A Brief Review of OPT101 Sensor Application in Near-Infrared Spectroscopy Instrumentation for Intensive Care Unit Clinics

The optoelectronic sensor OPT101 have merits in advanced optoelectronic response characteristics at wavelength range for medical near-infrared spectroscopy and small-size chip design with build-in trans-impedance amplifier. Our lab is devoted to developing a series of portable near-infrared spectroscopy (NIRS) devices embedded with OPT101 for applications in intensive care unit clinics, based on NIRS principle. Here we review the characteristics and advantages of OPT101 relative to clinical NIRS instrumentation, and the most recent achievements, including early-diagnosis and therapeutic effect evaluation of thrombus, noninvasive monitoring of patients\u27 shock severity, and fatigue evaluation. The future prospect on OPT101 improvements in noninvasive clinical applications is also discussed

Continuous Plant-Based and Remote Sensing for Determination of Fruit Tree Water Status

Climate change poses significant challenges to agricultural productivity, making the efficient management of water resources essential for sustainable crop production. The assessment of plant water status is crucial for understanding plant physiological responses to water stress and optimizing water management practices in agriculture. Proximal and remote sensing techniques have emerged as powerful tools for the non-destructive, efficient, and spatially extensive monitoring of plant water status. This review aims to examine the recent advancements in proximal and remote sensing methodologies utilized for assessing the water status, consumption, and irrigation needs of fruit tree crops. Several proximal sensing tools have proved useful in the continuous estimation of tree water status but have strong limitations in terms of spatial variability. On the contrary, remote sensing technologies, although less precise in terms of water status estimates, can easily cover from medium to large areas with drone or satellite images. The integration of proximal and remote sensing would definitely improve plant water status assessment, resulting in higher accuracy by integrating temporal and spatial scales. This paper consists of three parts: the first part covers current plant-based proximal sensing tools, the second part covers remote sensing techniques, and the third part includes an update on the on the combined use of the two methodologies

Development of an effective and sustainable system to monitor fruit tree water status with precision devices

In recent years, sustainable water resource management has become a significant and debated issue in the agro-environmental context. Agriculture, as one of the major water-consuming sectors, plays a crucial role in water resource management. Indeed, global climate change is leading to a general temperature rising, with a consequent increase in drought phenomena. As a result, this leads to an overuse of water resources for irrigation. Therefore, understanding tree crop responses to water availability is becoming increasingly urgent, aiming to increase their water use efficiency.In this regard, one of the primary objectives of scientific research today is to optimize the use of water resources, minimizing inputs without compromising outputs. Water resource savings alone will lead to increased profits. In recent years, deficit irrigation methods, such as regulated deficit irrigation (RDI) and partial rootzone drying (PRD), have allowed farmers to save water while increasing profit by irrigating only during specific phenological stages or with reduced volumes on alternated sides of the rootzone, inducing the plant to activate physiological mechanisms (partial stomatal closure) useful for maximizing water use efficiency. However, real-time knowledge of fruit tree water requirements with consequent automation of precise irrigation applications would allow farmers to further increase water use efficiency. In this regard, last-generation sensors allow continuous data acquisition directly from the plant, greatly increasing the level of information. The combined use of plant-based proximal sensors can provide highly precise information about its water status. Furthermore, remote sensing technologies allow strategic use of proximal sensors, taking into account the spatial variability of the orchard.Based on these premises, the main objective of this dissertation was to develop an effective and sustainable system for monitoring the water status of fruit trees using proximal and remote sensing technologies. Firstly, the use of plant-based proximal and remote sensing technologies, as well as the combination of the two techniques, was reviewed. Subsequently, some techniques for assessing the water status of young olive trees placed in a growth chamber were tested. In the subsequent trial, fruit growth sensors (fruit gauges) were used to study responses of fruit growth from five different species (peach, mango, olive, orange, and loquat) to vapor pressure deficit. In the last trial, the combined use of proximal and remote sensing technologies was tested for estimating the water status of 'Calatina' olive trees under open field conditions