Biodistribution Assay Research Articles

Development and Evaluation of a Novel Radiotracer 125I-rIL-27 to Monitor Allotransplant Rejection by Specifically Targeting IL-27Rα

Noninvasive monitoring of allograft rejection is beneficial for the prognosis of patients with organ transplantation. Recently, IL-27/IL-27R α was proved in close relation with inflammatory diseases, and 125I-anti-IL-27R α mAb our group developed demonstrated high accumulation in the rejection of the allograft. However, antibody imaging has limitations in the imaging background due to its large molecular weight. Therefore, we developed a novel radiotracer (iodine-125-labeled recombinant IL-27) to evaluate the advantage in the targeting and imaging of allograft rejection. In vitro specific binding of 125I-rIL-27 was determined by saturation and competitive assay. Blood clearance, biodistribution, phosphor autoradioimaging, and IL-27R α expression were studied on day 10 after transplantation (top period of allorejection). Our results indicated that 125I-rIL-27 could bind with IL-27R α specifically and selectively in vitro. The blood clearance assay demonstrated fast blood clearance with 13.20 μl/h of 125I-rIL-27 staying in the blood after 24 h. The whole-body phosphor autoradiography and biodistribution assay indicated a higher specific uptake of 125I-rIL-27 and a clear radioimage in allograft than in syngraft at 24 h, while a similar result was obtained at 48 h in the group of 125I-anti-IL-27R α mAb injection. Meanwhile, a higher expression of IL-27R α was found in the allograft by Western blot. The accumulation of radioactivity of 125I-rIL-27 was highly correlated with the expression of IL-27R α in the allograft. In conclusion, 125I-rIL-27 could be a promising probe for acutely monitoring allograft rejection with high specific binding towards IL-27R α on allograft and low imaging background.

Near-infrared-dye labeled tumor vascular-targeted dimer GEBP11 peptide for image-guided surgery in gastric cancer.

Positive resection margins occur in about 2.8%-8.2% gastric cancer surgeries and is associated with poor prognosis. Intraoperative guidance using Nearinfrared (NIR) fluorescence imaging is a promising technique for tumor detection and margin assessment. The goal of this study was to develop a tumor-specific probe for real-time intraoperative NIR fluorescence imaging guidance. The tumor vascular homing peptide specific for gastric cancer, GEBP11, was conjugated with a near-infrared fluorophore, Cy5.5. The binding specificity of the GEBP11 probes to tumor vascular endothelial cells were confirmed by immunofluorescent staining. The ability of the probe to detect tumor lesions was evaluated in two xenograft models. An orthotopic gastric cancer xenograft model was used to evaluate the efficacy of the GEBP11 NIR probes in real-time surgical guidance. In vitro assay suggested that both mono and dimeric GEBP11 NIR probes could bind specifically to tumor vascular epithelial cells, with dimeric peptides showed better affinity. In tumor xenograft mice, live imaging suggested that comparing with free Cy5.5 probe, significantly stronger NIR signals could be detected at the tumor site at 24-48h after injection of mono or dimeric GEBP11 probes. Dimeric GEBP11 probe showed prolonged and stronger NIR signals than mono GEBP11 probe. Biodistribution assay suggested that GEBP11 NIR probes were enriched in gastric cancer xenografts. Using dimeric GEBP11 NIR probes in real-time surgery, the tumor margins and peritoneal metastases could be clearly visualized. Histological examination confirmed the complete resection of the tumor. (GEBP11)2-ACP-Cy5.5 could be a potential useful probe for intraoperative florescence guidance in gastric cancer surgery.

X-Ray Triggered Nanoscintillators Photosensitize Pancreatic Cancer and Stimulate a Robust Systemic Immune Response

