Photothermal Properties Research Articles

Principle of vanadium doping-induced MoS2 homojunction effect and mechanism analysis of antibacterial process under near-infrared light

MoS2 exhibits unique physical and chemical properties in its 1 T and 2H phases. Each phase has its inherent advantages and limitations. Although several biochemical properties of MoS2 have been extensively reported, the specific impacts of these phases on photothermal and antibacterial performance, the feasibility of integrating the unique advantages of both phases and the underlying dominant bactericidal mechanisms are still largely unexplored. In this work, the electronic-structural relationships of 1 T- and 2H-MoS2 were first simulated using density functional theory (DFT), which provided unique insights into how these phases affect performance. Based on these insights, a solid-state coupling interface and built-in electric field were designed between the two phases, and a 1 T/2H MoS2 homojunction was synthesized using the hydrothermal method, achieving a higher carrier separation efficiency and exhibiting excellent photothermal and antibacterial properties. Subsequently, further attempts were made to adjust the electronic structure by doping vanadium atoms. This doping not only introduces additional electrons to facilitate electron transfer but also further enhances the antibacterial capability by creating surface defects that increase the number of active sites. Finally, the synergistic antibacterial mechanism of this system was thoroughly investigated through detailed experiments and DFT theoretical analysis. The design of the homojunction, the introduction of defects, and the incorporation of heteroatoms were discussed in this paper, which pave the way for the rational design strategy of advanced two-dimensional materials and can be extended to other polycrystalline materials.

Electrospun Silk-ICG Composite Fibers and the Application toward Hemorrhage Control.

In trauma and surgery, efficient hemorrhage control is crucial to avert fatal blood loss and increase the likelihood of survival. There is a significant demand for novel biomaterials capable of promptly and effectively managing bleeding. This study aimed to develop flexible biocomposite fibrous scaffolds with an electrospinning technique using silk fibroin (SF) and indocyanine green (ICG). The FDA-approved ICG dye has unique photothermal properties. The water permeability, degradability, and biocompatibility of Bombyx mori cocoon-derived SF make it promising for biomedical applications. While as-spun SF-ICG fibers were dissolvable in water, ethanol vapor treatment (EVT) effectively induced secondary structural changes to promote β-sheet formation. This resulted in significantly improved aqueous stability and mechanical strength of the fibers, thereby increasing their fluid uptake capability. The enhanced SF-ICG interaction effectively prevented ICG leaching from the composite fibers, enabling them to generate heat under NIR irradiation due to ICG's photothermal properties. Our results showed that an SF-ICG 0.4% fibrous matrix can uptake 473% water. When water was replaced by bovine blood, a 25 s NIR irradiation induced complete blood coagulation. However, pure silk did not have the same effect. Additionally, NIR irradiation of the SF-ICG fibers successfully stopped the flow of blood in an in vitro model that mimicked a damaged blood vessel. This novel breakthrough offers a biotextile platform poised to enhance patient outcomes across various medical scenarios, representing a significant milestone in functional biomaterials.

Development of MnO2 nanosheets nanozyme-based colorimetric and photothermal dual-signal platform for monitoring alkaline phosphatase activity

Herein, a dual-signal biosensing platform for monitoring alkaline phosphatase (ALP) activity was developed. This platform combined the oxidase-mimicking activity of MnO2 nanosheets (NS) with the colorimetric and photothermal properties of oxidized 3,3′,5,5′-tetramethylbenzidine (oxTMB). MnO2 NS effectively catalyzed the oxidation of TMB to oxTMB, resulting in a color change from colorless to blue and a significant light absorption band at 652 nm. Meanwhile, oxTMB demonstrated pronounced photothermal properties, with the solution exhibiting a notable increase in temperature upon irradiation with an 808 nm laser. In the presence of ALP, 2-Phospho-L-ascorbic acid trisodium salt (AAP) was converted into L-ascorbic acid (L-AA), which then reacted with MnO2 NS. Consequently, MnO2 NS was inhibited from oxidizing TMB to oxTMB. Based on this principle, a dual-readout assay that integrated both colorimetric and photothermal signals for ALP detection was developed. The detection limits were 0.08 mU/mL for the colorimetric method and 0.12 mU/mL for the photothermal method. Furthermore, the platform was successfully applied to human serum samples, demonstrating its effectiveness in detecting ALP in complex biological matrices. The combination of colorimetric and photothermal responses enhanced both the accuracy and reliability of ALP detection, making this platform a promising tool for biomedical applications.

