Yu-Lin Wang’s research while affiliated with Southern Taiwan University of Science and Technology and other places

High-electron-mobility transistors (HEMTs) are recognized for their high electron mobility, exceptional sensitivity and linear response, making them ideal for precise sensing applications. This study introduces a novel, self-powered monitoring system that integrates a rotating triboelectric nanogenerator (R-TENG) with an AlGaN/GaN HEMT sensor for detecting pH levels, heavy metals (Cr6+, As3+, Pb2+), pesticides (chlorpyrifos) and microplastics (polystyrene) under aquatic conditions. The encapsulated device constructed with acrylic layers and magnetic coupling, operates reliably underwater, achieving a 75 V output at 7 μA at 100 rpm. Demonstrating high pH sensitivity (-13.93 mA/pH) with strong linearity (R2 = 0.98), the HEMT sensor effectively detects pollutants at trace levels, distinguishing concentrations down to nanomolar ranges. Operating at a peak power of 76.64 μW and switching frequency of 60 Hz, this innovative system facilitates continuous, long-term environmental monitoring, harnessing water wave energy to enable sustainable pollutant detection in remote or harsh aquatic environments.

Building on our innovative approach to combatting cancer, this study explores the development of a sophisticated hybrid nanocarrier system leveraging the unique properties of allyl oxide cucurbit[6]uril with galactose clusters (AOQ[6]@Gal) to modify ZIF-8 nanoparticles. These nanoparticles are designed to encapsulate and efficiently deliver the anticancer drugs doxorubicin (DOX) and curcumin (CUR), enhancing their water solubility and stability, while also providing active targeting towards hepatocellular carcinoma cells. The comprehensive characterization of AOQ[6]@Gal@ZIF-8@Drug nanoparticles revealed promising outcomes, including drug loading efficiencies of 9.7% for DOX and 8.3% for CUR, alongside a pH-responsive release profile that ensures effective drug delivery in the tumor microenvironment. Cytotoxicity studies underscored the hybrid system’s superior safety profile, exhibiting minimal toxicity towards normal hepatocytes HL7702 and pronounced cytotoxic effects against hepatocellular carcinoma cells HepG2. These results highlight the hybrid nanocarrier’s potential as a targeted, efficient, and safe platform for the delivery of chemotherapy agents in the treatment of liver cancer.

Solid-liquid triboelectric nanogenerators (SL-TENGs) exhibit significant potential in energy harvesting and sensing. This review explores SL-TENG development, focusing on chemical sensing and biosensing applications. Initially, the working mechanisms of various SL-TENG modes are described. Subsequently, an analysis of surface modifications of contact surfaces and liquids to functionalize chemical sensing and biosensing is explored, including their impact on surface properties and the corresponding effect on device performance related to sensing applications.

Background Stroke survivors in post-acute care frequently experience physiological dysfunction and reduced quality of life. This study aims to assess the impact of the Post-Acute Care Interprofessional Collaborative Practice (PAC-IPCP) program across different care settings, and to identify sensitive tools for assessing physiological functions among post-acute stroke survivors. Methods This retrospective study involved 210 stroke survivors in Taiwan. Participants who self-selection for their preferred between hospital care setting and home care setting under PAC-IPCP. Multiple assessment tools were utilized, including the Barthel Index (BI), Functional Oral Intake Scale (FOIS), Mini Nutritional Assessment (MNA), EQ-5D-3L, and Instrumental Activities of Daily Living (IADL). The logistic regression was used to estimate the odds ratios of various functional assessment tools between hospital and home care settings. Additionally, the area under the ROC curves was used to determine which functional assessment tools had higher accuracy in measuring the association between care settings. Results Of the study population, 138 stroke survivors (65.71%) selection hospital care setting and 72 stroke survivors (34.29%) selection home care setting. The PAC-IPCP program was equally effective in both care settings for physical function status and quality of life improvements. Specifically, the BI emerged as the most sensitive tool for assessing care settings, with an adjusted OR of 1.04 (95% CI:1.02–1.07, p < 0.0001; AUC = 0.7557). IPCP-based hospital and home care models are equally effective in facilitating improved functional outcomes in post-acute stroke survivors. Conclusion The PAC-IPCP program is versatile and effective across care settings. The BI stands out as a robust assessment tool for physiological functions, endorsing its broader clinical application. Future studies should also consider swallowing and nutritional status for a more holistic approach to rehabilitation.

