3D-printed electrochemical sensors: A new horizon for measurement of biomolecules

Electrochemical sensors are widely used to monitor biomolecules. However, limitations in sensor geometry have restricted the scope of currently used electrochemical sensors. 3D-printing has emerged as a promising manufacturing approach, to robustly make electrochemical sensors, that can stably measure in biological environments. This review highlights the recent trends in the development of 3D-printed electrodes and biosensors for measurement of biomolecules. Novel geometries of 3D-printed electrodes have provided the means to conduct ex vivo measurement in the intestinal tract and in vivo measurements in the brain. 3D-printing is providing the ability to manufacture electrochemical sensors that can measure biomolecules in diverse areas of the body.     

Alterations of the exo- and endometabolite profiles in breast cancer cell lines: A mass spectrometry-based metabolomics approach

In recent years, knowledge about metabolite changes which are characteristic for the physiologic state of cancer cells has been acquired by liquid chromatography coupled to mass spectrometry. Distinct molecularly characterized breast cancer cell lines provide an unbiased and standardized in vitro tumor model reflecting the heterogeneity of the disease. Tandem mass spectrometry is a widely applied analytical platform and highly sensitive technique for analysis of complex biological samples. Endo- and exometabolite analysis of the breast cancer cell lines MDA-MB-231, -453 and BT-474 as well as the breast epithelial cell line MCF-10A has been performed using two different analytical platforms: UPLC-ESI-Q-TOF based on a scheduled precursor list has been applied for highlighting of significant differences between cell lines and HPLC-ESI-QqQ using multiple reaction monitoring has been utilized for a targeted approach focusing on RNA metabolism and interconnected pathways, respectively. Statistical analysis enabled a clear discrimination of the breast epithelial from the breast cancer cell lines. As an effect of oxidative stress, a decreased GSH/GSSG ratio has been detected in breast cancer cell lines. The triple negative breast cancer cell line MDA-MB-231 showed an elevation in nicotinamide, 1-ribosyl-nicotinamide and NAD+ reflecting the increased energy demand in triple negative breast cancer, which has a more aggressive clinical course than other forms of breast cancer. Obtained distinct metabolite pattern could be correlated with distinct molecular characteristics of breast cancer cells. Results and methodology of this preliminary in vitro study could be transferred to in vivo studies with breast cancer patients.     

Direct Detection of Circulating Tumor Cells in Whole Blood Using Time‐Resolved Luminescent Lanthanide Nanoprobes

The detection of circulating tumor cells (CTCs) is crucial to early cancer diagnosis and the evaluation of cancer metastasis. However, it remains challenging due to the scarcity of CTCs in the blood. Herein, we report an ultrasensitive platform for the direct detection of CTCs using luminescent lanthanide nanoprobes. These were designed to recognize the epithelial cell adhesion molecules on cancer cells, allowing signal amplification through dissolution‐enhanced time‐resolved photoluminescence (TRPL) and the elimination of short‐lived autofluorescence interference. This enabled the direct detection of blood breast‐cancer cells with a limit of detection down to 1 cell/well of a 96‐well plate. Moreover, blood CTCs (≥10 cells mL^?1) can be detected in cancer patients with a detection rate of 93.9 % (14/15 patients). We envision that this ultrasensitive detection platform with excellent practicality may provide an effective strategy for early cancer diagnosis and prognosis evaluation.     

Crosstalk events in the estrogen signaling pathway may affect tamoxifen efficacy in breast cancer molecular subtypes

Steroid hormones are involved on cell growth, development and differentiation. Such effects are often mediated by steroid receptors. One paradigmatic example of this coupling is the estrogen signaling pathway. Its dysregulation is involved in most tumors of the mammary gland. It is thus an important pharmacological target in breast cancer. This pathway, however, crosstalks with several other molecular pathways, a fact that may have consequences for the effectiveness of hormone modulating drug therapies, such as tamoxifen. For this work, we performed a systematic analysis of the major routes involved in crosstalk phenomena with the estrogen pathway – based on gene expression experiments (819 samples) and pathway analysis (493 samples) – for biopsy-captured tissue and contrasted in two independent datasets with in vivo and in vitro pharmacological stimulation. Our results confirm the presence of a number of crosstalk events across the estrogen signaling pathway with others that are dysregulated in different molecular subtypes of breast cancer. These may be involved in proliferation, invasiveness and apoptosis-evasion in patients. The results presented may open the way to new designs of adjuvant and neoadjuvant therapies for breast cancer treatment.     

