High Tumor Accumulation Research Articles

Evaluation of maSSS/maSES-PEG2-RM26 for their potential therapeutic use after labeling with Re-188. Could their [99mTc]Tc-labeled counterparts be used to estimate dosimetry?

BackgroundGastrin releasing peptide receptor (GRPR)-directed radiopharmaceuticals for targeted radionuclide therapy may be a very promising addition in prostate and breast cancer patient management. Aiming to provide a GRPR-targeting theranostic pair, we have utilized the Tc-99m/Re-188 radiometal pair, in combination with two bombesin based antagonists, maSSS-PEG2-RM26 and maSES-PEG2-RM26. The two main aims of the current study were (i) to elucidate the influence of the radiometal-exchange on the biodistribution profile of the two peptides and (ii) to evaluate the feasibility of using the [99mTc]Tc labeled counterparts for the dosimetry estimation for the [188Re]Re-labeled conjugates.ResultsBoth peptides were successfully labeled with Re-188 and evaluated both in vitro and in vivo. In GRPR expressing PC-3 cells, both [188Re]Re-labeled peptides displayed high cellular uptake (8.5 ± 0.1% and 5 ± 0.3% of added activity, respectively), heavily GRPR-driven, while retaining the radioantagonistic profile with slow internalization rates. Both agents demonstrated high receptor affinity when loaded with natRe (7.5 nM and 8 nM, respectively). When tested in vivo in GRPR expressing PC-3 xenografts, both radioantagonists demonstrated high tumor accumulation (6.3 ± 0.5%IA/g and 5 ± 1%IA/g at 1 h pi, respectively), with good retention over time (4 ± 2%IA/g and 3.1 ± 0.1%IA/g at 4 h pi, respectively). In addition, their biodistribution profiles were closely mimicking their [99mTc]Tc-labeled counterparts. Statistically significant lower tumor uptake was found for both conjugates labeled with Tc-99m, which may result in underestimation of the dose delivered to the tumor.ConclusionsAll the results indicate that Tc-99 m could be used for dosimetry evaluation for the two [188Re]Re-labeled radioligands, with minimal alterations in their biodistribution pattern and tumor targeting capabilities.

Triple-action cancer therapy using laser-activated NO-releasing metallomicellar nanophotosensitizer for pyroptosis-driven immune reprogramming.

Cancer photoimmunotherapy represents an intelligent and highly efficient therapeutic approach that harnesses the photothermal effect to precisely target and ablate tumor tissues, while simultaneously modulating the immune system to achieve tumor elimination. The integration of multifunctional therapeutic modalities for combined photoimmunotherapy requires advanced drug delivery systems. However, the design of a single nanoagent capable of serving as a multifunctional nanophotosensitizer remains a significant challenge. In this study, we developed a metallomicellar nanophotosensitizer named TAGNO, which offers a synergistic tri-modal cancer treatment strategy by combining photothermal therapy (PTT), gas therapy (GT), and immunotherapy. The TAGNO nanophotosensitizer consists of a gold nanorod core, responsible for inducing the photothermal effect, coated with an amphiphilic polymer functionalized with tumor cell penetrating peptide to accommodate lipophilic small molecule BNN6, a nitric oxide (NO) donor for GT. We demonstrated that TAGNO exhibited high tumor accumulation, excellent stability, and biocompatibility, ensuring the safe delivery of NO to the tumor site. Upon near-infrared (NIR) laser irradiation, TAGNO effectively raised the temperature within tumor tissues while sparing the surrounding healthy tissues and enabled controlled NO release. Once released, the NO interacts with hydrogen peroxide in the hypoxic tumor microenvironment, forming peroxynitrite (ONOO-), which induces mitochondrial dysfunction and triggers pyroptotic cell death. Pyroptosis induced immunogenic cell death and the subsequent release of tumor antigens, activating cytotoxic T cells and promoting M1 macrophage polarization, effectively controlling both primary and secondary tumor growth. Furthermore, laser-induced NO release facilitated the relaxation of stiff tumor tissues, enhancing blood vessel dilation and oxygenation. This improvement promoted immune cell infiltration while suppressing immunosuppressive cells. Overall, this innovative combination of PTT, GT, and immunotherapy presents a potent and synergistic strategy for the treatment of malignant colon tumors, achieving complete tumor eradication.

