Vision Screening Research Articles

Potential treatment approaches for malignant peritoneal mesothelioma: in vivo and in vitro experimental study of natural killer cell immunotherapy.

Malignant peritoneal mesothelioma (MPM) is a rare primary malignant tumor with an extremely poor prognosis that currently lacks effective treatment options. This study investigated the in vitro and in vivo efficacy of natural killer (NK) cells for treatment of MPM. An in vitro study was conducted to assess the cytotoxicity of NK cells from umbilical cord blood to MPM cells with the use of a high-content imaging analysis system, the Cell Counting Kit-8 assay, and Wright-Giemsa staining. The level of NK cell effector molecule expression was detected by flow cytometry and enzyme-linked immunosorbent assays. The ability of NK cells to kill MPM cells was determined based on live cell imaging, transmission electron microscopy, and scanning electron microscopy. An in vivo study was conducted to assess the efficacy and safety of NK cell therapy based on the experimental peritoneal cancer index, small animal magnetic resonance imaging, and conventional histopathologic, cytologic, and hematologic studies. NK cells effectively killed MPM cells through the release of effector molecules (granzyme B, perforin, interferon-γ, and tumor necrosis factor-α) in a dose- and density-dependent manner. The NK cell killing process potentially involved four dynamic steps: chemotaxis; hitting; adhesion; and penetration. NK cells significantly reduced the tumor burden, diminished ascites production, and extended survival with no significant hematologic toxicity or organ damage in NOG mice. NK cell immunotherapy inhibited proliferation of MPM cells in vitro and in vivo with a good safety profile.

An image-based RNAi screen identifies the EGF.R signaling pathway as a regulator of Imp/ IGF2BP RNP granules.

Biomolecular condensates have recently retained much attention since they provide a fundamental mechanism of cellular organization. Among those, cytoplasmic RNP granules selectively and reversibly concentrate RNA molecules and regulatory proteins, thus contributing to the spatio-temporal regulation of associated RNAs. Extensive in vitro work has unraveled the molecular and chemical bases of RNP granule assembly. The signaling pathways controlling this process in a cellular context are however still largely unknown. Here, we aimed at identifying regulators of cytoplasmic RNP granules characterized by the presence of the evolutionarily conserved IGF2BP/Imp/ZBP1 RNA binding protein. We performed a high-content image-based RNAi screen targeting all Drosophila genes encoding RNA binding proteins, phosphatases and kinases. This led to the identification of dozens of genes regulating the number of Imp+ RNP granules in S2R+ cells, among which components of the MAPK pathway. Combining functional approaches, phospho-mapping and generation of phospho-variants, we further showed that the EGF.R signaling inhibits Imp+ RNP granule assembly through activation of MAPK/Rolled and Imp S15 phosphosite. This work illustrates how signaling pathways can regulate cellular condensate assembly by post-translational modifications of specific components.

Seq-Scope: repurposing Illumina sequencing flow cells for high-resolution spatial transcriptomics.

Spatial transcriptomics technologies aim to advance gene expression studies by profiling the entire transcriptome with intact spatial information from a single histological slide. However, the application of spatial transcriptomics is limited by low resolution, limited transcript coverage, complex procedures, poor scalability and high costs of initial setup and/or individual experiments. Seq-Scope repurposes the Illumina sequencing platform for high-resolution, high-content spatial transcriptome analysis, overcoming these limitations. It offers submicrometer resolution, high capture efficiency, rapid turnaround time and precise annotation of histopathology at a much lower cost than commercial alternatives. This protocol details the implementation of Seq-Scope with an Illumina NovaSeq 6000 sequencing flow cell, allowing the profiling of multiple tissue sections in an area of 7 mm × 7 mm or larger. We describe the preparation of a fresh-frozen tissue section for both histological imaging and sequencing library preparation and provide a streamlined computational pipeline with comprehensive instructions to integrate histological and transcriptomic data for high-resolution spatial analysis. This includes the use of conventional software tools for single-cell and spatial analysis, as well as our recently developed segmentation-free method for analyzing spatial data at submicrometer resolution. Aside from array production and sequencing, which can be done in batches, tissue processing, library preparation and running the computational pipeline can be completed within 3 days by researchers with experience in molecular biology, histology and basic Unix skills. Given its adaptability across various biological tissues, Seq-Scope establishes itself as an invaluable tool for researchers in molecular biology and histology.

