines receive great attention in cancer treatment. Nevertheless, nonbiodegradable and long-term retention still limit their clinical translation. Herein, we successfully synthesize a hypoxia-triggered degradable porphyrinic covalent organic framework (HPCOF) for antitumor therapy in vivo. HPCOF possesses wide absorption in near infrared region (NIR) which endows HPCOF excellent photothermal conversion efficiency and photoacoustic (PA) imaging ability. Moreover, HPCOF exhibits excellent photodynamic and photothermal effect under special-wavelength laser irradiation. For the first time, the in vitro and in vivo tests demonstrate that HPCOF shows effective therapeutic effect for the combination of PDT and PTT under the monitoring of PA imaging. Importantly, in tumor region, HPCOF could be triggered by hypoxia microenvironment and collapsed gradually, then cleared from the body after treatment. This work fabricates a novel COF for cancer treatment and testifies great potential of HPCOF in clinical application with reducing long-term toxicity.

Chitosan-initiated gold nanoparticles with enhanced fluorescence for unique Fe3+/PPi sensing and photothermal therapy

The design of surface ligands is crucial for ligand-protected gold nanoparticles (AuNPs). Herein, following the principle of green synthesis, environmentally friendly gold nanoparticles (AuNPs@His@CC, AuHC) were fabricated based on dual ligands of histidine and carboxylated chitosan. AuHC showed the advantages of low toxicity, good photoluminescent stability and ideal biocompatibility. Compared with single histidine-coated gold nanoclusters (AuNCs@His, AuH), AuHC presented enhanced fluorescence attributed to the addition of chitosan. The blue-emitting AuHC has a unique response to Fe3+ with detection limits as low as 9.51 nM. Interestingly, the quenched fluorescence of AuHC–Fe3+ system could be restored through the introduction of PPi with a detection limit of 10.6 μM. So an “on-off-on” fluorescence sensing platform was achieved. Apart from good optical properties and sensing, the designed AuHC demonstrated outstanding photothermal conversion efficiency (27.8 %), which made it ideal material for thermal ablation of tumor. To be specific, after laser irradiation (660 nm, 0.78 W cm−2, 10 min) of AuHC, the survival rate of HeLa cells as a tumor cell model decreased to 12.7 %, indicating that AuHC has a significant tumor inhibition effect in vitro. Besides, AuHC also could be a befitting candidate for overcoming drug-resistant tumor cells such as MCF-7/ADR cells. Notably, AuHC can markedly ablate solid tumors in 4T1 tumor-bearing mice after laser irradiation (660 nm, 0.78 W cm−2, 10 min). Hence this work provides insight into the design of multifunctional AuNPs platform for simultaneously integrating the ion sensing and photothermal therapy of cancer.