Simple Instrument Research Articles

Correction of Sensible Heat Flux from Flux-Gradient Method to Eddy Covariance Method Based on Multi-Layer Perceptron

Abstract. Understanding surface-atmosphere interactions is critical for environmental and meteorological studies. Sensible heat flux, a key component in this interaction, is typically measured using methods such as Eddy Covariance (EC) and Flux-Gradient (FG). The EC method, known for its high temporal resolution and direct measurement capabilities of wind speed, temperature, and humidity changes, requires the use of expensive and complex equipment, making it costly and challenging to implement. On the contrary, the FG method is more accessible and economical, relying on simpler instruments, but often lacks the precision of the EC method. To harness the benefits of both methods, this article uses the Multi-Layer Perceptron (MLP) machine learning method to enhance the accuracy of the FG method's sensible heat flux calculations. Through the MLP model, this paper aims to determine the optimal parameter settings for the specific measurement environment, thereby improving the FG methods accuracy. The data was measured from Guandu Village, Anhui Province, China. This research seeks to demonstrate that the trained MLP model can be applied to similar measurement environments, thus enhancing the FG method's applicability and precision.

Enhanced chemiluminescence with sub-1 nanometer CuO-PMA nanosheets for the sensitive detection of quercetin

BackgroundChemiluminescence (CL) analysis, characterized by its simple instrumentation, high signal-to-noise ratio, wide linear range, and minimal background interference, has garnered increasing attention from researchers. Nanomaterials (NMs) have been explored to enhance CL intensity. Notably, sub-1 nanometer scale NMs are considered to hold significant untapped potential due to their size effects. The application of these sub-1 nanometer NMs in enhancing CL is anticipated to yield favorable results. Additionally, the low water solubility and bioavailability of quercetin glycosides lead to their presence in bodily fluids at only trace levels, highlighting the urgent need for efficient and rapid detection methods. ResultsIn this work, phosphomolybdic acid (PMA) was incorporated into CuO to synthesize sub-1 nanometer CuO-PMA nanosheets (SNSs) using a cluster-core co-assembly strategy. Conformational and structural characterization confirmed the successful synthesis of these nanosheets. The CuO-PMA SNSs were employed to enhance the CL emission of the luminol-H2O2 system, resulting in an increase of over 1000 times. The catalytic properties of CuO-PMA SNSs significantly facilitated the decomposition of H2O2, leading to an enhanced production of reactive oxygen species, which in turn induced the CL enhancement. Given that the antioxidant effect of quercetin would consume the reactive oxygen species generated during the catalysis, a decrease in CL intensity was anticipated. A CL sensor for quercetin detection was developed based on the CuO-PMA SNSs-luminol-H2O2 system, demonstrating a strong linear relationship (R2 = 0.9969) and a low detection limit of 0.31 nM. SignificanceThis research provides a strategy to enhance the CL intensity of the luminol-H2O2 system by using CuO-PMA SNSs, offering a highly sensitive assay for detecting quercetin concentrations. The method is characterized as a simple and cost-effective analytical strategy making CL analysis very attractive for chemical analysts.

Programmed DNA tile response system enabled accurate detection of ATP for clinical diagnosis

Adenosine triphosphate (ATP), as a crucial signaling molecule, is of high potential diagnosis value for multiple diseases. However, current technologies for ATP detection struggle to satisfy the harsh conditions required for biospecimen tests, existing several limitations for clinical practical application. In this study, the DNA tile response system was designed and constructed by integrating nucleic acid aptamer, hybrid chain reaction (HCR), and DNA tile self-assembly technology to achieve accurate detection of ATP in body fluid specimens. The DNA tile response system, possessing high-order structure characteristic, could remove HCR false-positive products and conquer the high noise background to enhance the detection sensitivity. Under the optimal reaction parameters, this system achieved the low limit of detection (LOD) of 189.23 nM over a wide linear range and splendid detection specificity faced with multiple interference terms. Furthermore, this system, possessing simple storage conditions, long-term detection stability, and superior anti-interference performance, was sufficient to satisfy the detection requirements for complicated biological specimens in multi-scenarios. Ultimately, the DNA tile response system showed excellent diagnostic efficiency that could easily distinguish urinary tract infection patients and healthy controls through ATP quantification, as well as hypertension patients and healthy ones. This system provides a high-potential rapid detection tool for early diagnosis and dynamic monitoring of urinary tract infections and hypertension, holding enormous potential for clinical translation due to the superiorities of simple operation, general applicability, and low instrument requirements.