A preliminary study of artificial intelligence to recognize tessellated fundus in visual function screening of 7-14 year old students

BackgroundTo evaluate the accuracy of artificial intelligence (AI)-based technology in recognizing tessellated fundus in students aged 7–14 years.MethodsA retrospective study was conducted to collect consecutive fundus photographs for visual function screening of students aged 7–14 years old in Haikou City from June 2018 to May 2019, and 1907 cases were included in the study. Among them, 949 cases were male and 958cases were female. The results were manually analyzed by two attending ophthalmologists to ensure the accuracy of the results. In case of discrepancies between the results analyzed by the two methods, the manual results were used as the standard. To assess the sensitivity and specificity of AI in recognizing tessellated fundus, a Kappa consistency test was performed comparing the results of manual recognition with those of AI recognition.ResultsAmong 1907 cases, 1782 cases, or 93.4%, were completely consistent with the recognition results of manual and AI; 125 cases, or 6.6%, were analyzed with differences. The diagnostic rates of manual and AI for tessellated fundus were 26.1% and 26.4%, respectively. The sensitivity, specificity and area of the ROC curve (AUC) of AI for recognizing tessellated fundus in students aged 7–14 years were 88.0%, 95.4% and 0.917, respectively. The results of test showed that that the manual and AI identification results were highly consistent (κ = 0.831, P = 0.000).ConclusionAI analysis has high specificity and sensitivity for tessellated fundus identification in students aged 7–14 years, and it is feasible to apply artificial intelligence to visual function screening in students aged 7–14 years.

ATPase Valosin-Containing Protein (VCP) Is Involved During the Replication and Egress of Sialodacryoadenitis Virus (SDAV) in Neurons

Sialodacryoadenitis virus (SDAV) has been identified as the etiological agent responsible for the respiratory system and salivary gland infections in rats. The existing literature on SDAV infections is insufficient to address the topic adequately, particularly in relation to the central nervous system. In order to ascertain how SDAV gains access to neuronal cells and subsequently exits, our attention was focused on the small molecule valosin-containing protein (VCP), which is an ATPase. VCP is acknowledged for its function in the ubiquitin-mediated proteasomal degradation of proteins, including those of viral origin. To ascertain the potential influence of VCP on SDAV replication and egress, high-content screening was employed to determine the viral titer and protein content. Western blot analysis was employed to ascertain the relative expression of VCP. Real-time imaging of SDAV-infected cells and confocal imaging for qualitative morphological analysis were conducted. The Eeyarestatin I (EerI) inhibitor was employed to disrupt VCP involvement in the endoplasmic reticulum-associated protein degradation pathway (ERAD) in both pre- and post-incubation systems, with concentrations of 5 μM/mL and 25 μM/mL, respectively. We demonstrated for the first time that SDAV productively replicates in cultured primary neurons. VCP expression is markedly elevated during SDAV infection. The application of 5 μM/mL EerI in the post-treatment system yielded a statistically significant inhibition of the SDAV yield. It is likely that this modulates the efficacy of virion assembly by arresting viral proteins in the submembrane area.