Acid-triggered size reduction of nanomedicines for enhancing tumor therapy efficacy.

Nanomedicines whose size can be varied on demand may synchronously achieve excellent tumor accumulation and penetration. In this study, by taking advantage of the pH sensitivity of a boronate ester, we synthesized acid-triggered size-reducing polymer nanoparticles (named PCD) by cross-linking β-cyclodextrin-cored multiarm polymers through the boronate ester. In PCD, the antitumor agent doxorubicin was loaded via the pH-sensitive hydrazone linkage. The in vitro and in vivo properties of PCD were investigated using a non-responsive nanoparticle (named UCD) as a reference. In the neutral condition of the bloodstream, PCD was stable and exhibited a suitable size for long circulation time. Upon entering tumors, PCD decomposed into stable and smaller multiarm polymers, which could deeply penetrate tumors. The high tumor accumulation and penetration of PCD offered significantly better anti-tumor efficacy than UCD.

Chemical Synthesis and Multihybridization of Small-Sized Hollow Mesoporous Organosilica Nanoparticles Toward Advanced Theranostics.

ConspectusAs one of the most widely used nanomaterials, mesoporous silica nanoparticles (MSNs) have received extensive attraction due to their desirable physicochemical performances of high stability, large surface area, and tunable pore sizes. Besides, the U.S. Food and Drug Administration (FDA) has recognized that silica-based nanoparticles are generally safe for biomedical applications. However, the poor biodegradation and inert Si-O-Si framework of inorganic MSNs severely impair their diverse biomedical applications. A promising strategy to improve the physicochemical properties of MSNs is the incorporation of functional organic moieties into their framework to construct mesoporous organosilica nanoparticles (MONs), which exhibit distinct advantages over traditional inorganic MSNs, such as adjustable organosilica framework, excellent biocompatibility, stimuli-responsive biodegradability, and even improved therapeutic effects. Moreover, the emerging hollow-structured MONs (HMONs) with an internal cavity can offer a large drug loading capacity and thus become increasingly attractive and promising theranostic nanoplatforms in biomedicine. In recent years, numerous studies have delved into establishing multifunctional HMONs with sizes ranging in diameters from 50 to 200 nm for desirable biological responses. With the gradual deepening of research, small-sized HMONs with diameters below 50 nm (sub-50 nm HMONs) demonstrate unparalleled advantages in extending blood circulation time, reducing the risk of vascular occlusion, and achieving high tumor accumulation, thus leading to a growing interest in the design, development, and translation of sub-50 nm HMONs. However, the mechanism of the chemical synthesis and structural regulation of sub-50 nm HMONs is still unclear, which is detrimental to further structural hybridization and surface functionalization.In this account, we will focus on the structural design, chemical synthesis, adjustable framework hybridization, multifunctional surface modification, and versatile biomedical applications of small-sized HMONs. First, we will illustrate the chemical approaches for controllable synthesis of HMONs and the underlying mechanism of particle size regulation below 50 nm. Subsequently, the basic principles and design strategies of multihybridization of sub-50 nm HMONs based on framework hybridization, surface modulation, and in situ polymerization will be systematically discussed. Through diverse functionalization strategies, a series of sub-50 nm multihybridized HMONs-based nanotheranostics are established, and their applications in multimodal biomedical imaging and highly efficient synergistic treatment of various diseases (e.g., cancer, glaucoma, bacterial infection, etc.) will be accounted. Finally, we will summarize the current status and potential challenges of HMONs in clinic trials, as well as provide a comprehensive outlook on the future development of sub-50 nm HMONs. These innovative sub-50 nm HMONs hold the potential to introduce novel theranostic modalities for a variety of systemic disorders and to advance smart promising nanomedicine in the near future.

Engineered microalgae for photo-sonodynamic synergistic therapy in breast cancer treatment.