Cavity-enhanced Faraday rotation spectroscopy for interference-free measurement of OH radical at 2.8 μm

An instrument based on cavity-enhanced Faraday rotation spectroscopy (CE-FRS) operating at 2.8 μm has been developed for interference-free measurement of OH radicals in the laboratory. By off-axis coupling of a continuous-wave laser into a high finesse optical cavity, FRS signal is obtained from balanced detection of time-integrated light intensity leaking out of the cavity in the presence of magnetic field. Radio-frequency white noise (5–520 MHz) was injected into laser current which reduced intensity fluctuations in cavity transmission, thus improved the signal-to-noise ratio of the spectroscopic signal by a factor of 2. The setup provides a simple and robust spectroscopic instrument for in-situ and highly-selective detection of paramagnetic species. We demonstrated the instrument’s capabilities using OH radical with concentration in the range of 1012 molecule.cm−3, generated by microwave discharge of water vapor at low pressure. The CE-FRS instrument exhibited a limit of detection of ∼ 1010 molecule.cm−3 in an integration time of 20 s, which is enhanced by a factor of 2.5 compared to cavity-enhanced wavelength modulation spectroscopy involving an off-axis integrated cavity output spectroscopy approach. A time-resolved FRS signal was recorded in a pulsed microwave discharge regime, giving a millisecond time resolution for the measurement of OH concentration profile. The developed instrument provides a potential analytical tool for the measurement of OH concentration for chemical kinetic study in reactor cells.

Skin conductance response and habituation to emotional facial expressions and words.

Skin conductance response (SCR) serves as a dependable marker of sympathetic activation used to measure emotional arousal. This study investigates the impact of presentation modality (face or word) on the degree of emotional discrimination elicited by SCR. Facial expressions or words associated with six basic emotions-anger, happiness, disgust, fear, sadness, and surprise-were studied among 102 participants. The amplitude of SCR was accurately predicted by subjective arousal ratings of these stimuli, but not by valence ratings. The habituation process to emotional and neutral stimuli across six successive presentations was characterized by an exponential decay function, capturing the rate at which SCR response diminishes in relation to the preceding trial of the same stimulus. Through the subtraction of the response to neutral stimuli from the emotion-evoked SCR, it was demonstrated that the initial presentation of each emotion elicits a substantial response, particularly attributable to the emotional content. Notably, the initial emotional response to faces expressing happiness, disgust, and sadness surpassed that of words conveying the same emotions. The results indicate that different emotional responses can be quantified using a simple electrical instrument.

Numerical Treatment for the Caputo-Fabrizio Fractional Smoking Model using an Efficient Numerical Technique

Smoking is a prevalent social behavior widely practiced worldwide, especially in settings such as schools and some significant gatherings. Based on the World Health Organization (WHO), smoking is the third leading source of human mortality and the primary preventable cause of disease. This study introduces a highly efficient simulation technique to analyze and solve the Caputo-Fabrizio (CF) fractional smoking model. We numerically solve the fractional integral equations (FIEs) with Simpson’s 1/3 rule, an effective numerical integration technique. We concentrate on clarifying the stability/convergence of the proposed strategy. We juxtapose the outcomes derived using the Runge-Kutta method (RK4) with those obtained through the implemented methodology. The findings indicate that the used technique provides a simple and efficient instrument for simulating the solution of these models. The principal advantage of the proposed method is its dependence on a limited number of straightforward steps, devoid of long-term consequences or reliance on a perturbation parameter.