Gambogic acid and IR780 self-assembled nanoparticles for combined chemo-phototherapy

Combined chemo-phototherapy has shown considerable advantages and potential in cancer treatment. For this purpose, self-assembled nanoparticles by gambogic acid (GA) and IR780 (referred to as GA-IR780 NPs) were prepared. Herein, GA, an active compound derived from Garcinia hanburyi Hook.f, was selected as a chemo-agent. IR780 was used as a photothermal agent as well as a photosensitizer, which could kill tumor cells via photothermal effect and photodynamic effect. The obtained GA-IR780 NPs were uniform spheres with particle size of ca. 50 nm. The drug loading efficiency of GA and IR780 was 38.42 % and 56.64 %, respectively. The GA-IR780 NPs exhibited excellent photothermal properties as well as photodynamic effect when irradiated by near infrared (NIR) light (808 nm, 2.0 W/cm2). Moreover, the GA-IR780 NPs showed enhanced cytotoxicity with NIR light activation. Results of animal experiments showed that GA-IR780 NPs had the most significant tumor inhibition when irradiated by laser, and the results of H&E, Ki-67 and TUNEL staining confirmed that the GA-IR780 NPs+Laser group caused the most severe tumor tissue damage. The above results indicated that GA-mediated chemotherapy combining with IR780-based phototherapy could significantly improve the anti-tumor efficacy.

Engineering Thermally Reduced Graphene Oxide for Synchronously Enhancing Photocatalytic Activity and Photothermal Effect.

The structural composition of reduced graphene oxide (rGO) can be modified and controlled by appropriate reduction methods to modulate its electronic structure, rendering it a versatile platform for tailoring optoelectronic and catalytic properties. Nevertheless, it is uncommon to concurrently amplify the photocatalytic and photothermal effects when regulating and utilizing pure rGO. Here, we investigate the impact of structural variations in thermally reduced graphene oxide (TGO) on its photocatalytic and photothermal properties. Various characterization results demonstrate that appropriate thermal reduction facilitates the preservation and transformation of oxygenated groups and structure defects, which in turn encourages the formation of reactive carbon radicals and discrete graphitic domains, thereby strengthening the activation of molecular oxygen and the plasmonic photothermal effect under near-infrared (NIR) light irradiation. Moreover, the optimized TGOs exhibit efficient sterilization with NIR irradiation due to enhanced photocatalytic activities and photothermal effects. This work highlights the potential for developing photocatalytic and photothermal rGO-based materials through structural engineering.

Eumelanin-Enhanced Photothermal Disinfection of Contact Lenses Using a Sustainable Marine Nanoplatform Engineered with Electrospun Nanofibers.

Bacterial keratitis (BK) is a severe eye infection commonly associated with Staphylococcus aureus (S. aureus), posing a significant risk to vision, especially among contact lens wearers. This research introduces a novel smart nanoplatform (deMS@cNF), developed from demineralized mussel shells (deMS) and reinforced with chitin (CT) nanofibrils, specifically designed for portable photothermal disinfection of contact lenses. The nanoplatform leverages the photothermal properties of eumelanin in mussel shells (MS), which, when activated by a simple bike flashlight, rapidly heats to temperatures up to 95°C, effectively destroying bacterial contamination. In vitro tests demonstrate that the nanoplatform is biocompatible and non-toxic, making it suitable for medical applications. This study highlights an innovative approach to converting marine biowaste into a safe, effective, and low-cost portable method for disinfecting contact lenses, showcasing the potential of the deMS@cNF platform for broader antimicrobial applications.