<h3>Purpose/Objective(s)</h3> X-ray excited photodynamic therapy (XPDT) utilizes X-ray excited nano-scintillators as a light source for photodynamic therapy to treat solid tumors in deep tissues and stimulate immunogenic tumor necrosis. The goals of our study were twofold: (1) to assess the efficacy of a novel XPDT agent, pYSM, in enhancing the regression of murine pancreatic tumors using low doses of radiation, and (2) to evaluate the immunogenic effects of XPDT and immunotherapy in stimulating a systemic anti-tumor immune response. <h3>Materials/Methods</h3> pYSM was synthesized by coating Y₂O₃:Eu nanoparticles in a mesoporous silica shell before loading the shell with methylene blue dye as a photosensitizer and encapsulating the complex in polyethylene glycol to improve systemic circulation. The generation of reactive oxygen species from irradiating pYSM in solution was measured by a singlet oxygen sensor green (SOSG) assay. In vitro studies were conducted using Panc02, a murine pancreatic cell line, by culturing cells with pYSM and measuring the cell viability after irradiation. In vivo studies were performed using C57BL/6 mice with subcutaneous bilateral flank injections of Panc02 cells. A biodistribution assay was performed to confirm that the intravenous tail-vein injection of pYSM resulted in the accumulation of the XPDT agent within the tumor microenvironment. Only right-sided tumors were treated with either XPDT+immunotherapy, XPDT only, radiotherapy only, or pYSM only, and left-sided tumors were left untreated. Tumor growth delay curves were measured for both treated and untreated tumors, and flow cytometry was performed on both tumors to measure the immune response in all treatment groups. <h3>Results</h3> XPDT mediated by pYSM resulted in the greater generation of reactive oxygen species generation under a 10 Gy dose when compared to controls. And in vitro studies confirmed the greater cytotoxic effects of pYSM under X-ray irradiation as compared to controls. Additionally, in vivo studies showed the enhanced tumor regression of pYSM-mediated XPDT+immunotherapy as compared to controls in both right-sided (treated) and left-sided (untreated) tumors, suggesting an abscopal effect, as well as an increase in immune responses within the microenvironment of both right-sided and left-sided tumors. <h3>Conclusion</h3> pYSM is a novel, viable construct capable of performing XPDT to treat solid tumors. Additionally, XPDT mediated by pYSM combined with immunotherapy can generate a systemic anti-tumor immune response that leads to the regression of treated tumors as well as an abscopal effect. This combined treatment modality can be used to treat deep-seated solid tumors with poor immunogenic profiles.

Novel serotonin decorated molecularly imprinted polymer nanoparticles based on biodegradable materials; A potential self-targeted delivery system for Irinotecan

Non-covalent imprinting polymerization was adopted to fabricate a novel molecularly imprinted polymer (MIP) for the targeted delivery of Irinotecan. The optimized condition to obtain a MIP with the highest binding efficiency was investigated by using different proportions of monomer to cross-linker. To overcome the drawbacks of conventional drug delivery systems, two main strategies in the preparation of the carrier were applied. Metformin as a non-hazardous material, with potential anti-cancer and targeted delivery properties, was used to fabricate the monomer. Moreover, the surface of the carrier was modified by serotonin (5-hydroxytryptamine). To improve the cellular uptake, prolong the circulation time, and to provide an appropriate accumulation of the drug at the tumor site, uniform, and nanoparticles were fabricated via mini-emulsion polymerization route. The structure of the prepared monomer was characterized using FTIR, 1HNMR, 13CNMR, and mass spectroscopy. The adsorption isotherm of the Irinotecan-MIP nanoparticles was investigated. Bio-distribution assay results revealed a suitable distribution of carrier nanoparticles in mice bodies. A controlled release profile with a maximum release of 83% in more acidic condition, was achieved for the designed formulation. According to all the above functions, it is believed that this study suggests a novel nano-carrier for the targeted delivery of Irinotecan.

Laser-assisted nanoparticle delivery to promote skin absorption and penetration depth of retinoic acid with the aim for treating photoaging

Retinoic acid (RA) is an approved treatment for skin photoaging induced by ultraviolet (UVA). Topically applied RA is mainly located in the stratum corneum (SC) with limited diffusion into the deeper strata. A delivery system capable of facilitating dermal delivery and cellular internalization for RA is critical for a successful photoaging therapy. Two delivery approaches, namely nanoparticles and laser ablation, were combined to improve RA’s absorption efficacy and safety. The nanoparticle absorption enhancement by the lasers was compared between full-ablative (Er:YAG) and fractional (CO2) modalities. We fabricated poly-L-lactic acid (PLA) and PLA/poly(lactic-co-glycolic acid) (PLGA) nanoparticles by an emulsion-solvent evaporation technique. The mean size of PLA and PLA/PLGA nanocarriers was 237 and 222 nm, respectively. The RA encapsulation percentage in both nanosystems was > 96 %. PLA and PLA/PLGA nanocarriers promoted RA skin deposition by 5- and 3-fold compared to free control. The ablative lasers further enhanced the skin deposition of RA-loaded nanoparticles, with the full-ablative laser showing greater permeation enhancement than the fractional mode. The skin biodistribution assay evaluated by confocal and fluorescence microscopies demonstrated that the laser-assisted nanoparticle delivery achieved a significant dermis and follicular accumulation. The cell-based study indicated a facile uptake of the nanoparticles into the human dermal fibroblasts. The nanoparticulate RA increased type I collagen and elastin production in the UVA-treated fibroblasts. A reduction of matrix metalloproteinase (MMP)-1 was also highlighted in the photoaging cells. The calculation of therapeutic index (TI) by multiplying collagen/elastin elevation percentage and skin deposition predicted better anti-photoaging performance in Er:YAG laser-assisted nanoparticle delivery than CO2 laser. Nanoencapsulation of RA decreased the cytotoxicity against skin fibroblasts. In vivo skin tolerance test on a nude mouse showed less skin damage after topical application of the nanoparticles than free RA. Our results hypothesized that the laser-mediated nanoparticle delivery provided an efficient and safe use for treating photoaging.