Performance of a Radio-Frequency Two-Photon Atomic Magnetometer in Different Magnetic Induction Measurement Geometries.

Measurements monitoring the inductive coupling between oscillating radio-frequency magnetic fields and objects of interest create versatile platforms for non-destructive testing. The benefits of ultra-low-frequency measurements, i.e., below 3 kHz, are sometimes outweighed by the fundamental and technical difficulties related to operating pick-up coils or other field sensors in this frequency range. Inductive measurements with the detection based on a two-photon interaction in rf atomic magnetometers address some of these issues as the sensor gains an uplift in its operational frequency. The developments reported here integrate the fundamental and applied aspects of the two-photon process in magnetic induction measurements. In this paper, all the spectral components of the two-photon process are identified, which result from the non-linear interactions between the rf fields and atoms. For the first time, a method for the retrieval of the two-photon phase information, which is critical for inductive measurements, is also demonstrated. Furthermore, a self-compensation configuration is introduced, whereby high-contrast measurements of defects can be obtained due to its insensitivity to the primary field, including using simplified instrumentation for this configuration by producing two rf fields with a single rf coil.

On the potential of the Cluster Ion Counter (CIC) to observe local new particle formation, condensation sink and growth rate of newly formed particles

Abstract. The Cluster Ion Counter (CIC) is a simple three-channel instrument designed to observe ions in the electrical mobility equivalent diameter range from 1.0 to 5 nm. With the three channels, we can observe concentrations of both ion clusters (sub-2 nm ions) and intermediate ions. Furthermore, as derived here, we can estimate condensation sink (CS), intensity of local new particle formation, growth rate of newly formed particles from 2 to 3 nm and formation rate of 2 nm ions. We compared CIC measurements with those of a multichannel ion spectrometer, the Neutral cluster and Air Ion Spectrometer (NAIS), and found that the concentrations agreed well between the two instruments, with correlation coefficients of 0.89 and 0.86 for sub-2 nm and 2.0–2.3 nm ions, respectively. According to the observations made in Hyytiälä, Finland, and Beijing, China, the ion source rate was estimated to be about two to four ion pairs cm−3 s−1. The new CIC is a simple and cheap instrument that can be used in different environments to obtain information about small ion dynamics, local intermediate ion formation and CS in a robust way when combined with the theoretical framework presented here.

Real-Time Visualization of HIV-1 RNA Detection Using Loop-Mediated Isothermal Amplification-Enabled Particle Diffusometry.

Isothermal nucleic acid amplification tests, NAATs, such as reverse transcription-loop-mediated isothermal amplification (RT-LAMP), offer promising capabilities to perform real-time semiquantitative detection of viral pathogens. These tests provide rapid results, utilize simple instrumentation for single-temperature reactions, support efficient user workflows, and are suitable for field use. Herein, we present a novel and robust method for real-time monitoring of HIV-1 RNA RT-LAMP utilizing a novel implementation of particle diffusometry (PD), a diffusivity quantification technique using fluorescent particles, to quantify viral concentration in nuclease-free water. We monitor changes in particle diffusion dynamics of 400 nm fluorescently labeled particles throughout the RT-LAMP of HIV-1 RNA in nuclease-free water, enabling measurement within 20 min and detection of concentrations as low as 25 virus particles per μL. Moreover, in a single-blind study, we demonstrate semiquantitative detection by accurately determining the initial concentration of an unknown HIV-1 RNA within a 10% absolute error margin. These results highlight the potential of real-time PD readout for quantifying HIV-1 RNA via RT-LAMP, offering promise for viral load monitoring of HIV and other chronic infections.