Use of intraoral mobile photography for screening of oral health in children

Abstract Background The aim of the study is to evaluate the diagnostic accuracy of intraoral mobile photography to assess caries intensity (DMFT/deft), simplified oral hygiene index (S-OHI) and modified gingival index (MGI). Methods Children aged 7-12 were included in the study. The clinical doctor evaluated the oral health indicators by visual examination: DMFT, deft, S-OHI, MGI were calculated. Dental students independently captured photos with a mobile phone (iPhone-11) in 8 predetermined projections. Dental images were kept in coded folders for research anonymity. Another professional calculated index based on the photos. Variables were used with binary values (DMFT/deft = 0/≥1; MGI=0/≥1; S-OHI≤1.2/>1.2). Sensitivity, specificity, positive predictive value (PPV), negative predictive value (NPV) of dental photography were evaluated and Cohen’s Kappa was calculated to measure the level of agreement between two independent observers. Results 2864 photographs were evaluated for 358 participants. The sensitivity and specificity of intraoral mobile photography for DMFT index is 95.8 (95% CI: 93.4-98.3) and 89.2 (95% CI: 83-95.5); For deft index: 100.0 (95% CI: 100-100) and 88.6 (95% CI: 79.3-98); For MGI: 89.7 (95% CI: 85.8-93.5) and 91.4 (95% CI: 86.3-96.5); For S-OHI: 77.6 (95% CI: 67.6-87.6) and 93.8 (95% CI: 91-96.6); The PPV value for DMFT, deft, MGI and S-OHI is 96.2; 97.7; 95.6 and 74.3 and the NPV value is 88.3; 100.0; 80.9 and 94.8 respectively. It was achieved substantial and perfect agreement between two independent raters: For DMFT, deft, MGI, S-OHI indices Cohen’s Kappa =0.85; 0.93; 0.78; 0.70 correspondingly. Conclusions Intraoral mobile photography, if applied within appropriate guidelines is reliable for assessing caries intensity, simplified hygiene index and modified gingival index as well as visual screening and may become a priority for dental public health. The involvement of dental students in studies of similar design is appropriate. Key messages • Intraoral mobile photography can be used for oral health screening in children. • The involvement of dental program students in screening studies conducted with intraoral mobile photography is appropriate.

Integrating single-cell sequencing and genetic lineage tracing reveals endothelial plasticity during atrial remodeling

Abstract Background Atrial fibrillation (AF), as the most burdensome cardiac arrhythmia, could lead to the significant mortality and morbidity. Atrial fibrosis is a well-recognized pathophysiological factor of the development and progression of AF, which also hampers its treatment. However, the underlying mechanisms of this intricate process remain largely unknown. Purpose This study sought to reveal the cellular composition of AF substrate and investigate the vital contributors to atrial structural remodeling. Methods Left atrial appendages from three patients with AF undergoing surgical ablation and three individuals with sinus rhythm undergoing heart transplantation were subjected to 10X single-cell RNA sequencing (scRNA-seq). Another five public scRNA-seq or snRNA-seq datasets of potentially remodeled right or left appendages were retrieved across three publications. The vital contributors of atrial structural remodeling and their characteristics were identified by intercellular communication analysis and trajectory inference. Transverse aortic constriction (TAC) was used to induce atrial remodeling in Cdh5-CreERT2;RFP mice, followed by scRNA-seq of endothelial cells (ECs). Human primary atrial ECs and fibroblasts were isolated for cell-cell interaction experiments. ECs-specific mouse models of Transforming growth factor beta 1 (TGFB1) (knockout and overexpression) were generated. Electrophysiological and histology analyses were performed to determine the consequences of ECs-derived TGFB1 gain and loss of function in the atrium. Results The comprehensive analysis of different scRNA-seq datasets revealed that ECs played an important regulatory role in the homeostasis of atrial substrate and displayed remarkable mesenchymal activation during atrial remodeling, which was further confirmed by TAC mice. Immunofluorescence staining and high-content screening suggested that the complete transition from ECs to mesenchymal cells slightly contributed to atrial remodeling. However, TGFB1 secreted from mesenchymal activated ECs significantly promoted activation, proliferation, and collagen secretion of fibroblasts. We discovered that overexpression of TGFB1 in ECs of mice significantly increased atrial fibrosis, and thus prolonging AF duration. Besides, knockout of TGFB1 in ECs of mice underwent TAC significantly attenuated the atrial fibrosis and decreased the rate of AF. Conclusion Our work demonstrates that mesenchymal ECs-derived Tgfb1 plays an important role in atrial remodeling by regulating the fibroblast function. EC-specific interventions were suggested to facilitate the development of novel strategies for mitigating AF substrate remodeling.