Application of the Chelator-Based Clickable Radiotheranostic Platform to Moderate-Molecular-Weight Ligands.

We have reported that the chelator-based clickable radiotheranostic platform, ADIBO-DOTADG-ALB (ADA), has favorable properties as a radiotheranostic platform for low-molecular-weight ligands. In this study, we evaluated the applicability of ADA to moderate-molecular-weight ligands to expand the utility of the ADA platform. As a moderate-molecular-weight ligand, we selected exendin-4, a peptide-based agonist to glucagon-like peptide-1 receptor (GLP-1R). An exendin-4-incorporated ADA derivative, exendin-4-Cys40-triazole-DOTADG-ALB (EtDA), was radiolabeled with 111In by the conjugation of exendin-4-Cys40 azide to [111In]In-ADA. The click ligation of exendin-4-Cys40 azide to [111In]In-ADA was quantitatively completed in 10 min under ambient conditions. In the in vitro cell-binding assay and albumin-binding assay, [111In]In-EtDA showed strong binding to both a GLP-1R-expressing cell and albumin. In the biodistribution assay, [111In]In-EtDA showed markedly protracted tumor uptake, which was significantly decreased by the coinjection of exendin-4-Cys40. The single photon emission computed tomography (SPECT) image of [111In]In-EtDA visualized the tumor clearly. These results indicated the utility of [111In]In-EtDA as a radiotheranostic agent, suggesting the applicability of the ADA platform to moderate-molecular-weight ligands.

Delivery of Small Molecules by Syndiotactic Peptides for Breast Cancer Therapy.

The utilization of peptide-based drug delivery systems has been suboptimal due to their poor proteolytic susceptibility, poor cell permeability, and limited tumor homing capabilities. Earlier attempts in using d-enantiomers in peptide sequences increased proteolytic stability but have compromised the overall penetration capability. We designed a series of peptides (STRAPs) with a syndiotactic polypeptide backbone that can potentially form a spatial array of cationic groups, an important feature that facilitates cellular uptake. The peptides penetrate cell membranes through a combination of active and passive modes. Furthermore, the cellular uptake of the peptides was unaffected by the presence of or treatment with bovine serum and human plasma. The designed peptides successfully delivered methotrexate, an anticancer drug, to the in vitro and in vivo models of breast cancer, with the best performing peptide STRAP-4-MTX conjugate having an EC50 value of 1.34 μM. Peptide drug delivery in mouse xenograft models showed a greater reduction of primary tumor and metastasis of breast cancer, in comparison to methotrexate of the same dose. The in vivo biodistribution assay of the STRAP-4 peptide suggests that the peptide accumulates at the tumor site after 2 h of treatment, and in the absence of tumors, the peptide gets metabolized and excreted from the system.

Mass Spectrometry-Based Method for the Determination of the Biodistribution of Tumor-Targeting Small Molecule-Metal Conjugates.

Nuclear medicine plays a key role in modern diagnosis and cancer therapy. The development of tumor-targeting radionuclide conjugates (also named small molecule-radio conjugates (SMRCs)) represents a significant improvement over the clinical use of metabolic radiotracers (e.g., [18F]-fluorodeoxyglucose) for imaging and over the application of biocidal external beam radiations for therapy. During the discovery of SMRCs, molecular candidates must be carefully evaluated typically by performing biodistribution assays in preclinical tumor models. Quantification methodologies based on radioactive counts are typically demanding due to safety concerns, availability of radioactive materials, and infrastructures. In this article, we report the development of a mass spectrometry (MS)-based method for the detection and quantification of small molecule-metal conjugates (SMMCs) as cold surrogates of SMRCs. We applied this methodology for the evaluation of the biodistribution of a particular class of tumor-targeting drug candidates based on natLu, natGa, and natF and directed against fibroblast activation protein (FAP). The reliability of the liquid chromatography-MS (LC-MS) analysis was validated by a direct comparison of MS-based and radioactivity-based biodistribution data. The results show that MS biodistribution of stable isotope metal conjugates is an orthogonal tool for the preclinical characterization of different classes of radiopharmaceuticals.