B-211 Quantum dot-DNA nanocomposite enhanced single-molecule flow (SiM-Flow) for ultrasensitive microRNA detection in metastatic castrate-resistant prostate cancer

Abstract Background MicroRNAs (miRs) like miR-375 and miR-1290 are associated with cancer progression and chemoresistance in metastatic castrate-resistant prostate cancer (mCRPC). However, these prognostic biomarkers are typically present in low abundance (0.1∼1 fM) in patient plasma, which is close to the detection limit of the current gold standard techniques, quantitative reverse-transcriptase polymerase chain reaction (qRT-PCR). Therefore, we tested a nanomaterial that incorporates quantum dots (QDs) and DNA amplicons for enhanced in-solution counting applications in plasma from a cohort of mCRPC patients. The QD-DNA nanocomposite increases the fluorescent intensity of an individual amplicon for ultrasensitive flow-counting and provides higher multiplex capacity due to the narrow emission band of QD for simple instrumentation. Methods QDs were synthesized with spectrally distinct emission bands by tuning the size or composition of CdSe core. QDs were then coated with multidentate polymer allowing further bioconjugations and better solubility in aqueous solution. The oligonucleotides complementary to amplicons generated from selected miR targets (prognostic biomarkers: miR-1290 and miR-375; normalization biomarkers: miR-16, miR-30a-5p, and cel-39) were then conjugated to QDs with optimized ratio. Total RNA was extracted from a screening cohort of 14 mCRPC patients from Huntsman Cancer Institute where platelet-poor plasma was uniformly processed with exogenous spike-in, cel-39, added in. qRT-PCR was performed using TaqMan miRNA assays, and SiM-Flow was conducted using a commercial flow cytometry to count QD barcoded enzymatic-extended miRs nanoparticles. The DNA template used for extending miRs was designed by our lab and purchased from IDT-DNA. Pearson correlation and interclass agreement analysis were applied to evaluate the concordance between the two assays. The mCRPC cohort was followed for clinical outcomes, and survival analysis for the time of progression from mCRPC to death/last follow-up was performed to determine the prognostic value of the QD-DNA nanoparticle counts. The Cox proportional hazards model was applied to linearly incorporate multiple hazard factors of patients for multivariate survival analysis. Results We demonstrated the multiplex ability of QDs with less than 5% false positive rate. The machine learning-guided optimized assay shows a 1000-time improved limit of detection of assay compared to the published literature. Interclass agreement > 0.9 and Pearson correlation of 0.94 between SiM-Flow and RT-qPCR on human plasma extracts suggest high specificity of SiM-Flow on miR detection. Also, miR-375 was identified among all the samples through SiM-Flow, although it was unidentified by qRT-PCR in 14 samples. Higher levels of miR-1290, miR-375, and prostate-specific antigen were significantly associated with poor overall survival (p=0.019) in the initial survival analysis. Survival analysis replication is ongoing in an independent mCRPC cohort. Conclusions SiM-Flow was able to detect target miRs in mCRPC patients’ plasma with a high agreement with qRT-PCR and lower detection limit and demonstrated multiplex ability with a simple optical set-up. This shows technological advancement in the detection of cancer-associated biomarkers and will aid in precision medicine therapeutic and point-of-care applications with both prognostic and predictive potential.

A comparative study of aptasensor vs. immunosensor for ultrasensitive detection of aflatoxin B1 using Ag-pSi SERS substrate

Numerous SERS based platforms have been designed to address the emerging need for detecting fungal metabolite contamination in foodstuffs, and specifically the Group 1 carcinogen aflatoxin B1. Herein, 4-aminothiophenol modified silver-coated porous silicon was used as the SERS substrate. Two ratiometric responses were individually assessed upon direct target capture using specific aptamers or antibodies. Under optimized physical features, elevated enhancement factor, wide dynamic range, low detection limits and pronounced recycling capabilities were achieved (7.39 × 107, 0.2–200 ppb, 0.0085 and 0.0110 ppb, 7 and 1 regeneration cycles without impairing the performances for aptasensor and immunosensor, respectively). The accuracy and anti-interference responses in several intricate matrices (maize, peanut, wheat, oats and rice) were compared to a routine HPLC method with equivalent recoveries. Overall, the comparative assessment revealed preferable features of reusability, durability and accuracy of the aptasensor over the immunosensor. Furthermore, the results demonstrate the substantial potential of the proposed SERS substrate for diverse on-site analytical applications using simple and portable monitoring instrumentation.