Characterisation of the novel SCN5A-P1891A variant, implicated in left ventricular noncompaction cardiomyopathy in a Finnish family, using human induced pluripotent stem cell-derived cardiomyocytes

Abstract Introduction Left ventricular noncompaction (LVNC) is a heterogenous cardiomyopathy characterised by an extensively trabeculated left ventricle (LV). Several genetic variants that perturb trabeculae compaction, and thus LV maturation, have been reported [1]. However, the precise mechanisms underpinning this have proven contentious with, for example, differentially aberrant cardiomyocyte proliferation implicated in the development of LVNC [2,3]. Purpose In this study, we investigate a novel SCN5A variant, P1891A, which is associated with LVNC in a Finnish family. We ascertain the effects of this variant through the characterisation of variant-carrying human induced pluripotent stem cell-derived cardiomyocytes (P1891A-hiPSC-CMs). Methods We isolated dermal fibroblasts from a symptomatic member of a Finnish family carrying the SCN5A-P1891A variant; derived P1891A-hiPSCs via nucleofection with reprogramming plasmids [4]; and differentiated these into hiPSC-CMs alongside healthy control-hiPSCs. We determined the action potential (AP) and sodium- (INa) and calcium-current (ICa) densities of hiPSC-CMs via patch-clamp. We investigated gene expression in hiPSC-CMs through qPCR and employed Multiple Approaches Combined (MCA) proteomics [5] in SCN5A-transfected HEK293-like cells to elucidate protein-protein interactions (PPI). We subjected hiPSC-CMs to mechanical stretch [6] to examine their stress response and assessed their proliferation capacity via high-content analysis for the percentage of BrdU positive hiPSC-CMs following mitogenic stimulation (5 µM CHIR99021 and 1 µM SB203580). Finally, we ascertained contractile kinetics and apparent contractile force using fibrin hydrogel-based engineered heart tissues (EHTs) [7]. Results The P1891A-hiPSC-CMs demonstrated elevated INa density alongside enhanced arrhythmogenicity relative to healthy control hiPSC-CMs although, AP kinetics and ICa density were unperturbed (Fig. 1). Under baseline conditions, P1891A-hiPSC-CMs exhibited higher SCN5A gene expression and proteomics revealed a reduction in PPI. Baseline proliferation was unchanged; however, aged P1891A-hiPSC-CMs had enhanced proliferative capacity following mitogenic stimulation. Further, the P1891A-hiPSC-CMs displayed impaired tolerance to mechanical stretch as evidenced by upregulated NPPB and ACTA1 expression. In the context of the EHT, P1891A-hiPSC-CMs yielded disparate phenotypes. Whilst a subset compacted fully and yielded weaker contractile parameters relative to healthy control EHTs, the majority of P1891A-hiPSC-CM EHTs failed to fully compact thereby recapitulating the LVNC phenotype (Fig. 2). Conclusions This study presents a unique aetiology of LVNC and links, for the first time, SCN5A mutations with enhanced human cardiomyocyte proliferation. The ability to recapture the noncompaction phenotype in EHTs presents a powerful model for future mechanistic research and drug development.

Imaging‐based profiling for elucidation of antibacterial mechanisms of action

AbstractIn this review, we aim to summarize experimental data and approaches to identifying cellular targets or mechanisms of action of antibacterials based on imaging techniques. Imaging‐based profiling methods, such as bacterial cytological profiling, dynamic bacterial morphology imaging, and others, have become a useful research tool for mechanistic studies of new antibiotics as well as combinations with conventional ones and other therapeutic options. The main methodological and experimental details and obtained results are summarized and discussed. The review covers the literature up to February 2024.

