Radionuclide molecular imaging of HER2 expression in disseminated cancer enables stratification of patients for HER2-targeted therapies. DARPin G3, a small (14 kDa) engineered scaffold protein, is a promising probe for imaging of HER2. We hypothesized that position (C-or N-terminus) and composition (hexahistidine or (HE) 3) of histidine-containing tags would influence the biodistribution of [ 99m Tc]Tc(CO) 3-labeled DARPin G3. To test the hypothesis, G3 variants containing tags at N-terminus (H 6-G3 and (HE) 3-G3) or at C-terminus (G3-H 6 and G3-(HE) 3) were labeled with [ 99m Tc]Tc(CO) 3. Labeling yield, label stability, specificity and affinity of the binding to HER2, biodistribution and tumor targeting properties of these variants were compared side-by-side. There was no substantial influence of position and composition of the tags on binding of [ 99m Tc]Tc(CO) 3-labeled variants to HER2. The specificity of HER2 targeting in vivo was confirmed. The tumor uptake in BALB/c nu/nu mice bearing SKOV3 xenografts was similar for all variants. On the opposite, there was a strong influence of the tags on uptake in normal tissues. the tumor-to-liver ratio for [ 99m Tc]Tc(CO) 3-(HE) 3-G3 was threefold higher compared to the hexahistidine-tag containing variants. overall, [ 99m Tc]Tc(CO) 3-(HE) 3-G3 variant provided the highest tumor-to-lung, tumor-to-liver, tumor-to-bone and tumor-to-muscle ratios, which should improve sensitivity of HER2 imaging in these common metastatic sites.
Radionuclide molecular imaging of human epidermal growth factor type 2 (HER2) expression may enable a non-invasive discrimination between HER2-positive and HER2-negative breast cancers for stratification of patients for HER2-targeted treatments. DARPin G3 is a small (molecular weigh 14 kDa) scaffold protein with picomolar affinity to HER2. The aim of this firstin-human study was to evaluate the safety, biodistribution and dosimetry of 99m Tc-(HE)3-G3.Methods. Three cohorts of patients with primary breast cancer (each including at least 4 patients with HER2-negative and 5 patients with HER2-positive tumors) were injected with either 1000, 2000 or 3000 µg of 99m Tc-(HE)3-G3 (287±170 MBq). Whole-body planar imaging followed by SPECT was performed at 2, 4, 6 and 24 h after injection. Vital signs and possible side effects were monitored during imaging and up to 7 days after injection.Results. All injections were well tolerated. No side effects were observed. The results of blood and urine analyses did not differ before and after studies. 99m Tc-(HE)3-G3 cleared rapidly from the blood. The highest uptake was detected in the kidneys and liver followed by the lungs, breasts and small intestinal content. The hepatic uptake after injecting with 2000 or 3000 µg was significantly (p<0.05) lower than the uptake after injecting with 1000 µg. Effective doses did not differ significantly between cohorts (average 0.011± 0.004 mSv/MBq). Tumor-to-contralateral site ratios for HER-positive tumors were significantly (p< 0.05) higher than for HER2-negative at 2 and 4 h after injection. Conclusions.Imaging of HER2 expression using 99m Tc-(HE)3-G3 is safe, well-tolerated and provides a low absorbed dose burden on patients. This imaging enables discerning HER2-positive and HER2-negative breast cancer. Phase I study data justifies further clinical development of 99m Tc-(HE)3-G3.