Application of loop-mediated isothermal amplification (LAMP) in plant pathogen detection.

Plant diseases impact the production of all kinds of crops, resulting in significant economic losses worldwide. Timely and accurate detection of plant pathogens is crucial for surveillance and management of plant diseases. In recent years, loop-mediated isothermal amplification (LAMP) has become a popular method for pathogen detection and disease diagnosis due to the advantages of its simple instrument requirement and constant reaction temperature. In this review, we provide an overview of current research on LAMP, including the reaction system, design of primers, selection of target regions, visualization of amplicons, and application of LAMP on the detection of all major groups of plant pathogens. We also discuss plant pathogens for which LAMP is yet to be developed, potential improvements of plant disease diagnosis, and disadvantages that need to be considered.

Atomically Fe(Ⅲ) anchored metal-organic frameworks-based fluorescent nanozyme for smartphone-adopted chemiluminescence-fluorescence dual-mode analysis of Uric acid

BackgroundChemiluminescence (CL) analysis is a promising analytical method with advantages including easy operation, high sensitivity and simple instrument. However, the single CL mode usually suffered from poor stability and reproducibility as a result of the flash-type nature of luminescent molecules, leading to false positive or negative results in practical applications. Dual-mode detection is an advanced sensing methodology that identifies analytes through independent output signals. This approach has the ability to circumvent the inherent constraints of individual sensing modes while integrating their respective strengths, thereby yielding a synergistic enhancement in the detection system. ResultsHerein, a chemiluminescence-fluorescence (FL) dual-mode analysis and imaging system is designed by constructing an atomically Fe(Ⅲ) anchored PCN-224 peroxidase-mimicking nanozyme (PCN-224/Fe(Ⅲ)) and achieve an ultrasensitive detection of Uric Acid (UA). The multifunctional PCN-224/Fe(Ⅲ) serves as a high-efficiency co-reaction promoter in the generation of reactive oxygen species (ROS) in both the CL and FL system, while also demonstrating exceptional capabilities as fluorescent nanoprobes. Ultimately, a smartphone-adopted CL imaging device was developed to achieve a visual CL detection through the design of portable paper-based chips. Besides, with the assistance of the TMB-mediated fluorescence energy resonance transfer, the fluorescent PCN-224/Fe(Ⅲ) nanoprobes exhibited good fluorescence detection performance for UA. The limit of detection was achieved as low as 2.45 × 10−10 M and 1.99 × 10−9 M in the CL and FL mode, respectively. SignificanceThis study engineered an atomically Fe(Ⅲ)- MOF-based multifunctional nanozyme and developed an innovative approach for creating CL-FL dual-mode analysis and imaging detection for UA. The proposed CL-FL dual-mode detection system not only provided a portable and sensitive method for UA detection but also offered valuable insights into the mechanism of the co-reaction promoter enhanced CL and FL analysis.

Transverse small incision intrathecal "loop" minimally invasive suture for treatment of acute Achilles tendon rupture