Photo-responsive NIR-II biomimetic nanomedicine for efficient cancer-targeted theranostics

In pancreatic cancer, the special barrier system formed by a large number of stromal cells severely hinders drug penetration in deep tumor tissues, resulting in low treatment efficiency. Cell membrane protein-camouflaged liposomal nanomedicines have cancer cell targeting abilities, whereas near-infrared two-zone (NIR-II) fluorescence imaging can achieve deep tissue penetration due to its long light wavelength (1,000–1,700 nm). To combine the cell membrane-based biomimetic technology with NIR-II fluorescence imaging, we constructed a biomimetic nanomedicine (BLIPO-I/D) by camouflaging indocyanine green-doxorubicin (ICG-DOX) liposomes with SW1990 pancreatic cancer cell membrane. The nanomedicine exhibited light-controlled DOX release and high pancreatic cancer treatment efficiency in vitro and in vivo. BLIPO-I/D showed the ability of targeted delivery of a large number of liposomes to pancreatic tumor tissues through homologous targeting of SW1990 cell membranes, which increased the NIR-II fluorescence imaging intensity. Irradiation of the liposomes taken up by pancreatic tumor tissues with near-infrared light (808 nm) triggered the rapid release of DOX from the liposomes, induced the photothermal and photodynamic effects of ICG, which exerted anti-tumor effects. Therefore, the fabricated biomimetic liposomal nanomedicine BLIPO-I/D is expected to achieve precise theranostics of pancreatic cancer.     

Quantitation of a PEGylated protein in monkey serum by UHPLC-HRMS using a surrogate disulfide-containing peptide: A new approach to bioanalysis and in vivo stability evaluation of disulfide-rich protein therapeutics

To quantify a therapeutic PEGylated protein in monkey serum as well as to monitor its potential in vivo instability and methionine oxidation, a novel ultra high performance liquid chromatography-high resolution mass spectrometric (UHPLC-HRMS) assay was developed using a surrogate disulfide-containing peptide, DCP(SS), and a confirmatory peptide, CP, a disulfide-free peptide. DCP(SS) was obtained by eliminating the step of reduction/alkylation before trypsin digestion. It contains an intact disulfide linkage between two peptide sequences that are essential for drug function but susceptible to potential in vivo cleavages. HRMS-based single ion monitoring (SIM) on a Q Exactive™ mass spectrometer was employed to improve assay specificity and sensitivity for DCP(SS) due to its poor fragmentation and low sensitivity with SRM detection. The assay has been validated for the protein drug in monkey serum using both surrogate peptides with excellent accuracy (within ±4.4%Dev) and precision (within 7.5%CV) with a lower limit of quantitation (LLOQ) at 10 ng mL⁻¹. The protein concentrations in monkey serum obtained from the DCP(SS)-based assay not only provided important pharmacokinetic parameters, but also confirmed in vivo stability of the peptide regions of interest by comparing drug concentrations with those obtained from the CP-based assay or from a ligand-binding assay (LBA). Furthermore, UHPLC-HRMS allowed simultaneous monitoring of the oxidized forms of both surrogate peptides to evaluate potential ex vivo/in vivo oxidation of one methionine present in each of both surrogate peptides. To the best of our knowledge, this is the first report of using a surrogate disulfide-containing peptide for LC-MS bioanalysis of a therapeutic protein.     