Dynamic therapies such as photodynamic therapy (PDT) and sonodynamic therapy (SDT) have potential in cancer treatment. Microalgae have attracted increasing attention because of their high active mobility, flexibility in terms of functionality, and good biocompatibility. In this study, surface-engineered microalgae Chlorella vulgaris (Chl) modified with metal‒organic framework (MOF) nanoparticles (denoted Chl-MOF) are successfully developed for synergistic photo-sonodynamic therapy and immunotherapy. The resulting Chl-MOF can be used as an oxygenator for O2 generation through Chl-mediated photosynthesis, alleviating tumor hypoxia. Furthermore, Chl-MOF produces reactive oxygen species (ROS) during laser and ultrasound (US) irradiation, further augmenting the photo-sonodynamic effects and enhancing tumor cell apoptosis. Owing to the high mobility of Chl, cellular uptake efficiency and accumulation in deep tumor sites are 5.2-fold and 3.3-fold higher, respectively, for Chl-MOF than for the MOF. Owing to the immunomodulatory effects of Chl, Chl-MOF can increase natural killer (NK) cell cytotoxic activity, increase dendritic cell (DC) antigen-presenting ability, reverse the establishment of an immunosuppressive tumor microenvironment (TME), and induce a relatively strong antitumor immune response. Chl-MOF can effectively reduce breast cancer size by 88.8 % in vitro and in vivo via synergistic photo-sonodynamic therapy and immunotherapy. These intriguing properties of the combination of Chl and MOF provide promising platform for cancer theranostic applications. STATEMENT OF SIGNIFICANCE: : • Chl acts as an O2 generator for alleviating hypoxia in tumors. • The high mobility of Chl resulted in 3.3-folds higher tumor accumulation. • The Chl-MOF can induce synergistic photo-sonodynamic effects and a relatively strong antitumor immune response. • Chl-MOF effectively reduce breast cancer size by 88.8 % via synergistic therapies.

Pulmonary delivery of dual-targeted nanoparticles improves tumor accumulation and cancer cell targeting by restricting macrophage interception in orthotopic lung tumors

Despite the recognized potential of inhaled nanomedicines to enhance and sustain local drug concentrations for lung cancer treatment, the influence of macrophage uptake on targeted nanoparticle delivery to and within tumors remains unclear. Here, we developed three ligand-coated nanoparticles for pulmonary delivery in lung cancer therapy: phenylboronic acid-modified nanoparticles (PBA-NPs), PBA combined with folic acid (FA-PBA-NPs), and PBA with mannose (MAN-PBA-NPs). In vitro, MAN-PBA-NPs were preferentially internalized by macrophages, whereas FA-PBA-NPs exhibited superior uptake by cancer cells compared to macrophages. Following intratracheal instillation into mice with orthotopic Lewis lung carcinoma tumors, all three nanoparticles showed similar lung retention. However, MAN-PBA-NPs were more prone to interception by lung macrophages, which limited their accumulation in tumor tissues. In contrast, both PBA-NPs and FA-PBA-NPs achieved comparable high tumor accumulation (∼11.3% of the dose). Furthermore, FA-PBA-NPs were internalized by ∼30% of cancer cells, significantly more than the 10–18% seen with PBA-NPs or MAN-PBA-NPs. Additionally, FA-PBA-NPs loaded with icaritin effectively inhibited the Wnt/β-catenin pathway, resulting in superior anti-tumor efficacy through targeted cancer cell delivery. Overall, FA-PBA-NPs demonstrated advantageous competitive uptake kinetics by cancer cells compared to macrophages, enhancing tumor targeting and therapeutic outcomes.

Engineering Radiocatalytic Nanoliposomes with Hydrophobic Gold Nanoclusters for Radiotherapy Enhancement.

Chemoradiation therapy is on the forefront of pancreatic cancer care, and there is a continued effort to improve its safety and efficacy. Liposomes are widely used to improve chemotherapy safety, and may accurately deliver high-Z element- radiocatalytic nanomaterials to cancer tissues. In this study, the interaction between X-rays and long-circulating nanoliposome formulations loaded with gold nanoclusters is explored in the context of oxaliplatin chemotherapy for desmoplastic pancreatic cancer. Hydrophobic gold nanoclusters stabilized with dodecanethiol (AuDDT) are efficiently incorporated in nanoliposomal bilayers. AuDDT-nanoliposomes significantly augmented radiation-induced •OH production, which is most effective with monochromatic X-rays at energies that exceed the K-shell electron binding energy of Au (81.7keV). Cargo release assays reveal that AuDDT-nanoliposomes can permeabilize lipid bilayers in an X-ray dose- and formulation-dependent manner. The radiocatalytic effect of AuDDT-nanoliposomes significantly augments radiotherapy and oxaliplatin-chemoradiotherapy outcomes in 3D pancreatic microtumors. The PEGylated AuDDT-nanoliposomes display high tumor accumulation in an orthotopic mouse model of pancreatic cancer, showing promise for nanoliposomes as carriers for radiocatalytic nanomaterials. Altogether, compelling proof for chemo-radiation dose-enhancement using AuDDT-nanoliposomes is presented. Further improving the nanoliposomal loading of high-Z elements will advance the safety, efficacy, and translatability of such chemoradiation dose-enhancement approaches.