Radionuclide imaging of HER2 expression in tumours may enable stratification of patients with breast, ovarian, and gastroesophageal cancers for HER2-targeting therapies. A first-generation HER2-binding affibody molecule [99mTc]Tc-ZHER2:V2 demonstrated favorable imaging properties in preclinical studies. Thereafter, the affibody scaffold has been extensively modified, which increased its melting point, improved storage stability, and increased hydrophilicity of the surface. In this study, a second-generation affibody molecule (designated ZHER2:41071) with a new improved scaffold has been prepared and characterized. HER2-binding, biodistribution, and tumour-targeting properties of [99mTc]Tc-labelled ZHER2:41071 were investigated. These properties were compared with properties of the first-generation affibody molecules, [99mTc]Tc-ZHER2:V2 and [99mTc]Tc-ZHER2:2395. [99mTc]Tc-ZHER2:41071 bound specifically to HER2 expressing cells with an affinity of 58 ± 2 pM. The renal uptake for [99mTc]Tc-ZHER2:41071 and [99mTc]Tc-ZHER2:V2 was 25–30 fold lower when compared with [99mTc]Tc-ZHER2:2395. The uptake in tumour and kidney for [99mTc]Tc-ZHER2:41071 and [99mTc]Tc-ZHER2:V2 in SKOV-3 xenografts was similar. In conclusion, an extensive re-engineering of the scaffold did not compromise imaging properties of the affibody molecule labelled with 99mTc using a GGGC chelator. The new probe, [99mTc]Tc-ZHER2:41071 provided the best tumour-to-blood ratio compared to HER2-imaging probes for single photon emission computed tomography (SPECT) described in the literature so far. [99mTc]Tc-ZHER2:41071 is a promising candidate for further clinical translation studies.
The targeted delivery of radionuclides to tumours holds great promise for diagnosis and treatment of malignant neoplasms. The development of scaffold proteins has significantly simplified the design of targeting agents with desirable properties. This review comprehensively describes the key aspects of the design of radionuclide compounds, including classification of radionuclides, methodology for their attachment to targeting agents and characteristics of these agents that affect their behaviour in the body. Various targeting molecules are compared in terms of their ability to specifically find malignant foci in the body. The most recent achievements of cancer theranostics that aim at increasing the selectivity of antitumour effect are described, such as the fusion of targeting scaffold proteins with the albumin-binding domain and pretargeting. Special attention is paid to the creation of targeted radionanomaterials. Advantages and disadvantages of different strategies are analyzed and approaches for improving the delivery to tumours and for minimizing the undesirable impact on healthy organs and tissues are proposed. Particular emphasis is placed on the results of studies published in 2020–2021 that have not yet been covered by reviews. The bibliography includes 191 references.
“Electronic nose” technology, including technical and software tools to analyze gas mixtures, is promising regarding the diagnosis of malignant neoplasms. This paper presents the research results of breath samples analysis from 59 people, including patients with a confirmed diagnosis of respiratory tract cancer. The research was carried out using a gas analytical system including a sampling device with 14 metal oxide sensors and a computer for data analysis. After digitization and preprocessing, the data were analyzed by a neural network with perceptron architecture. As a result, the accuracy of determining oncological disease was 81.85%, the sensitivity was 90.73%, and the specificity was 61.39%.
Recent studies show that overexpression of a short version of the cation exchanger 1 gene (sCAX1) can cause Ca2+ deficiency symptoms in tomato (Solanum lycopersicum L.). However, the Ca2+ deficiency in relation to the overexpression of this gene has not been investigated in potato (Solanum tuberosum L.). The objective of our study was to investigate the production of known Ca2+ deficiency symptoms in potato in relation to the overexpression of sCAX1. Plantlets of S. tuberosum cultivar ‘Atlantic’ overexpressing the sCAX1 gene were produced using Agrobacterium tumefaciens. Transgenic plants grown with normal amounts of Ca2+ under in vitro or greenhouse conditions showed known Ca2+ deficiency symptoms in potato plants such as shoot tips damage and leaf margin necrosis, as well as tuber internal defects (hollow heart). Growing the transgenic plants with higher amounts of Ca2+ in the media or soil nutrient solution mitigated these symptoms. These results support the notion that both shoot tip necrosis and hollow heart are associated with Ca2+ deficiency. There was abundance of calcium oxalate (CaC2O4) crystals present only in the transgenic plants suggesting that these plants sequester Ca2+ in the form of CaC2O4 in the vacuoles of transgenic plants, reducing Ca2+ in the other pools. Since both shoot tip necrosis and hollow heart are known to be associated with poor cell wall health, our results suggest that CAX1 is a regulator of Ca2+ in the cell wall. In support of this concept, we found reduced cell wall biomass in the transgenic plants compared with the wild type.
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