D-arginine-functionalized carbon dots with enhanced near-infrared emission and prolonged metabolism time for tumor fluorescent-guided photothermal therapy

Carbon dots (CDs) have garnered significant interest owing to their distinctive optical properties. However, their bioimaging and biomedical applications are limited by pronounced fluorescence (FL) quenching in aqueous media and low tumor accumulation efficacy associated with their ultra-small size. This study proposes a simple surface modification approach using functioning d-arginine on CDs (d-Arg@CDs) to improve their near-infrared (NIR) FL in aqueous solution and maintain their high photothermal conversion properties. Because of the low utilization rate of dextral amino acids in animals, modifying CDs with low molecular weight d-arginine did not increase particle size but extended the metabolism time in blood circulation, thereby leading to enhanced accumulation efficacy at tumor sites in the mice model. The enhanced tumor accumulation of d-Arg@CDs resulted in significantly superior tumor NIR FL imaging and photothermal therapy performance compared with pure CDs and l-arginine functionalized CDs. This dextral amino acid modification approach is expected to be an effective tool for enhancing the biomedical applications of CDs.

A novel solar-driven thermogalvanic cell with integrated heat storage capabilities

Low-grade heat sources like solar thermal radiation offer a vast energy resource. However, their low utilization rate limits energy recovery and conversion efficiency. Solar thermogalvanic cells, utilizing solar thermal radiation as a heat source, are considered an effective way to harness solar energy. However, their widespread application is hindered by performance instability due to periodic solar radiation fluctuations. This study developed composite electrodes with high conductivity, excellent photothermal properties, and heat storage capabilities, and applied them in thermogalvanic cells. Compared to traditional thermal chemical cells, the new heat storage electrode materials significantly enhance the stability and energy output efficiency. The results show that under temperature fluctuations, the new thermal chemical cells (EG/SA/LA-TGCs) significantly improve power output stability. The temperature difference increased from 6 °C to 17 °C, with the open-circuit voltage rising to 32 mV. Thanks to the electrodes’ heat storage and release capability, the heat released by the electrodes sustains the cell’s power generation. The discharge duration per unit volume of the electrode reached 12.74 min/cm3, 15 times longer than traditional thermal chemical cells.

Photothermal-assisted magnetic recoverable Cd0.9Zn0.1S/NiCoB heterojunction with extraordinary photocatalytic hydrogen evolution

Easily recyclable photocatalysts hold great potential in the field of photocatalysis. Guided by rational theoretical predictions, this study designs a novel tetrapod-like Cd0.9Zn0.1S/NiCoB (CZS/NCB) Schottky heterojunction with magnetic and photothermal properties, and demonstrates its excellent photocatalytic hydrogen evolution performance. Under the combined effects of the photothermal properties and the Schottky heterojunction, the photocatalytic hydrogen evolution rate extraordinarily reaches 108.39 mmol g−1 h−1 after 3 h of visible light irradiation, which is 4.69 times that of pure CZS. Additionally, photocatalytic hydrogen evolution tests conducted using infrared thermography and alternating visible and visible plus infrared light irradiation have confirmed the material’s outstanding photothermal properties. In-depth density functional theory (DFT) calculations reveal potential charge transfer pathways and confirm the formation of the Schottky heterojunction. This work provides guidance for the rational construction of magnetic recoverable photocatalysts with practical application.

Near-Infrared Stimuli-Responsive Hydrogel Promotes Cell Migration for Accelerated Diabetic Wound Healing.