Bioorthogonal oxime ligation mediated in vivo cancer targeting

Current cancer targeting relying on specific biological interaction between the cell surface antigen and respective antibody or its analogue has proven to be effective in the treatment of different cancers; however, this strategy has its own limitations, such as the heterogeneity of cancer cells and immunogenicity of the biomacromolecule binding ligands. Bioorthogonal chemical conjugation has emerged as an attractive alternative to biological interaction for in vivo cancer targeting. Here, we report an in vivo cancer targeting strategy mediated by bioorthogonal oxime ligation. An oxyamine group, the artificial target, is introduced onto 4T1 murine breast cancer cells through liposome delivery and fusion. Poly(ethylene glycol)-polylactide (PEG-PLA) nanoparticles (NPs) are surface-functionalized with aldehyde groups as targeting ligands. The improved in vivo cancer targeting of PEG-PLA NPs is achieved through specific and efficient chemical reaction between the oxyamine and aldehyde groups.     

Functionalization of short multi-walled carbon nanotubes with creatinine and aromatic aldehydes via microwave and thermal methods and their influence on the MKN45 and MCF7 cancer cells

The chemical functionalization of carboxylated short multi-walled carbon nanotubes (Sh–MWCNT–COOH) by creatinine (Sh–MWCNT–amide) and later modification with aromatic aldehydes for producing 2-amino-5-arylidene-1-methyl-1H–imidazol-4(5H)-one (Sh–MWCNT–imidazols) via thermal and microwave methods have been investigated. All the products were characterized by Fourier transform infrared spectroscopy, Raman spectroscopy, scanning electron microscope, elemental analysis, thermogravimetric analysis, derivative thermogravimetric and cellular investigations. These functionalizations have been chosen due to the active sites of CC and carbonyl groups in Sh–MWCNT–imidazols, which might be used as functional materials in the future. MTT assay was used to examine the behavior of cell proliferation after 72 h of cell culture experiments. Cellular investigations were performed for two kinds of cells, human breast and gastric cancer cells. Cellular results showed high toxicity of modified Sh–MWCNTs on the gastric cancer cells compared to breast cells.     

Design,synthesis and biological evaluation of novel quinazoline derivatives as potential NF-κb inhibitors

A series of novel 4-aminoquinazoline derivatives were designed, synthesized and biological properties on nuclear factor-kappaB (NF-κb) pathway inhibitory and potential in vitro anti-proliferation against breast cancer lines were also evaluated. Among them, LU1501 exhibited potent inhibition with IC₅₀ values in SK-BR-3 (10.16 ± 0.86 µM) and HCC1806 (10.66 ± 1.01 µM) cell lines. In vivo studies in breast cancer tumor model proved the correlation between anticancer activity of LU1501 and proliferation inhibition through the NF-κb signal pathway. The molecular docking studies also portrayed the potential binding mechanism between LU1501 and the key proteins of p65 and IkBα in NF-κb pathway. Accordingly, compound LU1501 could serve as a potent agent against breast cancer for further investigation.     

Ex vivo identification of circulating tumor cells in peripheral blood by fluorometric “turn on” aptamer nanoparticles

The detection of the circulating tumor cells (CTCs) detached from solid tumors has emerged as a burgeoning topic for cancer diagnosis and treatment. The conventional CTC enrichment and identification mainly rely on the specific binding of the antibodies on the capture interface of the magnetic nanoparticles with the corresponding biomarkers on the cell membranes. However, these methods could easily generate false-negative results due to the extremely low concentration of CTCs and the internal heterogeneity of the tumor cells. Herein, with the aim of selectively identifying CTCs and improving the detection accuracy in peripheral blood, we designed the fluorometric “turn on” Au nanoparticles (DHANs) with the modification of a tumor-targeted moiety, dehydroascorbic acid (DHA) and a fluorometric aptamer, which could be “switched-on” by an over-expressed intracellular protein, namely hypoxia-inducible factor-1α (HIF 1α). This novel nanoformulated detection platform demonstrated the great capacity for visualizing various CTCs in peripheral blood with significantly improved detection efficiency and sensitivity. As a result, the nanoplatform has a great potential to be further applied for CTC detection in vitro or in vivo, which holds promise for extensive CTC studies.

The detection of the circulating tumor cells (CTCs) detached from solid tumors has emerged as a burgeoning topic for cancer diagnosis and treatment.     