To evaluate the effectiveness and feasibility of a transverse small incision intrathecal "loop" minimally invasive suture for acute Achilles tendon rupture. The clinical data of 30 patients with acute Achilles tendon rupture treated with transverse small incision intrathecal "loop" minimally invasive suture between January 2022 and October 2023 was retrospectively analyzed. The patients were all male, aged from 29 to 51 years, with an average of 39.8 years. The cause of injury was acute sports injury, and the time from injury to operation was 1-14 days, with an average of 3.4 days. The operation time, incision length, intraoperative blood loss, intraoperative complications, wound healing, and hospital stay were recorded. Postoperative appearance and function of ankle were evaluated by American Orthopaedic Foot and Ankle Society (AOFAS) ankle-hindfoot score, Vancouver Scar Scale (VSS) score, and Arner-Lindholm score. The operation time ranged from 30 to 90 minutes, with an average of 54.2 minutes; the incision length ranged from 1.3 to 3.5 cm, with an average of 2.2 cm; the intraoperative blood loss ranged from 5 to 70 mL, with an average of 22.3 mL; and the hospital stay ranged from 2 to 6 days, with an average of 3.7 days. All incisions healed by first intention, and there was no incision infection, poor healing, and deep venous thrombosis. All patients were followed up 5.3-22.0 months (mean, 14.7 months). During the follow-up, all the 30 patients had returned to exercise, and there was no complication such as Achilles tendon re-rupture, postoperative infection, and gastrocnemius muscle injury. At last follow-up, the AOFAS ankle-hindfoot score was 82-100, with an average of 95.1; the VSS score was 1-4, with an average of 2.1; according to the Arner-Lindholm score, 24 cases were rated as excellent and 6 cases as good. Transverse small incision intrathecal "loop" minimally invasive suture for the treatment of acute Achilles tendon rupture has the advantages of simple instrument, convenient operation, small trauma, quick recovery, and satisfactory effectiveness.

Comparative analysis of upper body kinematics in stroke, Parkinson's disease, and healthy subjects: An observational study using IMU-based targeted box and block test

BackgroundThe Box and Block Test (BBT) is an essential and widely used test in rehabilitation for the assessment of gross unilateral manual dexterity. Although it is a valid, simple, and ecological instrument, it does not provide a quantitative measure of the upper limb trajectories during the test. Research questionThe study introduces a new motion-capture-based method (using ecological Inertial Measurement Units - IMUs) to evaluate upper body kinematics while performing a targeted version of BBT (tBBT). MethodsThis observational study compares data from 35 healthy subjects, 35 subjects with Parkinson’s disease, and 35 post-stroke individuals to evaluate upper limb kinematics during tBBT quantitatively. Seven IMUs were placed on the trunk, head, and upper limb of each subject. The joint angles and kinematic scores were calculated and analyzed. Motor task execution time and kinematic scores were statistically correlated with clinical assessment measures. Kruskal-Wallis between groups test and Dunn-Bonferroni post-hoc were used. ResultsThe statistics revealed significant differences (p<0.05) among the three groups. The analyzed joint angles highlight various compensatory strategies in neurological subjects, such as using the trunk to complete a motor task instead of the shoulder and using the wrist instead of the elbow, along with differences in movement fluidity (DimensionLess-Jerk, p<0.05). A positive correlation was found between kinematics and the Fugl-Meyer Assessment-Upper Limb (r=0.7344; p<0.01), and a negative correlation between kinematics and the Unified Parkinson's Disease Rating Scale (r=-0.5286; p<0.01). SignificanceThe quantitative assessments of joint kinematics correlated to clinical assessments could guarantee a new method of assessment of the upper limb in subjects with motor deficits. This would allow to capture new insight into the characteristics of the subject’s disability, with implications for the choice of a personalized rehabilitation treatment focused on the motor recovery of the upper limb.