Morphology-Mediated Tumor Deep Penetration for Enhanced Near Infrared II Photothermal and Chemotherapy of Colorectal Cancer.

The low permeability and heterogeneous distribution of drugs (including nanomedicines) have limited their deep penetration into solid tumors. Herein we report the design of gold nanoparticles with virus-like spikes (AuNVs) to mimic viral shapes and facilitate tumor penetration. Mechanistic studies revealed that AuNVs mainly entered cells through macropinocytosis, then transported to the Golgi/endoplasmic reticulum system via Rab11-regulated pathway, and finally exocytosed through recycling endosomes, leading to high cellular uptake, effective transcytosis, and deep tumor penetration compared to gold nanospheres (AuNPs) and gold nanostars (AuNSs). The high tumor accumulation and deep tumor penetration of mitoxantrone (MTO) facilitated by AuNVs endowed effective chemophotothermal therapy when exposed to a near-infrared II laser, significantly reducing tumor sizes in a mouse model of colorectal cancer. This study reveals a potent mechanism of viral-like structures in tissue penetration and highlights their potential as effective drug delivery carriers.

Targeted delivery of oxaliplatin to colorectal cancer using the cancer-specific cell-penetrating peptide BR2

Oxaliplatin is one of the main drugs used in chemotherapy to treat advanced colorectal cancer (CRC), but its effectiveness is limited by its weak cellular uptake, and poor targeting to cancer cells, which can lead to drug resistance and adverse effects in patients. To address these issues, we tested a cell-penetrating, cancer-specific peptide called BR2 as a new peptide-drug conjugate. We conjugated oxaliplatin with BR2 covalently using a heterobifunctional linker. The resulting conjugate (BR2-Oxal) was examined for in vitro and in vivo effectiveness against human colon cancer cells and tumors. Compared with the parent drug, the in vitro investigations showed selective cellular uptake of BR2-Oxal in cancer cells rather than in normal cells and a significantly greater reduction in colon cancer cell viability due to a higher ratio of apoptosis. We also found that BR2-Oxal exhibited a higher accumulation in tumors and greater tumor suppression than oxaliplatin in a xenograft mouse model, suggesting that BR2-Oxal was efficiently and specifically delivered to tumors in vivo. These findings indicate that using the BR2 peptide for the intracellular delivery of oxaliplatin is a promising drug-delivery strategy. This approach also has the potential to enhance the efficiency of oxaliplatin prodrugs or derivatives.

Polypyrrole/iron-glycol chitosan nanozymes mediate M1 macrophages to enhance the X-ray-triggered photodynamic therapy for bladder cancer by promoting antitumor immunity

X-ray Photodynamic Therapy (XPDT) is an emerging, deeply penetrating, and non-invasive tumor treatment that stimulates robust antitumor immune responses. However, its efficacy is often limited by low therapeutic delivery and immunosuppressant within the tumor microenvironment. This challenge can potentially be addressed by utilizing X-ray responsive iron-glycol chitosan-polypyrrole nanozymes (GCS-I-PPy NZs), which activate M1 macrophages. These nanozymes increase tumor infiltration and enhance the macrophages' intrinsic immune response and their ability to stimulate adaptive immunity. Authors have designed biocompatible, photosensitizer-containing GCS-I-PPy NZs using oxidation/reduction reactions. These nanozymes were internalized by M1 macrophages to form RAW-GCS-I-PPy NZs. Authors' results demonstrated that these engineered macrophages effectively delivered the nanozymes with potentially high tumor accumulation. Within the tumor microenvironment, the accumulated GCS-I-PPy NZs underwent X-ray irradiation, generating reactive oxygen species (ROS). This ROS augmentation significantly enhanced the therapeutic effect of XPDT and synergistically promoted T cell infiltration into the tumor. These findings suggest that nano-engineered M1 macrophages can effectively boost the immune effects of XPDT, providing a promising strategy for enhancing cancer immunotherapy. The ability of GCS-I-PPy NZs to mediate M1 macrophage activation and increase tumor infiltration highlights their potential in overcoming the limitations of current XPDT approaches and improving therapeutic outcomes in melanoma and other cancers.