Evaluation on bioactivities of triterpenes from Bergenia emeiensis

Bergenia emeiensis is a traditional folk medicine in China. Most studies are focusing on the bioactivity of bergenin, neglecting other compounds. Therefore, in this present work, the antioxidant, antibacterial and anticancer abilities of triterpenes from B. emeiensis rhizomes (TBE) were comprehensively evaluated. The results showed that TBE could well scavenge DPPH with a lower EC50 of 0.29 mg/mL and could improve the cell viability of CHO cells against H₂O₂ induced cell death. Additionally, TBE also enhanced the resistance of C. elegans under thermal stress, exhibiting a strong antioxidant potential in vivo. Moreover, TBE showed a certain antibacterial ability on five kind strains such as Pseudomonas aeruginosa while TBE could not significantly inhibit the growth of plant pathogenic fungi. Furthermore, TBE possessed an excellent suppression ability on the proliferation of cancer cells especially Hela and Hep G2 cells with an IC50 of 41.79 μg/mL and 48.62 μg/mL at 48 h, respectively. After fractionally extracted with petroleum ether, ethyl acetate and ethanol, ethanol phase (EP) contained the most triterpenes, followed by ethyl acetate phase (EAP) and petroleum ether phase (PEP). Besides, EP and EAP exhibited a strong antioxidant capacity and also inhibited the proliferation of Hela and Hep G2 cells with the effect of pro-oxidation by inducing a high level of ROS and decreasing mitochondrial membrane potential, thus causing oxidative stress then inducing cell apoptosis. Therefore, these outcomes indicated the triterpenes from B. emeiensis possessed a strong antioxidant ability and an anticancer effect, thus making B. emeiensis become a promising potential alternative in pharmacological field.     

Azadirachta indica leaves mediated green synthesized copper oxide nanoparticles induce apoptosis through activation of TNF-α and caspases signaling pathway against cancer cells

Green nanotechnology elucidates highly prioritized anticancer activity. We synthesized Copper oxide nanoparticles (CuONPs) using leaves of Azadirachta indica (A. indica) plants and studied the molecular mechanism of cancer cell apoptosis. After their synthesis, with the help of expository tools like Fourier transform infrared spectroscopy (FT-IR), Transmission electron microscopy (TEM), Dynamic light scattering (DLS) and surface zeta potential we confirmed the successful synthesis of CuONPs. Here, crystalline structure of green synthesized CuONPs of 36?±?8?nm size and spherical shape was able to kill MCF-7 and Hela cells, estimated by MTT assay. Successful internalization of Cu⁺² ions inside the cell was estimated by the atomic absorption study. Cellular uptake of Cu⁺² ions inflicted significant Reactive Oxygen Species (ROS) generation inside the cancer cells, thereby leading to DNA fragmentation as observed by DAPI staining. In in vivo model, CuONPs reduced the breast tumor volume in Balb/C mice and increased the mean survival time through the alteration of pro-inflammatory cytokines level. In case of both in vivo and in vitro models, CuONPs altered the pro-inflammatory cytokine level and pro-apoptotic protein expressions. In future, green synthesized CuONPs might be beneficial for its application as an anticancer drug in in vivo (mice model) and in vitro, though further study is needed on its toxicity.     

Breast cancer cell obatoclax response characterization using passivated‐electrode insulator‐based dielectrophoresis

Inherent electrical properties of cells can be beneficial to characterize different cell lines and their response to experimental drugs. This paper presents a novel method to characterize the response of breast cancer cells to drug stimuli through use of off‐chip passivated‐electrode insulator‐based dielectrophoresis (OπDEP) and the application of AC electric fields. This work is the first to demonstrate the ability of OπDEP to differentiate between two closely related breast cancer cell lines, LCC1 and LCC9 while assessing their drug sensitivity to an experimental anti‐cancer agent, Obatoclax. Although both cell lines are derivatives of estrogen‐responsive MCF‐7 breast cancer cells, growth of LCC1 is estrogen independent and anti‐estrogen responsive, while LCC9 is both estrogen‐independent and anti‐estrogen resistant. Under the same operating conditions, LCC1 and LCC9 had different DEP profiles. LCC1 cells had a trapping onset (crossover) frequency of 700 kHz and trapping efficiencies between 30–40%, while LCC9 cells had a lower crossover frequency (100 kHz) and showed higher trapping efficiencies of 40–60%. When exposed to the Obatoclax, both cell lines exhibited dose‐dependent shifts in DEP crossover frequency and trapping efficiency. Here, DEP results supplemented with cell morphology and proliferation assays help us to understand the response of these breast cancer cells to Obatoclax.     