Diabetic wound healing including diabetic foot ulcers is a major clinical challenge, which could bring an increased level of mortality and morbidity. However, conventional wound dressings exhibit limited healing efficacy due to their lack of active modulation for the healing process. Here, a near-infrared (NIR) stimuli-responsive composite hydrogel dressing with the synergistic effect of both mechanical contraction and epithelial-mesenchymal transition (EMT) was developed to facilitate cell migration and vascularization for diabetic wound healing. In the methacrylated gelatin-based composite hydrogel, N-isopropylacrylamide and polydopamine nanoparticles were incorporated to endow the composite hydrogel with thermosensitive and photothermal properties. Linagliptin (LIN) was loaded into the composite hydrogel, and the drug release rate could be controlled by NIR laser irradiation. NIR-triggered on-demand active contraction of wound area and LIN release for biological stimulation were potentially realized in this responsive system due to the thermally induced sol-gel transition of the composite hydrogel. The release of loaded LIN could effectively promote cell migration by activating EMT and enhancing angiogenesis. In the full-thickness skin defect model, the LIN-loaded composite hydrogel with NIR laser irradiation had the highest wound closure rate as compared with the pure hydrogel and LIN-loaded hydrogel groups. Therefore, this composite hydrogel can serve as an excellent platform for promoting wound healing and will find more practical value in clinical treatment.

Tailorable MBene aerogel with the lowest evaporation enthalpy for solar seawater desalination and wastewater purification

Growing global water scarcity has fueled the quest for sustainable and effective desalination solutions under lower energy requirements. However, it has a common strategy that has led to reducing the enthalpy of evaporation of water during solar-driven interfacial evaporation by dual-layer aerogels with effective mechanical robustness. Here, we introduce a novel class of 2D transition metal boride (MBene) integrated into the hydratable polymeric network of Polyvinyl alcohol/Chitosan/Polyurethane (MPCP) for an “all-in-one” solar evaporator. This dual-layer aerogel possesses both photothermal properties (for evaporating seawater) and reduced evaporation enthalpy (resulting in lower energy requirements). The MPCP aerogel gains broadband light absorption, and effective heat localization and exploits the polar groups on the polymer chains to interact with water molecules, resulting in reduced enthalpies of evaporation of 1132 J g−1 for water and 1245 J g−1 for seawater, which promotes excellent solar steam generation performance with a high evaporation rate of 2.83 kg/m2h under 1 kW m−2 solar intensity. The MBene aerogel has favorable endurance and versatility in effectively treating a wide range of polluted wastewater sources, such as organic dyes and heavy metal solutions, with high efficiency and exceptional longevity under real seawater tests over 20 consecutive days. This work could guide the development of MBenes for efficient solar-driven water evaporation and wastewater remediation.

Influence of excitation light wavelength and irradiation time on photothermal properties of photochemically synthesized colloidal gold

Influence of excitation light wavelength and irradiation time on photothermal properties of photochemically synthesized colloidal gold

Generation of oxygen vacancies in CuO/TiO2 heterojunction induced by diatomite for highly efficient UV–Vis-IR driven photothermal catalytic oxidation of HCHO