The demand for a faster and more efficient IC has been steadily increasing more than ever to accommodate the trend of Artificial Intelligence, Industry 4.0, Machine Learning, and Big Data. Traditionally, the semiconductor industry has kept up with demand of faster and more efficient IC by shrinking the size of transistor. As we approach a 1 nm transistor the technological challenge will be challenging to overcome as quantum tunneling becomes more pronounced and would decrease the reliability of the chip. To overcome this technological challenge, an advance packaging of 3D IC chip technology has been developed and delivered to market such as CoWoS (Chip-on-Wafer-on-Substrate) and InFO (Integrated Fan-Out). However, the aforementioned technology have their drawbacks with CoWoS uses interposer and TSV (through-silicon substrate via) which make it costly, time consuming, and wastes a lot of energy and InFO is limited in the number of layers it can accommodate for chiplets. Both of those technology are currently limited to 2 or 3 layer of IC and difficult to be modularize. In this study, we aim to develop a heterogeneous 3D IC package that can overcome the aforementioned problem which is modular, cost-effective, able to integrate chip from different manufacturers, and capable to stack more than 3 layers of ICs. This study has successfully completed the first stage of development by employing an advanced package consisting of Epoxy substrate with 200Å Ti/500Å Pt/1000Å Au metal interconnects, previously fabricated as a base for 3D stacking. Keywords : 3D IC Package, Advance Packaging, Modulable IC Packaging, Heterogeneous Integration Figure 1

Klebsiella pneumoniae demonstrates versatility in its pathogenicity, leading to diverse infections in humans such as pneumonia, urinary tract infections, bacteremia, wound infections, meningitis, endocarditis, and sepsis. The severity of these infections is contingent upon the patient's immune status, the site of infection, and the existence of underlying medical comorbidities. A sputum or urine culture, on the other hand, typically takes between 24 and 72 hours to produce results. Over recent years, various innovative methodologies have emerged, including optical and electrochemical techniques and molecular detection via PCR. Despite the diversity of available techniques, concerns persist regarding their sensitivity and specificity. Moreover, fluorescence-based methodologies and Surface Plasmon Resonance (SPR)-based sensors have been explored for bacterial detection. However, these existing methods have drawbacks such as elevated costs, prolonged turnaround times, the need for sophisticated instrumentation, and a demand for skilled personnel. Field-effect transistor (FET) sensors have garnered considerable scientific attention since their inception due to their remarkable sensitivity, facile signal readout, and the capability for label-free assays. The aim of this research is to detect the detect Klebsiella pneumoniae bacteria in blood serum by double electric layer (EDL) extended-gate field-effect transistor (FET) sensor. In this study, a preliminary investigation employed a single-step surface functionalization approach to immobilize receptor probes, specifically single-stranded DNA (ssDNA). This strategy aimed to enable the rapid detection of complementary DNA (cDNA) across varying concentrations, leveraging differential gate voltages to modulate the sensitivity of this analytical platform. The designed probes were successfully immobilized onto a disposable chip housing a pair of gold electrodes. A handheld reader, integrating enhancement-mode N-channel MOSFETs, established connectivity with a laptop via a USB port to facilitate the measurement of sensor signals. By applying pulsed gate voltage to the input electrode, which modulates the channel conductivity which behaves as a function of the charge distribution within the EDL structure, consequently influencing the drain current of the MOSFET. The immobilized probe, positioned on the gate electrode, underwent testing using varying concentrations of cDNA introduced into TE buffer. Detection of probe-target binding occurred through fluorescence alterations and electrically by assessing changes in drain current. In order to improve the response time, we elevated the temperature near the Tm enhances sensitivity and binding rates, in shorter time period of 1 minutes. Figure 1

In the field of sensors, particularly in FETs (Field-Effect Transistors), they have emerged as a promising solution for detecting heavy metal ions. These sensors offer high sensitivity, rapid response, compact and portable device sizes, and the potential for low cost. These advantages have led to their successful application in monitoring drinking water, environmental samples, and industrial wastewater, enabling rapid on-site detection of heavy metal ions. At the molecular level, certain organic molecules or coordination compounds can selectively bind to specific ions through specific chemical reactions or coordination interactions. Therefore, designing ionophores specifically for capturing or transporting particular types of ions is possible. Previous research has employed the mechanism of Ion Selective Membranes (ISM) for detecting heavy metals. However, ISMs are typically polymer coatings applied through spinning, resulting in a thick layer that leads to longer diffusion times, requiring 15 minutes or more to achieve baseline stability, with a detection limit of µM to nM . Many studies have also utilized aptamers for detecting metal ions, but aptamers are typically expensive and require controlled formation of specific structures to bind with ions. They are susceptible to interference signals from pH value or salt concentrations. In environmental or food samples, the presence of heavy metals often needs to be detected. Electric-Double-layer (EDL) sensors exhibit better stability, with a monolayer recognition layer providing shorter detection times and higher sensitivity. This study successfully developed FET (Field-Effect Transistor) metal ionophores based on a specially designed ionophore with a double-layer expanded gate, including mercury ionophore sensors and lead ionophore sensors. By defining a gate sensing area with dimensions of 500 μm x 500 μm, significant detection limits of nM to pM were achieved within minutes. The combination of FETs, EDL, and ionophores in this study's development has resulted in highly efficient, sensitive, selective, and portable detection instruments. Keywords: MOSFET, EDL, Aptamer, Ionophore, Heavy metal Figure 1