Tuning nanoparticle core composition drives orthogonal fluorescence amplification for enhanced tumour imaging

Tumour detection with high selectivity and sensitivity is crucial for delineating tumour margins and identifying metastatic foci during image-guided surgery. Optical nanoprobes with preferential tumour accumulation is often limited by inefficient amplification of biological signals. Here, we report the design of a library of hydrophobic core-tunable ultra-pH-sensitive nanoprobes (HUNPs) for orthogonally amplifying tumour microenvironmental signals on multiple tumour models. We find that tuning the hydrophobicity of nanoparticle core composition with non-ionizable monomers can enhance cellular association of HUNPs by more than ten-fold, resulting in a high cellular internalization efficiency of HUNPs with up to 50% in tumours. Combining high tumour accumulation and high cell internalization efficiency, HUNPs show orthogonally amplified fluorescence signals, permitting the precise locating and delineating margins between malignant lesions and normal tissues with high contrast-to-noise ratio and resolution. Our study provides key strategies to design nanomedicines with high intracellular bioavailability for cancer detection, drug/gene delivery, and therapy.

(SiFA)SeFe: A Hydrophilic Silicon-Based Fluoride Acceptor Enabling Versatile Peptidic Radiohybrid Tracers.

The radiohybrid (rh) concept to design targeted (and chemically identical) radiotracers for imaging or radionuclide therapy of tumors has gained momentum. For this strategy, a new bifunctional Silicon-based Fluoride Acceptor (SiFA) moiety (SiFA)SeFe was synthesized, endowed with improved hydrophilicity and high versatility of integration into rh-compounds. Preliminary radiolabeling and stability studies under different conditions were conducted using model bioconjugate peptides. Further, three somatostatin receptor 2 (sstR2)-targeted rh-compounds ((SiFA)SeFe-rhTATE1-3, TATE = (Tyr3)-octreotate) were developed. Compound (SiFA)SeFe-rhTATE3, enables labeling with 18F for PET imaging or chelation of 177Lu for therapy. The rh-compounds possess comparable receptor binding affinity and in vitro performance as good as the clinically proven gold standards. SstR2-specificity was further shown for (SiFA)SeFe-rhTATE2 using the chicken chorioallantoic membrane (CAM) model. The biodistribution of two compounds in mice showed high accumulation in tumors and excretion via the kidneys, demonstrating the clinical applicability of the (SiFA)SeFe moiety.

Oleanolic acid derivative self-assembled aggregates based on heparin and chitosan for breast cancer therapy

Oleanolic acid is an active ingredient from natural products with anti-breast cancer activity. However, the poor solubility in water and low bioavailability have limited its effectiveness in clinic. To improve the anticancer activity of oleanolic acid, we synthesized a novel oleanolic quaternary ammonium (QDT), which, driven by electrostatic interactions, was introduced into heparin and coated with chitosan to obtain a QDT/heparin/chitosan nanoaggregate (QDT/HEP/CS NAs). QDT/HEP/CS NAs showed the negative zeta potential (−35.01 ± 4.38 mV), suitable mean particle size (150.45 ± 0.68 nm) with strip shape, and high drug loading (36 %). The coated chitosan had strong anti-leakage characteristics toward QDT under physiological conditions. More importantly, upon sustained release in tumor cells, QDT could significantly decrease the mitochondrial membrane potential and induce apoptosis of breast cancer cells. Further in vivo antitumor study on 4 T1 tumor-bearing mice confirmed the enhanced anticancer efficacy of QDT/HEP/CS NAs via upregulation of caspase-3, caspase-9 and cytochrome C, which was attributed to the high accumulation in tumor via the enhanced permeability and retention effect. Moreover, QDT/HEP/CS NAs significantly enhanced the biosafety and biocompatibility of QDT in vitro and in vivo. Collectively, the development of QDT/HEP/CS NAs with high antitumor activity, favorable biodistribution and good biocompatibility provided a safe, facile and promising strategy to improve the anti-cancer effect of traditional Chinese medicine ingredients.

Blocking Metallothionein-2 Expression by Copper-Doped Carbon Dots Induces Cellular Antioxidant System Collapse for Antitumor Therapy.