ASPECTOS QUE CONFEREM COMPLEXIDADE À INTERPRETAÇÃO NA PERSPECTIVA DO INTÉRPRETE EDUCACIONAL DO ENSINO MÉDIO

At the expense of a greater insertion of the deaf in the academic environment, the educational interpreter of Brazilian Sign Language – Libras, has been gaining recognition in relation to the importance of his performance in the teaching process of this student. This study explored the aspects that confer complexity to the interpretation of Portuguese for Libras in the educational environment, aiming to identify, understand and offer reflections on the elements that foster this phenomenon, in order to build new perspectives in the field of action of the educational interpreter of Libras, with emphasis on the collaborative work between the teacher and the educational interpreter. With a unique case study, through the simple self-confrontation instrument proposed by Yves Clot (2010) with an approach in the psychodynamics of work that sought to promote the reflection of one's own action during the work activity. Intertwining the conception of Sobral (2008) and the assumptions of Bakhtin (2009, 2010) that emphasize the dialogic nature of language, it argued that the meaning of words emerges from interaction in specific contexts and the field of translation that there is a need to recreate the dialogue between different cultures and social contexts. Resulting in the survey of the following elements that confer complexity. Resulting in the survey of the following elements that confer complexity to the interpretative act in the educational sphere: I) construction of concepts: from simple to complex; II) collaborative work between the teacher and the educational interpreter; III) emotional aspects in the performance of the educational interpreter.

Polyacrylonitrile‒Chitosan IPN composite scaffolds that closely mimic the human trabecular bone structure for tissue engineering

Successful bone tissue engineering involves managing several important parameters, such as the design of intercommunicating porous structures, pore sizes, and the material and mechanical suitability of the material. In our work, we focused on the preparation of a synthetic scaffold that morphologically mimics the structure of human trabecular bone. The scaffolds were fabricated through the thermal modification (TM) of polyacrylonitrile. The scaffold strength was supported by a crosslinked chitosan supporting network. The prepared scaffold has imprinted pores of the appropriate size to facilitate the ingrowth and proliferation of human osteoblasts throughout the entire pore volume created by a primary porogen, sodium chloride. The resulting material has a dual porous morphological structure, in which adjustable larger pores support cellular ingrowth into the scaffold, whereas smaller pores, created using succinonitrile (SCN) as a secondary porogen, increase the diffusion of oxygen and nutrients to developing cells. The mechanical properties of the scaffold were promoted by the use of a secondary interpenetrating network (IPN) based on chitosan. The incorporation of secondary IPNs led to a significant improvement in the mechanical characteristics of the scaffold. Two crosslinking agents were used: the widely utilized glutaraldehyde (GA) and its green, nontoxic alternative, genipin (GEN).The current study introduces a synthetic scaffold that effectively mimics the structure of human trabecular bone, providing a conducive environment for osteoblast proliferation and ingrowth. We incorporated a dual porous morphology and a secondary IPN based on chitosan and found that the scaffold exhibited improved mechanical properties and nutrient diffusion capabilities. This research highlights the potential of these scaffolds for major advancements in bone tissue engineering, demonstrating their noncytotoxic nature and ability to support the adhesion and proliferation of the human osteosarcoma cell line SAOS-2. The described scaffold preparation technique may offer distinct advantages over current high-end methods such as 3D printing. The primary benefit lies in its very simple instrumentation, which enables the creation of a complex trabecular bone morphology with both macro- and microporosity in the bulk, which is still challenging for common 3D printers. Additionally, IPN with chitosan can be postmodified, substantially expanding the potential applications of these scaffolds.

Investigating the Effect of Singing Bowl Sound on the Level of State-trait Anxiety and Physiological Variables of Patients Awaiting Angiography

PurposeMany patients are anxious and fearful while waiting for angiography, which may negatively affect the performance of this test and their physiological variables. The aim of this study was to investigate the effect of singing bowl sounds on situational anxiety and physiological variables of patients awaiting angiography. DesignA semiexperimental pretest and post-test study. MethodsThis semiexperimental pretest and post-test study with 2 groups was conducted from October 2022 to March 2023 in 60 patients (30 in the intervention group and 30 in the control group) awaiting angiography at the Angiography Department of Rouhani Hospital, affiliated with Babol University of Medical Sciences. One hour before angiography, the intervention group received the singing bowl intervention in addition to routine departmental interventions, whereas the control group received only routine departmental interventions. The State-Trait Anxiety Inventory Form Y-1 was used to measure anxiety. FindingsState-trait anxiety after the intervention was significantly lower in the intervention group than in the control group (P = .00). Systolic and diastolic blood pressure, pulse rate, and respiration were the same in the intervention and control groups before and after the intervention and showed no statistically significant difference (P > .05). ConclusionsThe results indicated that the singing bowl intervention led to an improvement in anxiety in patients waiting for angiography. Considering that this intervention was performed with a simple, cheap, and accessible instrument, it is therefore suggested that this method be used to reduce state-trait anxiety in clinical anxiety-provoking conditions. Since the physiological variables of the patients before and after the intervention showed no statistically significant difference in both groups, it is suggested that the physiological variables should be investigated in future studies and several clinical situations so that a scientific opinion on the effect of the singing bowl on these variables can be given with more certainty.