A Keratinocyte-Tethered Biologic Enables Location-Precise Treatment in Mouse Vitiligo

Despite the central role of IFN-γ in vitiligo pathogenesis, systemic IFN-γ neutralization is an impractical treatment option owing to strong immunosuppression. However, most patients with vitiligo present with <20% affected body surface area, which provides an opportunity for localized treatments that avoid systemic side effects. After identifying keratinocytes as key cells that amplify IFN-γ signaling during vitiligo, we hypothesized that tethering an IFN-γ‒neutralizing antibody to keratinocytes would limit anti‒IFN-γ effects on the treated skin for the localized treatment. To that end, we developed a bispecific antibody capable of blocking IFN-γ signaling while binding to desmoglein expressed by keratinocytes. We characterized the effect of the bispecific antibody invitro, exvivo, and in a mouse model of vitiligo. Single-photon emission computed tomography/computed tomography biodistribution and serum assays after local footpad injection revealed that the bispecific antibody had improved skin retention, faster elimination from the blood, and less systemic IFN-γ inhibition than the nontethered version. Furthermore, the bispecific antibody conferred localized protection almost exclusively to the treated footpad during vitiligo, which was not possible by local injection of the nontethered anti‒IFN-γ antibody. Thus, keratinocyte tethering proved effective while significantly diminishing the off-tissue effects of IFN-γ blockade, offering a safer treatment strategy for localized skin diseases, including vitiligo.

Structure-Activity Relationships and Pharmacokinetics of 111In-Labeled Glucagon-like Peptide-1 Receptor-Targeting Exendin-4 Derivatives Conjugated with Albumin Binder Moieties.

Insulinomas are neuroendocrine tumors that are derived from pancreatic β-cells, and they often overexpress the glucagon-like peptide-1 receptor (GLP-1R). Radiolabeled exendin-4 derivatives have been used to noninvasively detect the GLP-1R during the diagnosis and preoperative localization of insulinomas; however, their marked renal accumulation can hinder the imaging of pancreatic tail lesions. In this study, we designed and synthesized 111In-labeled exendin-4 derivatives that possessed 4-(4-substituted phenyl)-moieties as albumin binder (ALB) moieties ([111In]In-E4DA2-4), and studied their structure-activity relationships and pharmacokinetics (as well as those of [111In]In-E4DA1, which we previously reported) to determine their usefulness as radioligands for GLP-1R imaging. 111In-labeling was performed by reacting maleimide precursors with [111In]InCl3 in 2-(N-morpholino)ethanesulfonic acid buffer, and then, the products were conjugated with exendin-4-Cys40. A saturation binding assay using GLP-1R-expressing INS-1 cells was carried out to evaluate the in vitro affinity of the radioligands for the cells. In addition, the affinity of the 111In-labeled derivatives for human serum albumin (HSA) was evaluated in an HSA-binding assay. Furthermore, an in vivo biodistribution study and single-photon emission computed tomography (SPECT) imaging were performed using INS-1 tumor-bearing mice. [111In]In-E4DA1-4 were prepared at radiochemical yields of 6-17%. In the saturation binding assay, [111In]In-E4DA1-4 showed a similar affinity for the INS-1 cells, indicating that the kind of ALB moiety used had no effect on the affinity of the exendin-4 derivatives for the cells. In the HSA-binding assay, [111In]In-E4DA1-4 all bound to HSA. In the biodistribution assay, [111In]In-E4DA1-4 exhibited marked tumor accumulation and retention. In addition, they showed lower renal accumulation than previously reported exendin-4-based radioligands without ALB moieties. The pharmacokinetics of the 111In-labeled exendin-4 derivatives varied markedly according to the kind of ALB moiety used. In particular, [111In]In-E4DA2, which contained a 4-(4-bromophenyl)butyric acid derivative as an ALB moiety, showed the highest tumor accumulation. SPECT imaging with [111In]In-E4DA2 clearly visualized INS-1 tumors with no marked accumulation in normal organs. These results provide important information that will aid the design of novel exendin-4-based radioligands targeting the GLP-1R.

Synthesis and Evaluation of Novel 111In-Labeled Picolinic Acid-Based Radioligands Containing an Albumin Binder for Development of a Radiotheranostic Platform.