Android-based framework for condition assessment of existing RC hospital buildings

Rapid visual screening (RVS) is a practically viable tool implemented all over the world to rank structures based on their seismic vulnerability. Seismic assessment of hospital buildings is essential in seismic-prone regions to ensure their structural integrity and readiness to provide emergency care and medical treatment after significant seismic events. Therefore, in the current study, an approach is developed that is similar to the proven methodologies reported in the literature, for the seismic evaluation of structural and non-structural elements of hospital buildings in a metropolitan city like Karachi. Karachi is located in the southwest of Pakistan and is vulnerable to earthquake and tsunami hazards. To this end, an android-based RVS system has been developed for large-scale seismic risk mapping of hospital buildings. The proposed system acquires the physical status of the building features in real time and identifies the building performance obtained from the calculated seismic risk index. Moreover, three case study hospital buildings were employed and analysed through the proposed RVS system. Results illustrate the performance of case study hospital buildings at organisational, structural and non-structural levels based on seismic risk indices.

Genetically Engineered Filamentous Bacteriophages Displaying TGF-β1 Promote Angiogenesis in 3D Microenvironments

Combined 3D cell culture in vitro assays with microenvironment-mimicking systems are effective for cell-based screening tests of drug and chemical toxicity. Filamentous bacteriophages have diverse applications in material science, drug delivery, tissue engineering, energy, and biosensor development. Specifically, genetically modified bacteriophages have the potential to deliver therapeutic molecules or genes to targeted tumor tissues. The engineered bacteriophages in this study significantly enhanced endothelial cell migration and tube formation within the extracellular matrix (ECM). Compared to TGF-β1 alone and non-modified phages, the presence of TGF-β1 on the bacteriophages demonstrated superior performance as a continuous stimulant in the microenvironment, effectively promoting these angiogenic processes. Assays, including RT-qPCR, ELISA, and fluorescence microscopy, confirmed the expression of angiogenic markers such as CD31, validating the formation of 3D angiogenic structures. Our findings indicate that the TGF-β1 displayed by bacteriophages likely acted as a chemotactic factor, promoting the migration, proliferation, and tube formation of endothelial cells (ECs) within the ECM. Although direct contact between ECs and bacteriophages was not explicitly confirmed, the observed effects strongly suggest that TGF-β1-RGD bacteriophages contributed to the stimulation of angiogenic processes. The formation of angiogenic structures by ECs in the ECM was confirmed as three-dimensional and regulated by the surface treatment of microfluidic channels. These results suggest that biocompatible TGF-β1-displaying bacteriophages could continuously stimulate the microenvironment in vitro for angiogenesis models. Furthermore, we demonstrated that these functionalized bacteriophages have the potential to be utilized as versatile biomaterials in the field of biomedical engineering. Similar strategies could be applied to develop angiogenic matrices for tissue engineering in in vitro assays.

Validation of a functional human AD model with four AD therapeutics utilizing patterned ipsc-derived cortical neurons integrated with microelectrode arrays

Preclinical methods are needed for screening potential Alzheimer’s disease (AD) therapeutics that recapitulate phenotypes found in the Mild Cognitive Impairment (MCI) stage or even before this stage of the disease. This would require a phenotypic system that reproduces cognitive deficits without significant neuronal cell death to mimic the clinical manifestations of AD during these stages. Long-term potentiation (LTP), which is a correlate of learning and memory, was induced in mature human iPSC-derived cortical neurons cultured on microelectrode arrays utilizing circuit patterns connecting two adjacent electrodes. We demonstrated an LTP system that modeled the MCI and pre-MCI stages of Alzheimer’s and validated this functional system utilizing four AD therapeutics, which was also verified utilizing patch-clamp electrophysiology. LTP was induced by tetanic electrical stimulation, and LTP maintenance was significantly reduced in the presence of Amyloid-Beta 42 (Aβ42) oligomers compared to the controls, however, co-treatment with AD therapeutics (Donepezil, Memantine, Rolipram and Saracatinib) corrected Aβ42-induced LTP impairment. The results illustrate the utility of the system as a validated platform to model MCI AD pathology, and potentially for the pre-MCI phase before significant neuronal death. This system also has the potential to become an ideal platform for high-content therapeutic screening for other neurodegenerative diseases.

Testing Visual Function by Assessment of the Optomotor Reflex in Glaucoma.