Photothermal catalytic oxidation is a promising and sustainable method for the degradation of indoor formaldehyde (HCHO). However, the excessively high surface temperature of existing photothermal catalysts during catalysis hinders the effective adsorption and degradation of formaldehyde under static conditions. Catalyst loading and oxygen vacancies (OVs) modulation are commonly employed strategies to reduce the photothermal catalytic temperature and enhance the efficiency of photothermal catalytic oxidation. In this work, a p-n type CuO/TiO2 heterojunction is successfully loaded onto diatomite using a wet precipitation method. Under the irradiation of a 300W xenon lamp, the prepared composite material achieved a 100% removal rate of HCHO within 2 h, with a 98% conversion rate to CO2, surpassing the performance of both individual photocatalysts and thermocatalysts. Additionally, by adjusting conditions such as light irradiation and temperature, we have demonstrated that this material exhibits synergistic photothermal catalytic properties. Based on HRTEM, XPS, Raman, and EPR analyses, the introduction of diatomite as a catalyst support was shown to effectively increase the number of OVs. Experimental results, along with O2-TPD, photoelectrochemical characterization, and radical detection, demonstrate that the presence of OVs enhances the oxidative efficiency of both photocatalysis and thermocatalysis, as well as the UV–Vis-IR photothermal catalytic performance. The ternary composite material generates weak hydroxyl (•OH) and superoxide (•O2−) radical under high-temperature with dark conditions, indicating its catalytic oxidation activity under this condition. The increase in temperature and the expansion of the spectral range both enhance the generation of these radicals. In summary, this work demonstrates that the use of diatomite as a support increases the material's specific surface area and OVs content, thereby enhancing adsorption and photothermal catalysis. It elucidates the enhanced catalytic degradation mechanism of this mineral-based photothermal catalyst.

Preparation and photothermal properties of latent functional thermal fluid based on size-controllable phase change nanocapsules

To improve the solar heat utilization efficiency of working fluid in direct solar collector, a novel latent functional thermal fluid (LFTF) based on self-designed 1-octadecanol@silica phase change nanocapsules (NEPCMs) with excellent heat storage capacity and photothermal conversion efficiency were prepared. The NEPCMs prepared by sol–gel method were dispersed in water containing multi-walled carbon nanoparticles to prepare the LFTF. The prepared NEPCMs have high encapsulation efficiency (85.12 %) and melting phase change enthalpy (235.1 J/g), controllable particle size (27.13–167.30 nm), excellent thermal stability and cycle stability. The LFTF containing 10 wt% NEPCMs was considered the optimal choice for its excellent dispersion stability (zeta potential 35.63 mV), thermal storage capacity (peak specific heat capacity 5.11 J·g−1·K−1) and superior photothermal conversion efficiency (up to 98 %), which is roughly 3.29 times that of water. These results offer valuable insights for the future development of LFTF in the field of solar thermal applications.

Study on three-dimensional porous carbon fiber-MWCNTs-PEG phase change materials and its photo/electricity-thermal conversion performance

Solar energy, as a crucial green energy source, attracted significant attention. Phase change materials (PCMs) addressed the intermittency issue by storing and releasing latent heat. This study innovatively combined carbon fibers (CFs), phenolic resin, polyethylene glycol (PEG), and multi-walled carbon nanotubes (MWCNTs) to create high-loading (>86 %) and high-enthalpy composite CF-based phase change materials (CFPCMs), with melting and freezing enthalpies of 156.6 J/g and 148.6 J/g. CFPCMs demonstrated excellent photothermal and electrothermal properties. The lightweight, porous CFs structure stabilized the PCMs matrix, enhancing its performance while facilitating the reuse of waste CFs products, thus contributing to environmental protection.

Photothermal and host immune activated therapy of cutaneous tuberculosis using macrophage targeted mesoporous polydopamine nanoparticles

Tuberculosis (TB) remains the leading cause of deaths among infectious diseases worldwide. Cutaneous Tuberculosis (CTB), caused by Mycobacterium tuberculosis (Mtb) infection in the skin, is still a harmful public health issue that requires more effective treatment strategy. Herein, we introduced mannose-modified mesoporous polydopamine nanosystems (Man-mPDA NPs) as the macrophage-targeted vectors to deliver anti-TB drug rifampicin and as photothermal agent to facilitate photothermal therapy (PTT) against Mtb infected macrophages for synergistic treatment of CTB. Based on the selective macrophage targeting effects, the proposed Rif@Man-mPDA NPs also showed excellent photothermal properties to develop Rif@Man-mPDA NPs-mediated PTT for intracellular Mtb killings in macrophages. Importantly, Rif@Man-mPDA NPs could inhibit the immune escape of Mtb by effectively chelating intracellular Fe2+ and inhibiting lipid peroxidation, and up-regulating GPX4 expression to inhibit ferroptosis of Mtb infected macrophages through activating Nrf2/HO-1 signaling. Moreover, Rif@Man-mPDA NPs-mediated PTT could effectively activate host cell immune responses by promoting autophagy of Mtb infected macrophages, which thus synergizes targeted drug delivery and ferroptosis inhibition for more effective intracellular Mtb clearance. This Rif@Man-mPDA NPs-mediated PTT strategy could also effectively inhibit the Mtb burdens and alleviate the pathological lesions induced by Mtb infection without significant systemic side effects in mouse CTB model. These results indicate that Rif@Man-mPDA NPs-mediated PTT can be served as a novel anti-TB strategy against CTB by synergizing macrophage targeted photothermal therapy and host immune defenses, thus holding promise for more effective treatment strategy development against CTB.