Picolinic acid-based metallic chelators, e.g., neunpa and octapa, have attracted much attention as promising scaffolds for radiotheranostic agents, particularly those containing larger α-emitting radiometals. Furthermore, albumin binder (ALB) moieties, which noncovalently bind to albumin, have been utilized to improve the pharmacokinetics of radioligands targeting various biomolecules. In this study, we designed and synthesized novel neunpa and octapa derivatives (Neunpa-2 and Octapa-2, respectively), which contained a prostate-specific membrane antigen (PSMA)-binding moiety (model targeting vector) and an ALB moiety. We evaluated the fundamental properties of these derivatives as radiotheranostic agents using 111In. In a cell-binding assay using LNCaP (PSMA-positive) cells, [111In]In-Neunpa-2 and [111In]In-Octapa-2 specifically bound to the LNCaP cells. In addition, a human serum albumin (HSA)-binding assay revealed that [111In]In-Neunpa-2 and [111In]In-Octapa-2 exhibited greater binding to HSA than their non-ALB-conjugated counterparts ([111In]In-Neunpa-1 and [111In]In-Octapa-1, respectively). A biodistribution assay conducted in LNCaP tumor-bearing mice showed that the introduction of the ALB moiety into the 111In-labeled neunpa and octapa derivatives resulted in markedly enhanced tumor uptake and retention of the radioligands. Furthermore, single-photon emission computed tomography imaging of LNCaP tumor-bearing mice with [111In]In-Octapa-2 produced tumor images. These results indicate that [111In]In-Octapa-2 may be a useful PSMA imaging probe and that picolinic acid-based ALB-conjugated radiometallic complexes may be promising candidates as radiotheranostic agents.

Assessment of endothelial colony forming cells delivery routes in a murine model of critical limb threatening ischemia using an optimized cell tracking approach

BackgroundEndothelial colony forming cells (ECFCs), alone or in combination with mesenchymal stem cells, have been selected as potential therapeutic candidates for critical limb-threatening ischemia (CLTI), mainly for those patients considered as “no-option,” due to their capability to enhance revascularization and perfusion recovery of ischemic tissues. Nevertheless, prior to translating cell therapy to the clinic, biodistribution assays are required by regulatory guidelines to ensure biosafety as well as to discard undesired systemic translocations. Different approaches, from imaging technologies to qPCR-based methods, are currently applied.MethodsIn the current study, we have optimized a cell-tracking assay based on DiR fluorescent cell labeling and near-infrared detection for in vivo and ex vivo assays. Briefly, an improved protocol for DiR staining was set up, by incubation of ECFCs with 6.67 µM DiR and intensive washing steps prior cell administration. The minimal signal detected for the residual DiR, remaining after these washes, was considered as a baseline signal to estimate cell amounts correlated to the DiR intensity values registered in vivo. Besides, several assays were also performed to determine any potential effect of DiR over ECFCs functionality. Furthermore, the optimized protocol was applied in combination with qPCR amplification of specific human Alu sequences to assess the final distribution of ECFCs after intramuscular or intravenous administration to a murine model of CLTI.ResultsThe optimized DiR labeling protocol indicated that ECFCs administered intramuscularly remained mainly within the hind limb muscle while cells injected intravenously were found in the spleen, liver and lungs.ConclusionOverall, the combination of DiR labeling and qPCR analysis in biodistribution assays constitutes a highly sensitive approach to systemically track cells in vivo. Thereby, human ECFCs administered intramuscularly to CLTI mice remained locally within the ischemic tissues, while intravenously injected cells were found in several organs. Our data corroborate the need to perform biodistribution assays in order to define specific parameters such as the optimal delivery route for ECFCs before their application into the clinic.

Abstract 311: Development of cludin-3 specific human monoclonal antibody(ABN501) as therapeutic anti-tumor agents