Polyphenol Oxidase as a Promising Alternative Therapeutic Agent for Cancer Therapy

Cancers have always been the most difficult to fight, the treatment of cancer is still not considered. Thus, exploring new anticancer drugs is still imminent. Traditional Chinese medicine has played an important role in the treatment of cancer. Polyphenol oxidase (PPO) extracted from Edible mushroom has many related reports on its characteristics, but its role in cancer treatment is still unclear. This study aims to investigate the effects of PPO extracted from Edible mushroom on the proliferation, migration, invasion, and apoptosis of cancer cells in vitro and explore the therapeutic effects of PPO on tumors in vivo. A cell counting kit-8 (CCK8) assay was used to detect the effect of PPO on the proliferation of cancer cells. The effect of PPO on cancer cell migration ability was detected by scratch test. The effect of PPO on the invasion ability of cancer cells was detected by a transwell assay. The effect of PPO on the apoptosis of cancer cells was detected by flow cytometry. Female BALB/c mice (18–25 g, 6–8 weeks) were used for in vivo experiments. The experiments were divided into control group, model group, low-dose group (25 mg/kg), and high-dose group (50 mg/kg). In vitro, PPO extracted from Edible mushroom significantly inhibited the proliferation, migration, and invasion capability of breast cancer cell 4T1, lung cancer cell A549, and prostate cancer cell C4-2, and significantly promoted the apoptosis of 4T1, A549, and C4-2. In vivo experiments showed PPO inhibitory effect on tumor growth. Collectively, the edible fungus extract PPO could play an effective role in treating various cancers, and it may potentially be a promising agent for treating cancers.     

Diagnostic microchip to assay 3D colony-growth potential of captured circulating tumor cells

Microfluidic technology has been successfully applied to isolate very rare tumor-derived epithelial cells (circulating tumor cells, CTCs) from blood with relatively high yield and purity, opening up exciting prospects for early detection of cancer. However, a major limitation of state-of-the-art CTC-chips is their inability to characterize the behavior and function of captured CTCs, for example to obtain information on proliferative and invasive properties or, ultimately, tumor re-initiating potential. Although CTCs can be efficiently immunostained with markers reporting phenotype or fate (e.g. apoptosis, proliferation), it has not yet been possible to reliably grow captured CTCs over long periods of time and at single cell level. It is challenging to remove CTCs from a microchip after capture, therefore such analyses should ideally be performed directly on-chip. To address this challenge, we merged CTC capture with three-dimensional (3D) tumor cell culture on the same microfluidic platform. PC3 prostate cancer cells were isolated from spiked blood on a transparent PDMS CTC-chip, encapsulated on-chip in a biomimetic hydrogel matrix (QGel?) that was formed in situ, and their clonal 3D spheroid growth potential was assessed by microscopy over one week in culture. The possibility to clonally expand a subset of captured CTCs in a near-physiological in vitro model adds an important element to the expanding CTC-chip toolbox that ultimately should improve prediction of treatment responses and disease progression.     

Numerical study of dielectrophoresis-modified inertial migration for overlapping sized cell separation

Circulating tumor cells (CTCs) have been proven to have significant prognostic, diagnostic, and clinical values in early-stage cancer detection and treatment. The efficient separation of CTCs from peripheral blood can ensure intact and viable CTCs and can, thus, give proper genetic characterization and drug innovation. In this study, continuous and high-throughput separation of MDA-231 CTCs from overlapping sized white blood cells (WBCs) is achieved by modifying inertial cell focusing with dielectrophoresis (DEP) in a single-stage microfluidic platform by numeric simulation. The DEP is enabled by embedding interdigitated electrodes with alternating field control on a serpentine microchannel to avoid creating two-stage separation. Rather than using the electrokinetic migration of cells which slows down the throughput, the system leverages the inertial microfluidic flow to achieve high-speed continuous separation. The cell migration and cell positioning characteristics are quantified through coupled physics analyses to evaluate the effects of the applied voltages and Reynolds numbers (Re) on the separation performance. The results indicate that the introduction of DEP successfully migrates WBCs away from CTCs and that separation of MDA-231 CTCs from similar sized WBCs at a high Re of 100 can be achieved with a low voltage of magnitude 4 ×10⁶ V/m. Additionally, the viability of MDA-231 CTCs is expected to be sustained after separation due to the short-term DEP exposure. The developed technique could be exploited to design active microchips for high-throughput separation of mixed cell beads despite their significant size overlap, using DEP-modified inertial focusing controlled simply by adjusting the applied external field.     