Staphylococcus epidermidis is a Gram-positive bacterium which commonly grows in human skin, nasal passages, respiratory tract, intestinal tract, air, and water. Although it is harmless to healthy individuals, immunocompromised patients are at risk of infection, which can lead to severe symptoms. With the increased reliance on antibiotics in hospitals, the antimicrobial resistance of Staphylococcus epidermidis has also risen, pointing out a challenge in clinical treatment. Therefore, the diagnosis of this bacterium has gained significant attention. The aim of this experiment is to detect bloodstream infections (BSIs) in the shortest possible time. The study is intended to be implemented in hospitals to provide a more convenient method for medical professionals to conduct screenings. The approach involves screening for the most common disease sequence, ssDNA, followed by sequential detection of corresponding cDNA, plasmids, and bacteria. To detect bacteria with the least amount of bacteerial load, a novel isothermal amplification method called Loop-mediated isothermal amplification (LAMP) is employed to increase the concentration of DNA of BSIs bacteria before measurement. The overall time required for this process doesn’t exceed one day, significantly increasing speed for the detection of blood-borne bacteria in hospitals. The core mechanism of this platform involves the use of electric-double-layer-gated field-effect-transistors (EDL-gated FETs) to amplify the gate voltage changes generated when the ssDNA binds with complementary DNA. These voltage changes are then converted into numerical values for analysis and interpretation. Currently, the research results show that this biomedical sensor can detect concentrations ranging from 1fM to 1pM. With the assistance of LAMP, it has successfully achieved a concentration of approximately 1yM (10-24 M) and detected with EDL-gated FETs. The experiment was also carried out step by step on simulated clinical specimens. The experiments have found successful serum nucleic acid amplification methods that provide excellent detection limits. Compared with other biomedical sensors in the past, it not only has lower detection limits but also brings features such as faster, more convenient, and more portable. Keywords: EDL, FET, Staphylococcus epidermidis, Biosensor, LAMP Figure 1

According to the latest statistics and analysis by American researchers based on the data from 195 countries worldwide, it has been found that one person in every five people died due to sepsis. The annual death caused by sepsis reaches up to eleven million people, and the number of deaths from sepsis is even higher than those from cancer. We believe that the detection of MRSA is necessary. Staphylococcus aureus is the most common pathogen of sepsis. Methicillin-resistant Staphylococcus aureus (MRSA) or Multiple-resistant Staphylococcus aureus is a distinct strain of Staphylococcus aureus. It has mecA gene which codes for penicillin binding protein 2a (PBP 2A) that will remain active under beta lactams antibiotics. This gives bacterial the ability to grow under concentrations of beta-lactam antibiotics which leads to MRSA's resistance to almost all the different penicillin-type antibiotics including methicillin and other beta-lactamase-resistant penicillins. To detect MRSA in the shortest possible time, we adopt field-effect transistor (FET) biosensor for the real-time detection of binding reactions between DNA probe and cDNA. We select DNA probe sequence of mecA to be the aptamer and immobilize probe DNA which are complementary to the target cDNA on the sensor. This process allows DNA strands to attach to the gold surface. After that, we detect the binding reaction of DNA probe and cDNA by analyzing electrical response of field-effect transistor (FET). We can observe that the Id current changes after cDNA hybridizes with DNA probe. In conclusion, in our research results, Field-effect transistor (FET) biosensor can detect concentration ranging from 1fM to 1pM. In addition, we can achieve other advantages such as more portable, higher sensitivity, real-time monitoring capability, and lower detection limits. With this rapid detection procedure, we can do early diagnosis and treatment, thus improving the quality of human life. Keywords: FET, EDL, Aptamer, DNA, MRSA Figure 1