Abstract The tight junctions of epithelial tissues, that most malignant tumors are derived from, are associated in cell-cell interactions. Among the tight junction proteins, claudin-3 (CLDN3) is overexpressed in many types of solid cancers, such as breast, ovarian, colorectal, and gastric cancers. Although CLDN3 can be potential therapeutic target due to the overexpression in various types of cancers, high homology with other CLDN family members is a hurdle to develop antibodies specifically targeting CLDN3. In this study, human IgG1 monoclonal antibody (ABN501) against CLDN3 was developed by scFv phage display using CLDN3-overexpressing stable cells and CLDN3-embedded lipoparticles as antigens. It was confirmed that ABN501 specifically bound to human and mouse CLDN3 without cross-reactivity to other CLDN family members. Sub-nanomolar affinity in binding kinetics of ABN501 was measured in CLDN3 expressing cell lines. We observed the antibody-dependent cytotoxicity (ADCC) activity of ABN501 with human NK cells expressing CD16a (NK-92MI-CD16a), in various cancer cell lines according to CLDN3 expression levels. We also confirmed that ABN501 specifically targeted CLDN3-expressing tumors in biodistribution assay using fluorescence-conjugated ABN501. In addition, ABN501 showed anti-tumor effects when treated with NK-92MI-CD16a in xenograft mice bearing CLDN3 expressing tumors. Taken these results together, we suggest that ABN501, specifically recognizing to CLDN3, can be used as therapeutic agents for CLDN3 positive cancer, and developed in many different forms to treat cancers with its specificity for cancer diagnosis, antibody-drug conjugates, and chimeric antigen receptor (CAR) immunotherapy. Citation Format: Hong-Seok Choi, Euni Sim, Na Young Kim, Yong Jin Lee, Sae Hyung Lee, Hayeon Park, Hobin Yang, Jiwon Jo, Myeung-Ryun Seo, Heegeon Park, Ji-Hye Lee, Sungyoul Hong, Young Kee Shin, Jun-Young Choi. Development of cludin-3 specific human monoclonal antibody(ABN501) as therapeutic anti-tumor agents [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 311.

In vivo nanotracer for the detection of brain thrombi in an AD mouse model.

Background: Alzheimer’s disease (AD) is the most common cause of dementia. It is a multifactorial degenerative disease pathologically characterized by intracellular neurofibrillary tangles and extracellular deposition of amyloid. An early hemostatic dysregulation is also present and contributes to an increment in clot formation, leading to hypoperfusion, blood brain barrier disruption and neuronal loss. The detection of this prothrombotic state is of the upmost importance in diagnostic approaches to identify AD patients who would benefit from anticoagulation. Method: The aim of this project is to use an in vivo nanotracer for the detection of brain thrombi in an AD mouse model by fast pre-targeted positron emission tomography (PET) imaging. For that purpose, AD animals and their wild-type littermates were intravenously injected with the antiplatelet antibody against CD41 conjugated with transcyclooctene (TCO-antiCD41). Twenty-four hours later, [68Ga]core-doped iron oxide nanoparticles (NP) functionalized with tetrazine (TZ) were intravenously administered. TCO and TZ produce a rapid in vivo reaction by means of bioorthogonal chemistry, allowing to non-invasively evaluate platelets’ levels by PET. Two hours after [68Ga]NP-TZ injection, a static PET study of each mouse was acquired with a scanner for small animals (nanoScan® PET/CT, Mediso, USA). Finally, biodistribution assays of different organs after the PET study were performed. All PET images were analyzed by regions of interest and voxel-wise analyses. Conclusions: Our results provide a neuroimaging strategy to diagnose the prothrombotic state towards the personalization of anticoagulation treatment in AD patients.

Biodistribution of 99mTc-PLA/PVA/Atezolizumab nanoparticles for non-small cell lung cancer diagnosis

Lung cancer (LC) is a common type of cancer, which is a leading cause of death around the world. There is an urgency for the development of new drugs that could diagnose the LC in the early stages and in a precise manner. In this direction, the development of nanoparticles radiolabeled with the diagnostic radioisotopes represent an important advance in the field of cancer imaging. In this study were developed PLA/PVA/Atezolizumab nanoparticles which were radiolabeled with 99mTc (Technetium-99m). The radiolabeled nanoparticles were evaluated in both: in-vitro (L-929 and A-549) as in-vivo (mice). The results showed no cytotoxicity effect in the healthy cells (L-929) and cytotoxicity effect in the tumor cells (A-549). The biodistribution assay demonstrated that 99mTc-PLA/PVA/Atezolizumab could reach the tumor site 14-folds higher than the nonparticulate atezolizumab. In conclusion, 99mTc-PLA/PVA/Atezolizumab nanoparticles showed to be a new drug which is able to precisely image the lung tumor, and it must be considered for clinical trials.

Inhalable Mannosylated Rifampicin-Curcumin Co-Loaded Nanomicelles with Enhanced In Vitro Antimicrobial Efficacy for an Optimized Pulmonary Tuberculosis Therapy.