The insufficient antioxidant reserves in tumor cells play a critical role in reactive oxygen species (ROS)-mediated therapeutics. Metallothionein-2 (MT-2), an intracellular cysteine-rich protein renowned for its potent antioxidant properties, is intricately involved in tumor development and correlates with a poor prognosis. Consequently, MT-2 emerges as a promising target for tumor therapy. Herein, we present the development of copper-doped carbon dots (Cu-CDs) to target MT-2 to compromise the delicate antioxidant reserves in tumor cells. These Cu-CDs with high tumor accumulation and prolonged body retention can effectively suppress tumor growth by inducing oxidative stress. Transcriptome sequencing unveils a significant decrease in MT-2 expression within the in vivo tumor samples. Further mechanical investigations demonstrate that the antitumor effect of Cu-CDs is intricately linked to apolipoprotein E (ApoE)-mediated downregulation of MT-2 expression and the collapse of the antioxidant system. The robust antitumor efficacy of Cu-CDs provides invaluable insights into developing MT-2-targeted nanomedicine for cancer therapies.

Structure-affinity-pharmacokinetics relationships of 111In-labeled PSMA-targeted ligands with different albumin binders

IntroductionProstate-specific membrane antigen (PSMA) is a promising target for treating metastatic castration-resistant prostate cancer. Our previous report presented 111In- or 225Ac-labeled PSMA-NAT-DA1 (PNT-DA1) as a PSMA-targeted ligand. To improve its therapeutic efficiency, PNT-DA1 contains 4-(p-iodophenyl)butyric acid (IPBA), which is known as an albumin binder (ALB) moiety. However, few reports have examined the relationship between the chemical modification of the ALB moiety and pharmacokinetics of PSMA-targeted radioligands. To assess this relationship, we designed, synthesized, and evaluated four [111In]In-PNT-DA1 analogues with ALB moieties different from IPBA. MethodsThe [111In]In-PNT-DA1 analogues were synthesized from their corresponding precursors through ligand substitution reaction. The stability of [111In]In-PNT-DA1 analogues in mouse plasma, their affinity for human serum albumin (HSA), their binding to mouse plasma proteins, and their affinity for PSMA were evaluated in vitro. The tissue distribution profile of the radioligands was assessed in biodistribution studies using LNCaP tumor-bearing nude mice. ResultsAll [111In]In-PNT-DA1 analogues were obtained at a high radiochemical yield and purity. These analogues were highly stable in mouse plasma after 24 h. The binding affinity for HSA significantly varied among the different ALB moieties. Moreover, high affinity for mouse plasma proteins was observed for all [111In]In-PNT-DA1 analogues compared with their counterparts without an ALB moiety. The affinity for PSMA was comparable for all radioligands. In the biodistribution assay, the pharmacokinetics of [111In]In-PNT-DA1 analogues varied markedly depending on the type of ALB moiety. In particular, tumor area under the curve (AUC) values were increased for radioligands with higher blood retention, while some previous studies reported that compounds with moderate blood retention exhibited the highest tumor AUC values. ConclusionThe introduction of an appropriate ALB moiety into the ligand may lead to the development of more useful PSMA-targeted radioligands with higher tumor accumulation.

Employing antagonistic C-X-C motif chemokine receptor 4 antagonistic peptide functionalized NaGdF4 nanodots for magnetic resonance imaging-guided biotherapy of breast cancer

C-X-C motif chemokine receptor 4 (CXCR4) is a promising therapeutic target of breast cancer because it is overexpressed on cell surface of all molecular subtypes of breast cancer including triplenegative breast cancer (TNBC). Herein, CXCR4 antagonistic peptide-NaGdF4 nanodot conjugates (termed as anti-CXCR4-NaGdF4 NDs) have been constructed for magnetic resonance imaging (MRI)-guided biotherapy of TNBC through conjugation of the C-X-C Motif Chemokine 12 (CXCL12)-derived cyclic peptide with tryptone coated NaGdF4 nanodots (5 ± 0.5 nm in diameter, termed as Try-NaGdF4 NDs). The as-prepared anti-CXCR4-NaGdF4 NDs exhibits high longitudinal relaxivity (r1) value (21.87 mM−1S−1), reasonable biocompatibility and good tumor accumulation ability. The features of anti-CXCR4-NaGdF4 NDs improve the tumor-MRI sensitivity and facilitate tumor biotherapy after injection in mouse-bearing MDA-MB-231 tumor model in vivo. MRI-guided biotherapy using anti-CXCR4-NaGdF4 NDs enables to suppress 46% tumor growth. In addition, about 47% injection dose of anti-CXCR4-NaGdF4 NDs is found in the mouse urine at 24 h post-injection. These findings demonstrate that anti-CXCR4-NaGdF4 NDs enable to be used as renal clearable nanomedicine for biotherapy and MRI of breast cancer.