Hydrogel microspheres encapsulating lysozyme/MXene for photothermally enhanced antibacterial activity and infected wound healing

The high mortality and enormous economic burden of bacterially infected wounds remains a huge challenge for human health. The development of ideal wound dressings with desirable antibacterial and good wound healing properties still remains a major problem affecting the regeneration of bacterially infected wound tissue. Herein, we present novel alginate-based hydrogel microspheres containing lysozyme and MXene (i-Lyso@Alg), in which the positively charged lysozyme is immobilized on the negatively charged MXene by electrostatic interaction. Due to the presence of MXene, i-Lyso@Alg exhibits good thermal effect, drug release behavior and strong antibacterial activity under near-infrared (NIR) irradiation. The synthesized i-Lyso@Alg can realize not only improvement of lysozyme stability but also photothermal responsive up-regulation for biocatalysis of lysozyme. The excellent antibacterial activities of i-Lyso@Alg were attributed to the photothermally enhanced lysozyme activity, assisted by bacterial death caused by local thermal effect of photothermally activated MXene and the physical damage due to the MXene. In addition, in the infected skin wounds of rats, i-Lyso@Alg + NIR significantly accelerates the wound healing process by inhibiting the expression of inflammatory factors and bacterial (Staphylococcus aureus) infection, and inducing the expression of pro-angiogenic factors and tissue remodeling. Overall, the results of this study introduce a pioneering approach by integrating the unique photothermal properties of MXene with the enzymatic action of lysozyme within an alginate-based hydrogel microsphere. This synergistic system not only advances the frontier of antibacterial wound dressings but also represents a significant step towards effective management of infected wounds, which possesses great potential in clinical treatment of infected wounds.

Redox Concomitant Formation Method for Fabrication of Cu(I)-MOF/Polymer Composites with Antifouling Properties.

Marine biofouling, which is one of the technical challenges hindering the growth of the marine economy, has been controlled using cuprous oxide (Cu2O) nanoparticles due to the exceptional antifouling properties of Cu(I) ions. However, Cu2O nanoparticles have encountered bottlenecks due to explosive releases of Cu+ ions, high toxicity at elevated doses, and long-term instability. Here, we present a novel method called Redox Concomitant Formation (RCF) for fabricating a hierarchical Cu(I) metal-organic framework polypyrrole (Cu(I)-MOF/PPy) composite. This method enables in-situ phase transition via successive redox reactions that change the chemical valence state and coordination mode of Cu(II)-MOF, resulting in a new structure of Cu(I)-MOF while creating a PPy layer surrounded by the hierarchical structure. Owing to the steady release of Cu+ ions from the Cu(I) sites and photothermal properties of PPy, Cu(I)-MOF/PPy exhibits superior and broad-spectrum resistance to marine bacteria, algae, and surface-adhered biofilms in complex biological environments, as well as long-term stability, resulting in 100% eradication efficiency under solar-driven heating. Mechanistic insights into successive structural redox reactions and formation using the RCF method are provided in detail, enabling the fabrication of novel MOFs with the desired composition and structure for a wide range of potential applications.