Optomotor response/reflex (OMR) is a fast and efficient first-in-line visual screening method, especially for rodents. It has the potential to evaluate both the scotopic and photopic visions of nonrestrained animals through tracking head movement, providing a quantitative estimate of visual functions. In restrained animals, optokinetic response (OKR), compensatory eye movements for visual shifts in the surroundings, is utilized. Both OMR and OKR capitalize on an individual's innate reflex to stabilize images for the purpose of capturing clear vision. The two reflexes have similar reliability when evaluating stimulus luminance, contrast, spatial frequency, and velocity. They have emerged as powerful tools to evaluate the efficacy of pharmacological treatments and phenotypes of subjects undergoing study. With OMR and OKR accurately assessing visual acuity (VA) as well as contrast sensitivity (CS), the gold standards for measuring clinical vision, they provide reliable and easily accessible results that further eye and brain research. These methods of sight evaluation have been used in multiple animal models, particularly mice and zebrafish. Through OMR assays, these animal models have been utilized to investigate retinal degenerative diseases, helping researchers differentiate between worsening stages. Alongside tests such as optical coherence tomography (OCT), OMR provides confirmation of visual status, where increased OMR function often correlates with improved visual status. OMR has continued to be used outside of glaucoma in various retinal diseases, such as retinitis pigmentosa (RP), diabetic retinopathy, and age-related macular degeneration.In this chapter, we will introduce the concept and application of visual stimulus-induced head or eye reflex movement in different animal species and experimental models of eye diseases, such as glaucoma and other neurodegenerative disorders, and in patients with glaucoma.

Cell-Based Screen Identifies a Highly Potent and Orally Available ABCB1 Modulator for Treatment of Multidrug Resistance.

Targeting ABCB1 is a promising strategy in combating multidrug resistance. Our cell-based phenotypic screening led to the discovery of novel triazolo[1,5-a]pyrimidone-based ABCB1 modulators. Notably, WS-917 was identified as a significant contributor to heightened sensitization of human colorectal adenocarcinoma cells (SW620/Ad300) to paclitaxel (IC50 = 5 nM). Mechanistic elucidation revealed that this compound substantially augmented intracellular paclitaxel and [3H]-paclitaxel, concurrently mitigating the efflux of [3H]-paclitaxel in SW620/Ad300 through the inhibition of ABCB1 efflux. The cellular thermal shift assay underscored its ability to stabilize ABCB1 through direct binding. Additionally, WS-917 induced stimulation of ABCB1 ATPase activity while exhibiting negligible inhibitory effect against CYP3A4. Remarkable was its capacity to enhance the sensitivity of SW620/Ad300 to paclitaxel, as well as the sensitivity of CT26/TAXOL to paclitaxel and PD-L1 inhibitor (Atezolizumab) in vivo, all achieved without inducing observable toxicity. The discovery of WS-917 holds promise for the development of more potent ABCB1 modulators.

CMS121, a Novel Drug Candidate for the Treatment of Alzheimer's Disease and Age-Related Dementia.

Old age is the major risk factor for sporadic Alzheimer's disease (AD). However, old age-related changes in brain physiology have generally not been taken into consideration in developing drug candidates for the treatment of AD. This is at least partly because the role of these age-related processes in the development and progression of AD are still not well understood. Nevertheless, we and others have described an association between the oxytosis/ferroptosis non-apoptotic regulated cell death pathway and aging. Based on this association, we incorporated protection against this pathway as part of a cell-based phenotypic screening approach to identify novel drug candidates for the treatment of AD. Using this approach, we identified the fisetin derivative CMS121 as a potent neuroprotective molecule that is able to maintain cognitive function in multiple pre-clinical models of AD. Furthermore, we identified a key target of CMS121 as fatty acid synthase, a protein which had not been previously considered in the context of AD. Herein, we provide a comprehensive description of the development of CMS121, its preclinical activities, and the results of the toxicology testing that led to its IND approval.