Dried Blood Matrix as a New Material for the Detection of DNA Viruses.

The gold standard for diagnosing viruses such as the Hepatitis B Virus has remained largely unchanged, relying on conventional methods involving extraction, purification, and polymerase chain reaction (PCR). This approach is hindered by limited availability, as it is time-consuming and requires highly trained personnel. Moreover, it suffers from low recovery rates of the nucleic acid molecules for samples with low copy numbers. To address the challenges of complex instrumentation and low recovery rate of DNA, a drying process coupled with thermal treatment of whole blood is employed, resulting in the creation of a dried blood matrix characterized by a porous structure with a high surface-to-volume ratio where it also inactivates the amplification inhibitors present in whole blood. Drawing on insights from Brunauer-Emmett-Teller (BET)- Barrett-Joyner-Halenda (BJH) analysis, scanning electron microscopy (SEM), and fluorescence recovery after photobleaching (FRAP), detection assay is devised for HBV, as a demonstration, from whole blood with high recovery of DNA and simplified instrumentation achieving a limit of detection (LOD) of 10 IU mL-1. This assay can be completed in <1.5 h using a simple heater, can be applied to other DNA viruses, and is expected to be suitable for point-of-care, especially in low-resource settings.

Comparative Performance of Five Cognitive Screening Tests in a Large Sample of Seniors.

Recent introductions of disease-modifying treatments for Alzheimer's disease have re-invigorated the cause of early dementia detection. Cognitive "paper and pencil" tests represent the bedrock of clinical assessment, because they are cheap, easy to perform, and do not require brain imaging or biological testing. Cognitive tests vary greatly in duration, complexity, sociolinguistic biases, probed cognitive domains, and their specificity and sensitivity of detecting cognitive impairment (CI). Consequently, an ecologically valid head-to-head comparison seems essential for evidence-based dementia screening. We compared five tests: Montreal cognitive assessment (MoCA), Alzheimer's disease assessment scale-cognitive subscale (ADAS), Addenbrooke's cognitive examination (ACE-III), euro-coin handling test (Eurotest), and image identification test (Phototest) on a large sample of seniors (N = 456, 77.9 ± 8 years, 71% females). Their specificity and sensitivity were estimated in a novel way by contrasting each test's outcome to the majority outcome across the remaining tests (comparative specificity and sensitivity calculation [CSSC]). This obviates the need for an a priori gold standard such as a clinically clear-cut sample of dementia/MCI/controls. We posit that the CSSC results in a more ecologically valid estimation of clinical performance while precluding biases resulting from different dementia/MCI diagnostic criteria and the proficiency in detecting these conditions. There exists a stark trade-off between behavioral test specificity and sensitivity. The test with the highest specificity had the lowest sensitivity, and vice versa. The comparative specificities and sensitivities were, respectively: Phototest (97%, 47%), Eurotest (94%, 55%), ADAS (90%, 68%), ACE-III (72%, 77%), MoCA (55%, 95%). Assuming a CI prevalence of 10%, the shortest (∼3 min) and the simplest instrument, the Phototest, was shown to have the best overall performance (accuracy 92%, PPV 66%, NPV 94%).