Albumin incorporation into recognising layer of HER2-specific magnetic nanoparticles as a tool for optimal targeting of the acidic tumor microenvironment

Cancer is unquestionably a global healthcare challenge, spurring the exporation of novel treatment approaches. In recent years, nanomaterials have garnered significant interest with the greatest hopes for targeted nanoformulations due to their cell-specific delivery, improved therapeutic efficacy, and reduced systemic toxicity for the organism. The problem of successful clinical translation of nanoparticles may be related to the fact that most in vitro tests are performed at pH values of normal cells and tissues, ranging from 7.2 to 7.4. The extracellular pH values of tumors are characterized by a shift to a more acidic region in the range of 5.6–7.0 and represent a crucial target for enhancing nanoparticle delivery to cancer cells. Here we show the method of non-active protein incorporation into the surface of HER2-targeted nanoparticles to achieve optimal cellular uptake within the pH range of the tumor microenvironment. The method efficacy was confirmed in vitro and in vivo showing the maximum binding of nanoparticles to cells at a pH value 6.4. Namely, fluorescent magnetic nanoparticles, modified with HER2-recognising affibody ZHER2:342, with proven specificity in terms of HER2 recognition (with 62-fold higher cellular uptake compared to control nanoparticles) were designed for targeting cancer cells at slightly acidic pH values. The stabilizing protein, namely, bovine serum albumin, one of the major blood components with widespread availability and biocompatibility, was used for the decoration of the nanoparticle surface to alter the pH response of the targeting magnetic conjugates. The optimally designed nanoparticles showed a bell-shaped dependency of interaction with cancer cells in the pH range of 5.6–8.0 with maximum cellular uptake at pH value 6.4 close to that of the tumor microenvironment. In vivo experiments revealed that after i.v. administration, BSA-decorated nanoparticles exhibited 2 times higher accumulation in tumors compared to magnetic nanoparticles modified with affibody only. Thus, we demonstrated a valid method for enhancing the specificity of targeted nanoparticle delivery to cancer cells without changing the functional components of nanoparticles.

PH-Sensitive doxorubicin delivery using zinc oxide nanoparticles as a rectified theranostic platform: in vitro anti-proliferative, apoptotic, cell cycle arrest and in vivo radio-distribution studies.

Despite enormous advancements in its management, cancer is the world's primary cause of mortality. Therefore, tremendous strides were made to produce intelligent theranostics with mitigated side effects and improved specificity and efficiency. Thus, we developed a pH-sensitive theranostic platform composed of dextran immobilized zinc oxide nanoparticles, loaded with doxorubicin and radiolabeled with the technetium-99m radionuclide (99mTc-labelled DOX-loaded ZnO@dextran). The platform measured 11.5 nm in diameter with -12 mV zeta potential, 88% DOX loading efficiency and 98.5% radiolabeling efficiency. It showed DOX release in a pH-responsive manner, releasing 93.1% cumulatively at pH 5 but just 7% at pH 7.4. It showed improved intracellular uptake, which resulted in a high growth suppressive effect against MCF-7 cancer cells as compared to the free DOX. It boasted a 4 times lower IC50 than DOX, indicating its significant anti-proliferative potential (0.14 and 0.55 μg ml-1, respectively). The in vitro biological evaluation revealed that its molecular mode of anti-proliferative action included downregulating Cdk-2, which provoked G1/S cell cycle arrest, and upregulating both the intracellular ROS level and caspase-3, which induced apoptosis and necrosis. The in vivo experiments in Ehrlich-ascites carcinoma bearing mice demonstrated that DOX-loaded ZnO@dextran showed a considerable 4-fold increase in anti-tumor efficacy compared to DOX. Moreover, by utilizing the diagnostic radionuclide (99mTc), the radiolabeled platform (99mTc-labelled DOX-loaded ZnO@dextran) was in vivo monitored in tumor-bearing mice, revealing high tumor accumulation (14% ID g-1 at 1 h p.i.) and reduced uptake in non-target organs with a 17.5 T/NT ratio at 1 h p.i. Hence, 99mTc-labelled DOX-loaded ZnO@dextran could be recommended as a rectified tumor-targeted theranostic platform.