Targeting AGAT gene expression – a drug screening approach for the treatment of GAMT deficiency

ABSTRACT Background Targeting the enzyme L-Arginine:glycine amidinotransferase (AGAT) to reduce the formation of guanidinoacetate (GAA) in patients with guanidinoacetate methyltransferase (GAMT) deficiency, we attempted to identify drugs for repurposing that reduce the expression of AGAT via transcriptional inhibition. Research Design and Methods The authors applied a HeLa cell line stably expressing AGAT promoter and firefly luciferase reporter for high-content screening and secondary screening. For further assessment, the authors integrated Nanoluc luciferase as a reporter into the endogenous AGAT gene in HAP1 cell lines and used the human immortalized cell line RH30 as model of GAMT deficiency. Results Screening 6,000 drugs and drug-like compounds, the authors identified 43 and 34 high-score candidates as inhibitors and inducers of AGAT promoter-reporter expression, respectively. After further deselection considering dose response, drug toxicity, topical formulations, price, and accessibility, the authors assessed seven candidates and found none of them demonstrating efficacy in HAP1 and RH30 cells and warranting further assessment. Conclusion The selection of the test models is crucial for screening of gene repressor drugs. Almost all drugs with an impact on gene expression had off-target effects. It is unlikely to find drugs that are selective inhibitors of AGAT expression, rendering pharmacological AGAT gene repression a risky approach for the treatment of GAMT deficiency.

CD81-guided heterologous EVs present heterogeneous interactions with breast cancer cells

BackgroundExtracellular vesicles (EVs) are cell-secreted particles conceived as natural vehicles for intercellular communication. The capacity to entrap heterogeneous molecular cargoes and target specific cell populations through EV functionalization promises advancements in biomedical applications. However, the efficiency of the obtained EVs, the contribution of cell-exposed receptors to EV interactions, and the predictability of functional cargo release with potential sharing of high molecular weight recombinant mRNAs are crucial for advancing heterologous EVs in targeted therapy applications.MethodsIn this work, we selected the popular EV marker CD81 as a transmembrane guide for fusion proteins with a C-terminal GFP reporter encompassing or not Trastuzumab light chains targeting the HER2 receptor. We performed high-content imaging analyses to track EV-cell interactions, including isogenic breast cancer cells with manipulated HER2 expression. We validated the functional cargo delivery of recombinant EVs carrying doxorubicin upon EV-donor cell treatment. Then, we performed an in vivo study using JIMT-1 cells commonly used as HER2-refractory, trastuzumab-resistant model to detect a more than 2000 nt length recombinant mRNA in engrafted tumors.ResultsFusion proteins participated in vesicular trafficking dynamics and accumulated on secreted EVs according to their expression levels in HEK293T cells. Despite the presence of GFP, secreted EV populations retained a HER2 receptor-binding capacity and were used to track EV-cell interactions. In time-frames where the global EV distribution did not change between HER2-positive (SK-BR-3) or -negative (MDA-MB-231) breast cancer cell lines, the HER2 exposure in isogenic cells remarkably affected the tropism of heterologous EVs, demonstrating the specificity of antiHER2 EVs representing about 20% of secreted bulk vesicles. The specific interaction strongly correlated with improved cell-killing activity of doxorubicin-EVs in MDA-MB-231 ectopically expressing HER2 and reduced toxicity in SK-BR-3 with a knocked-out HER2 receptor, overcoming the effects of the free drug. Interestingly, the fusion protein-corresponding transcripts present as full-length mRNAs in recombinant EVs could reach orthotopic breast tumors in JIMT-1-xenografted mice, improving our sensitivity in detecting penetrant cargoes in tissue biopsies.ConclusionsThis study highlights the quantitative aspects underlying the creation of a platform for secreted heterologous EVs and shows the limits of single receptor-ligand interactions behind EV-cell engagement mechanisms, which now become the pivotal step to predict functional tropism and design new generations of EV-based nanovehicles.