Redox Concomitant Formation Method for Fabrication of Cu(I)−MOF/Polymer Composites with Antifouling Properties

AbstractMarine biofouling, which is one of the technical challenges hindering the growth of the marine economy, has been controlled using cuprous oxide (Cu2O) nanoparticles due to the exceptional antifouling properties of Cu(I) ions. However, Cu2O nanoparticles have encountered bottlenecks due to explosive releases of Cu+ ions, high toxicity at elevated doses, and long‐term instability. Here, we present a novel method called Redox Concomitant Formation (RCF) for fabricating a hierarchical Cu(I) metal–organic framework polypyrrole (Cu(I)−MOF/PPy) composite. This method enables in situ phase transition via successive redox reactions that change the chemical valence state and coordination mode of Cu(II)−MOF, resulting in a new structure of Cu(I)−MOF while creating a PPy layer surrounded by the hierarchical structure. Owing to the steady release of Cu+ ions from the Cu(I) sites and photothermal properties of PPy, Cu(I)−MOF/PPy exhibits superior and broad‐spectrum resistance to marine bacteria, algae, and surface‐adhered biofilms in complex biological environments, as well as long‐term stability, resulting in 100 % eradication efficiency under solar‐driven heating. Mechanistic insights into successive structural redox reactions and formation using the RCF method are provided in detail, enabling the fabrication of novel MOFs with the desired composition and structure for a wide range of potential applications.

Biomimetic modification of macrophage membrane-coated prussian blue nanoparticles loaded with SN-38 to treat colorectal cancer by photothermal-chemotherapy.

SN-38 is the active metabolite of irinotecan and acts as an effective topoisomerase I inhibitor with therapeutic effects on many malignant tumors, including some drug-resistant cancers. However, the poor solubility, low bioavailability, and severe dose-dependent toxicity limits the clinical application of SN-38. Currently, emerging macrophage membrane-coated nanoparticles provide an efficient biomimetic approach to develop novel SN-38 formulations for the reduction of its side effects. Photothermal therapy (PTT) is a promising methods in tumor treatment to thermally ablate tumors using various materials such Prussian blue nanoparticles (NPs) and can combined with chemotherapy to synergistically work. There is no report that combined SN38 and photothermal therapy for the treatment of colorectal cancer (CRC). SN38-PB@CM NPs were constructed by loading SN-38 into macrophage cell membrane-coated hollow mesoporous Prussian blue (PB) NPs. The morphology, size and zeta potential were evaluated by transmission microscopy and dynamic light scatter (DLS). Coomassie bright blue staining was performed to assess total protein profile. The photothermal properties of it were also investigated via near-infrared imaging. CCK8 and calcein-AM/PI staining were used to evaluate cell viability. Flow cytometry was performed to assess cell apoptosis. The fluorescent microscopy was used to observe cellular uptake of SN38-PB@CM NPs to assess its internalization in vitro. The biodistribution, tumor-targeting efficacy, antitumor efficacy and safety of SN38-PB@CM NPs in vivo were assessed in CT26 tumor-bearing mice via In Vivo Imaging System. SN38-PB@CM NPs were successfully constructed and exhibited a uniform size distribution (140.5 ± 4.3nm) and an excellent drug-loading capacity (5.61 ± 0.64%). SN38-PB@CM NPs showed stable release properties within 72h. It can also enhance the selective intracellular delivery of SN38 in vitro and showed good near-infrared (NIR) photothermal properties. And the NPs showed excellent tumor targeting, effective photothermal therapy, improved biosafety and antitumor efficacy on CT26-bearing mice. Multifunctional SN38-PB@CM NPs could achieve improved biosafety, great tumor-targeting, high-efficiency PTT and excellent antitumor efficacy, which provided a promising and attractive combination therapy for the treatment of CRC.