Among respiratory infections, tuberculosis was the second deadliest infectious disease in 2020 behind COVID-19. Inhalable nanocarriers offer the possibility of actively targeting anti-tuberculosis drugs to the lungs, especially to alveolar macrophages (cellular reservoirs of the Mycobacterium tuberculosis). Our strategy was based on the development of a mannose-decorated micellar nanoformulation based in Soluplus® to co-encapsulate rifampicin and curcumin. The former is one of the most effective anti-tuberculosis first-line drugs, while curcumin has demonstrated potential anti-mycobacterial properties. Mannose-coated rifampicin (10 mg/mL)–curcumin (5 mg/mL)-loaded polymeric micelles (10% w/v) demonstrated excellent colloidal properties with micellar size ~108 ± 1 nm after freeze-drying, and they remain stable under dilution in simulated interstitial lung fluid. Drug-loaded polymeric micelles were suitable for drug delivery to the deep lung with lung accumulation, according to the in vitro nebulization studies and the in vivo biodistribution assays of radiolabeled (99mTc) polymeric micelles, respectively. Hence, the nanoformulation did not exhibit hemolytic potential. Interestingly, the addition of mannose significantly improved (5.2-fold) the microbicidal efficacy against Mycobacterium tuberculosis H37Rv of the drug-co-loaded systems in comparison with their counterpart mannose-free polymeric micelles. Thus, this novel inhaled nanoformulation has demonstrated its potential for active drug delivery in pulmonary tuberculosis therapy.

SPECT imaging properties of the CdTe-Timepix3 detector used in a new prototype FullSPECT 3D multimodal preclinical imaging system: Comparison with scintillation gamma camera

Small animal SPECT imaging represents a fast-evolving method for a noninvasive molecular imaging of metabolism, diseases, or malfunctions in live animal models. Preclinical imaging is important for translational research related to development and testing of new tracers, diagnostic and therapeutic methods for clinical application, and helps also in basic biological research. The small animal imaging requires better spatial resolution compared to human imaging. The improvement on the detector side should be implemented because the currently used scintillation gamma cameras are now touching their limits. The main goal of this work aims on introduction of a new concept of our prototype system (FullSPECT 3D) and comparison of the performance of its hybrid semiconductor Timepix3 based detector, and standard scintillation gamma camera in a commercially available device (Albira Preclinical Imaging System) for SPECT imaging on phantom and animal model. We compared both detector types on widely used 99mTc-HDP (for bone scan), and 125I labeled antibody biodistribution assays. The images taken with a single Timepix3 based detector were comparable and in some parameters exceeded standard detectors under similar geometry in 2D projections. The differences in 3D reconstructed images were not calculated because of the huge difference in the reconstruction algorithms, nevertheless the 3D images are shown as well. The future SPECT systems could benefit from the speed, energy resolution and size of Timepix3 based detectors and open the way to construction of very fast multimodal imagers requiring less ionizing radiation delivered to the patient.

Development of an 111In-Labeled Glucagon-Like Peptide-1 Receptor-Targeting Exendin-4 Derivative that Exhibits Reduced Renal Uptake.

Insulinomas are neuroendocrine tumors that are mainly found in the pancreas. Surgical resection is currently the first-line treatment for insulinomas; thus, it is vital to preoperatively determine their locations. The marked expression of the glucagon-like peptide-1 receptor (GLP-1R) is seen in pancreatic β-cells and almost all insulinomas. Radiolabeled derivatives of exendin-4, a GLP-1R agonist, have been used with nuclear medicine imaging techniques for the in vivo detection of the GLP-1R; however, their marked renal accumulation can hinder the imaging of pancreatic tail lesions. To develop a GLP-1R imaging probe that exhibits reduced renal accumulation, we designed and synthesized a straight-chain GLP-1R-targeting radioligand, [111In]In-E4DA1, which consisted of exendin-4, DOTADG (a chelator), and an (iodophenyl)butyric acid derivative (an albumin binder [ALB]). We performed preclinical evaluations of [111In]In-E4DA1 to investigate its utility as a GLP-1R imaging probe. [111In]In-E4DA1 and [111In]In-E4D (a control compound lacking the ALB moiety) were prepared by reacting the corresponding precursors with [111In]InCl3 in buffer. Cell-binding and human serum albumin (HSA)-binding assays were performed to assess the in vitro affinity of the molecules for INS-1 (GLP-1R-positive) cells and albumin, respectively. A biodistribution assay and single-photon emission computed tomography imaging were carried out using INS-1 tumor-bearing mice. In the cell-binding assay, [111In]In-E4DA1 and [111In]In-E4D exhibited in vitro binding to INS-1 cells. In the HSA-binding assay, [111In]In-E4DA1 bound to HSA, while [111In]In-E4D showed little HSA binding. The in vivo experiments involving INS-1 tumor-bearing mice revealed that the introduction of an ALB moiety into the DOTADG-based exendin-4 derivative markedly increased the molecule's tumor accumulation while decreasing its renal accumulation. In addition, [111In]In-E4DA1 exhibited greater tumor accumulation than renal accumulation, whereas previously reported radiolabeled exendin-4 derivatives demonstrated much higher accumulation in the kidneys than in tumors. These results indicate that [111In]In-E4DA1 may be a useful GLP-1R imaging probe, as it demonstrates only slight renal accumulation.