Patterns of refractive errors and visual function in school-going children in South Africa

Background: Uncorrected refractive error is the most significant contributor of VI in children and is usually detected through vision screenings or scheduled eye and vision examinations conducted among school children.Aim: To describe patterns of refractive errors (RE), visual function and amblyopia in school-going children.Setting: Mankweng, Polokwane, South Africa.Methods: Retrospective chart reviews were conducted on 837 clinical record cards of children attending selected schools and who were screened between 2019 and 2021 at the University of Limpopo Optometry clinic. Purposive sampling was used to sample the clinical record cards.Results: About 134 children (16%) reported blurred vision, 197 (23.5%) failed distance visual acuity screening, while 173 (20.7%) had RE. Myopia among 168 (9.6%) children was the most common RE, followed by astigmatism and hyperopia at 60 (4.70%) and 28 (4.4%), respectively. Furthermore, 14 (1.7%) children had anisometropia. Amblyopia, colour vision deficiency and contrast sensitivity were also detected at prevalence rates of 4.4%, 9.8% and 8.2%, respectively.Conclusion: Vision screenings and regular comprehensive eye examinations are commonly conducted to detect and manage REs to prevent or delay the onset of amblyopia and strabismus. Children had a high prevalence of RE and amblyopia, which is similar to global estimates.Contribution: To describe the pattern of REs, amblyopia and visual function, which is critical to understand the prevalence of amblyopia and associated conditions. Knowing the patterns of these conditions may provide an impetus for the implementation of strategies such as vision screenings and vision examinations in schools.

Identification of lipid senolytics targeting senescent cells through ferroptosis induction.

Cellular senescence is a key driver of the aging process and contributes to tissue dysfunction and age-related pathologies. Senolytics have emerged as a promising therapeutic intervention to extend healthspan and treat age-related diseases. Through a senescent cell-based phenotypic drug screen, we identified a class of conjugated polyunsaturated fatty acids, specifically α-eleostearic acid and its methyl ester derivative, as novel senolytics that effectively killed a broad range of senescent cells, reduced tissue senescence, and extended healthspan in mice. Importantly, these novel lipids induced senolysis through ferroptosis, rather than apoptosis or necrosis, by exploiting elevated iron, cytosolic PUFAs and ROS levels in senescent cells. Mechanistic studies and computational analyses further revealed their key targets in the ferroptosis pathway, ACSL4, LPCAT3, and ALOX15, important for lipid-induced senolysis. This new class of ferroptosis-inducing lipid senolytics provides a novel approach to slow aging and treat age-related disease, targeting senescent cells that are primed for ferroptosis.

Rapid and Ultrasensitive Detection of H. aduncum via the RPA-CRISPR/Cas12a Platform.

Hysterothylacium aduncum is one of six pathogens responsible for human anisakiasis. Infection with H. aduncum can cause acute abdominal symptoms and allergic reactions and is prone to misdiagnosis in clinical practice. This study aims to enhance the efficiency and accuracy of detecting H. aduncum in food ingredients. We targeted the internal transcribed spacer 1 (ITS 1) regions of Anisakis to develop a visual screening method for detecting H. aduncum using recombinase polymerase amplification (RPA) combined with the CRISPR/Cas12a system. By comparing the ITS 1 region sequences of eight nematode species, we designed specific primers and CRISPR RNA (crRNA). The specificity of RPA primers was screened and evaluated, and the CRISPR system was optimized. We assessed its specificity and sensitivity and performed testing on commercial samples. The results indicated that the alternative primer ADU 1 was the most effective. The final optimized concentrations were 250 nM for Cas12a, 500 nM for crRNA, and 500 nM for ssDNA. The complete test procedure was achievable within 45 min at 37 °C, with a limit of detection (LOD) of 1.27 pg/μL. The amplified product could be directly observed using a fluorescence microscope or ultraviolet lamp. Detection results for 15 Anisakis samples were entirely consistent with those obtained via Sanger sequencing, demonstrating the higher efficacy of this method for detecting and identifying H. aduncum. This visual detection method, characterized by simple operation, visual results, high sensitivity, and specificity, meets the requirements for food safety testing and enhances monitoring efficiency.