Expression of GD3 synthase modifies ganglioside profile and increases migration of MCF-7 breast cancer cells

B- and c-series of gangliosides are over-expressed in neuro-ectoderm-related cancers, including breast cancer. It has been shown that G_D3 ganglioside is over-expressed in about 50% of invasive ductal breast carcinoma and the G_D3 synthase (GD3S) gene displays higher expression among estrogen receptor (ER) negative breast tumors. We previously showed that GD3S expression in MDA-MB-231 breast cancer cells induces the expression of G_D2 and increased cell proliferation and migration via a G_D2-dependent activation of c-Met receptor. Here, we show that in ER-positive MCF-7 breast cancer cells, GD3S expression resulted in an increase of G_D1b, which was associated with a decrease of G_M1a and G_M2. Meanwhile, GD3S expressing MCF-7 cells exhibited an increased migration without any modification of proliferation rate. Therefore, GD3S expression can result in different modifications of both ganglioside profiles and cell phenotypes depending on breast cell types.     

Triptolide downregulates Rac1 and the JAK/STAT3 pathway and inhibits colitis-related colon cancer progression

Triptolide, a diterpenoid triepoxide from the traditional Chinese medicinal herb Tripterygium wilfordii Hook. f., is a potential treatment for autoimmune diseases as well a possible anti-tumor agent. It inhibits proliferation of coloretal cancer cells in vitro and in vivo. In this study, its ability to block progress of colitis to colon cancer, and its molecular mechanism of action are investigated. A mouse model for colitis-induced colorectal cancer was used to test the effect of triptolide on cancer progression. Treatment of mice with triptolide decreased the incidence of colon cancer formation, and increased survival rate. Moreover, triptolide decreased the incidence of tumors in nude mice inoculated with cultured colon cancer cells dose-dependently. In vitro, triptolide inhibited the proliferation, migration and colony formation of colon cancer cells. Secretion of IL6 and levels of JAK1, IL6R and phosphorylated STAT3 were all reduced by triptolide treatment. Triptolide prohibited Rac1 activity and blocked cyclin D1 and CDK4 expression, leading to G1 arrest. Triptolide interrupted the IL6R-JAK/STAT pathway that is crucial for cell proliferation, survival, and inflammation. This suggests that triptolide might be a candidate for prevention of colitis induced colon cancer because it reduces inflammation and prevents tumor formation and development.     

Preparation,characterization, and antitumor activity of Chaenomeles speciosa polysaccharide-based selenium nanoparticles

Nanoparticles have been found to possess unique advantages in many fields, especially in the field of cancer treatment. Herein, based on the unique physical and chemical properties of natural polysaccharides, the polysaccharide from the edible and medicinal fruits of Chaenomeles speciosa was prepared, and the complex nanoparticles constructed by combining C. speciosa polysaccharide with selenium have been successfully developed by a chemical method. Monodisperse spherical nanoparticles with the particle size of 80.5 nm were characterized by various methods, which exhibited ideal size distribution and prominent stability under physiological conditions and alkaline conditions. Cellular studies demonstrated the nanoparticles significantly inhibited the growth of MCF-7 cells with an IC₅₀ value of 8.37 ± 0.97 μg/mL through inducing the apoptosis and arresting the cell circle at S phase. Moreover, the zebrafish assays confirmed the antitumor effects of the nanoparticles, which suppressed the proliferation and migration of tumor and blocked the angiogenesis of transgenic zebrafish. Collectively, the results suggested that the nanoparticles may be considered as a candidate agent to treat breast cancer.