Evaluation of poly (lactic-co-glycolic acid) nanoparticles to improve the therapeutic efficacy of paclitaxel in breast cancer.

Introduction: Paclitaxel (PTX) is a cornerstone in the treatment of breast cancer, the most common type of cancer in women. However, this drug has serious limitations, including lack of tissue-specificity, poor water solubility, and the development of drug resistance. The transport of PTX in a polymeric nanoformulation could overcome these limitations. Methods: In this study, PLGA-PTX nanoparticles (NPs) were assayed in breast cancer cell lines, breast cancer stem cells (CSCs) and multicellular tumor spheroids (MTSs) analyzing cell cycle, cell uptake (Nile Red-NR-) and α-tubulin expression. In addition, PLGA-PTX NPs were tested in vivo using C57BL/6 mice, including a biodistribution assay. Results: PTX-PLGA NPs induced a significant decrease in the PTX IC50 of cancer cell lines (1.31 and 3.03-fold reduction in MDA-MB-231 and E0771 cells, respectively) and CSCs. In addition, MTSs treated with PTX-PLGA exhibited a more disorganized surface and significantly higher cell death rates compared to free PTX (27.9% and 16.3% less in MTSs from MCF-7 and E0771, respectively). PTX-PLGA nanoformulation preserved PTX's mechanism of action and increased its cell internalization. Interestingly, PTX-PLGA NPs not only reduced the tumor volume of treated mice but also increased the antineoplastic drug accumulation in their lungs, liver, and spleen. In addition, mice treated with PTX-loaded NPs showed blood parameters similar to the control mice, in contrast with free PTX. Conclusion: These results suggest that our PTX-PLGA NPs could be a suitable strategy for breast cancer therapy, improving antitumor drug efficiency and reducing systemic toxicity without altering its mechanism of action.

Noninvasive Evaluation of EGFR Expression of Digestive Tumors Using 99mTc-MAG3-Cet-F(ab')2-Based SPECT/CT Imaging.

Purpose This study is aimed at investigating the feasibility of cetuximab (Cet) F(ab′)2 fragment- (Cet-F(ab′)2-) based single photon emission tomography/computed tomography (SPECT/CT) for assessing the epidermal growth factor receptor (EGFR) expression in digestive tumor mouse models. Methods Cet-F(ab′)2 was synthesized using immunoglobulin G-degrading enzyme of Streptococcus pyogenes (IdeS) protease and purified with protein A beads. The product and its in vitro stability in normal saline and 1% bovine serum albumin were analyzed with sodium dodecyl sulfate–polyacrylamide gel electrophoresis. The EGFR expression in the human colon tumor cell line HT29 and the human stomach tumor cell line MGC803 were verified using western blotting and immunocytochemistry. Cet-F(ab′)2 was conjugated with 5(6)-carboxytetramethylrhodamine succinimidyl ester to demonstrate its binding ability to the MGC803 and HT29 cells. Cet-F(ab′)2 was conjugated with NHS-MAG3 for 99mTc radiolabeling. The best imaging time was determined using a biodistribution assay at 1, 4, 16, and 24 h after injection of the 99mTc-MAG3-Cet-F(ab′)2 tracer. Furthermore, 99mTc-MAG3-Cet-F(ab′)2 SPECT/CT was performed on MGC803 and HT29 tumor-bearing nude mice. Results HT29 cells had low EGFR expression while MGC803 cell exhibited the high EGFR expression. Cet-F(ab′)2 and intact cetuximab showed similar high binding ability to MGC803 cells but not to HT29 cells. Cet-F(ab′)2 and 99mTc-MAG3-Cet-F(ab′)2 showed excellent in vitro stability. The biodistribution assay showed that the target to nontarget ratio was the highest at 16 h (17.29 ± 5.72, n = 4) after tracer injection. The 99mTc-MAG3-Cet-F(ab′)2-based SPECT/CT imaging revealed rapid and sustained tracer uptake in MGC803 tumors rather than in HT29 tumors with high image contrast, which was consistent with the results in vitro. Conclusion SPECT/CT imaging using 99mTc-MAG3-Cet-F(ab′)2 enables the evaluation of the EGFR expression in murine EGFR-positive tumors, indicating the potential utility for noninvasive evaluation of the EGFR expression in tumors.