Manipulating the Crosstalk between Cancer and Immunosuppressive Cells with Phototherapeutic Gold-Nanohut for Reprogramming Tumor Microenvironment.

Photoimmunotherapy faces challenges due to insufficient intratumoral accumulation of photothermal agents and the reversion of the cancer-immunity cycle during treatment. In this study, an anti-PD-L1-immobilized magnetic gold nanohut, AuNH-2-Ab, with photoresponsive, thermosensitive, and immunomodulatory properties to effectively suppress the growth of primary tumors, elevate immunogenic cell death (ICD) levels, reverse the tumor immune microenvironment (TIME), and consequently inhibit metastases are developed. AuNH-2-Ab achieves high tumor accumulation (9.54% injected dose) following systemic administration, allowing the modulation of hyperthermia dose of over 50°C in the tumor. By optimizing the hyperthermia dose, AuNH-2-Ab simultaneously target and eliminate cancer cells and tumor-associated macrophages, thereby activating potent antitumor immunity without being compromised by immunosuppressive elements. Hyperthermia/pH induced morphological transformation of AuNH-2-Ab involving the detachment of the surface antibody for in situ PD-L1 inhibition, and exposure of the inner fucoidan layer for natural killer (NK) cell activation. This precision photoimmunotherapy approach reprograms the TIME, significantly prolongs survival in a murine hepatocellular carcinoma model (Hep55.1c), and harnesses the synergistic effects of ICD production and checkpoint inhibitors by utilizing a single nanoplatform.

In vivo stable 211At-labeled prostate-specific membrane antigen-targeted tracer using a neopentyl glycol structure

BackgroundProstate cancer is a common cancer among men worldwide that has a very poor prognosis, especially when it progresses to metastatic castration-resistant prostate cancer (mCRPC). Therefore, novel therapeutic agents for mCRPC are urgently required. Because prostate-specific membrane antigen (PSMA) is overexpressed in mCRPC, targeted alpha therapy (TAT) for PSMA is a promising treatment for mCRPC. Astatine-211 (211At) is a versatile α-emitting radionuclide that can be produced using a cyclotron. Therefore, 211At-labeled PSMA compounds could be useful for TAT; however, 211At-labeled compounds are unstable against deastatination in vivo. In this study, to develop in vivo stable 211At-labeled PSMA derivatives, we designed and synthesized 211At-labeled PSMA derivatives using a neopentyl glycol (NpG) structure that can stably retain 211At in vivo. We also evaluated their biodistribution in normal and tumor-bearing mice.ResultsWe designed and synthesized 211At-labeled PSMA derivatives containing two glutamic acid (Glu) linkers between the NpG structure and asymmetric urea (NpG-L-PSMA ((L-Glu)2 linker used) and NpG-D-PSMA ((D-Glu)2 linker used)). First, we evaluated the characteristics of 125I-labeled NpG derivatives because 125I was readily available. [125I]I-NpG-L-PSMA and [125I]I-NpG-D-PSMA showed low accumulation in the stomach and thyroid, indicating their high in vivo stability against deiodination. [125I]I-NpG-L-PSMA was excreted in urine as hydrophilic radiometabolites in addition to the intact form. Meanwhile, [125I]I-NpG-D-PSMA was excreted in urine in an intact form. In both cases, no radioactivity was observed in the free iodine fraction. [125I]I-NpG-D-PSMA showed higher tumor accumulation than [125I]I-NpG-L-PSMA. We then developed 211At-labeled PSMA using the NpG-D-PSMA structure. [211At]At-NpG-D-PSMA showed low accumulation in the stomach and thyroid in normal mice, indicating its high stability against deastatination in vivo. Moreover, [211At]At-NpG-D-PSMA showed high accumulation in tumor similar to that of [125I]I-NpG-D-PSMA.Conclusions[211At]At-NpG-D-PSMA showed high in vivo stability against deastatination and high tumor accumulation. [211At]At-NpG-D-PSMA should be considered as a potential new TAT for mCRPC.