The document provides an overview of the proposed changes to Michigan's healthcare code to adopt the 2018 FGI Guidelines for Design and Construction of Hospitals and Outpatient Facilities. It discusses the history and purpose of the FGI, differences between the 2007 Michigan code and 2018 FGI Guidelines, and some key environmental and architectural elements such as room use design requirements and handrail specifications. Adopting the 2018 FGI Guidelines will provide a more comprehensive set of standards across various healthcare facility types and disciplines.
The document provides an overview of the proposed changes to Michigan's healthcare code to adopt the 2018 FGI Guidelines for Design and Construction of Hospitals and Outpatient Facilities. It discusses the history and purpose of the FGI, differences between the 2007 Michigan code and 2018 FGI Guidelines, and some key environmental and architectural elements such as room use design requirements and handrail specifications. Adopting the 2018 FGI Guidelines will provide a more comprehensive set of standards across various healthcare facility types and disciplines.
The document provides an instruction manual for the FluorCam instrument, which measures chlorophyll fluorescence to study photosynthesis. It begins with an introduction to chlorophyll fluorescence techniques, explaining how fluorescence yields provide information about photosynthetic energy conversion. It then describes the FluorCam instrument and various models. The manual explains how to assemble, operate, and analyze data from the FluorCam using its software. It provides protocols for capturing fluorescence transients and imaging fluorescence to study spatial heterogeneity and kinetics of photosynthesis.
Phenotyping for crop improvement requires integrated concepts and infrastructure to fully explore its potential. The EMPHASIS project aims to implement a pan-European research infrastructure for plant phenotyping to address challenges in crop development. It is currently in the implementation phase (2019-2021) to establish long-term operations, engage member countries, and set up services to ensure sustainable access. The infrastructure will integrate specialized facilities, environmental controls, and expertise in imaging, sensor techniques, and data analysis to allow quantitative assessment of plant phenotypes across scales from single plants to fields.
This document summarizes an experiment that used an automated plant phenotyping platform to analyze the drought tolerance of different barley genotypes. Two barley accessions (W30 and Abyssinian 1125) that showed contrasting responses to drought were selected. Plants were subjected to a drought period followed by rewatering to evaluate recovery. Throughout, various traits like plant area, chlorophyll fluorescence, and leaf temperature were measured. The results showed that W30 recovered well after rewatering, while Abyssinian 1125 did not recover significantly. This demonstrated different drought tolerance strategies between the two accessions.
The document describes using an automated high-throughput phenotyping platform called PlantScreenTM Conveyer System to visualize and quantify the early stress response of Arabidopsis thaliana plants to the herbicide glyphosate. RGB imaging, chlorophyll fluorescence kinetics imaging, and hyperspectral imaging were used to analyze plant structure, growth, and photosynthetic performance over 72 hours after glyphosate application. Results showed glyphosate impaired growth dynamics after 20 hours and decreased chlorophyll content and photosynthetic performance within 10-13 hours, as indicated by changes in fluorescence parameters, NDVI, and other indices. The study demonstrated how high-throughput phenotyping can help characterize plant stress responses and accelerate crop breeding.
This study used a high-throughput phenotyping platform called PlantScreen System to analyze early plant stress responses under progressive drought conditions. Various imaging techniques were used including RGB imaging, chlorophyll fluorescence imaging, and thermal imaging. Parameters like area, compactness, and maximum fluorescence in the light-adapted state were identified as early discriminants between stressed and control plants. Changes in chlorophyll fluorescence kinetics and decreases in maximum fluorescence occurred in stressed plants after 7-8 days, indicating their potential as early drought stress markers.
1) The study used high-throughput imaging technologies to analyze the early responses of Arabidopsis thaliana plants to salt stress, comparing accessions Col-0 and the more salt-tolerant C24.
2) Within days of salt treatment, plant growth was reduced, photosynthetic performance declined, and color changes occurred, indicating stress. C24 was less affected than Col-0.
3) Quantitative analysis of chlorophyll fluorescence kinetics and imaging data revealed rapid reductions in key photosynthetic parameters and increases in non-photochemical quenching in salt-treated plants, showing immediate physiological impacts of stress.
This document summarizes research using an automated PlantScreen system to study the response of Arabidopsis plants to salt stress. Various Arabidopsis ecotypes were grown under normal conditions then exposed to salt stress. Automated kinetic phenotyping was performed using chlorophyll fluorescence imaging and RGB imaging to analyze plant growth, development, and physiology. Chlorophyll fluorescence measurements identified early response stress markers, with statistically significant differences seen in some parameters like NPQ and Rfd between treated and untreated plants within 48 hours. RGB imaging also tracked morphological changes over time.
This document describes a study that used automated plant phenotyping systems to evaluate the effects of 9 different plant-derived biostimulants on tomato plants under control conditions. High-throughput image-based analysis was used to monitor multiple morphological and physiological traits over time. Preliminary results found that 3 biostimulants (A, E, and H) significantly increased plant growth compared to controls. Additional analysis of chlorophyll fluorescence data may provide insights into effects on photosynthetic efficiency and correlate with growth responses. The automated phenotyping platform allowed detailed non-invasive analysis of biostimulant modes of action on whole plant performance.
This document summarizes an experiment that used high-throughput phenotyping to analyze the growth and photosynthetic performance of two lettuce cultivars (Aquino and Barlach) under control and drought stress conditions over 36 days. Seedlings were grown in a controlled environment chamber and divided into control and stressed plants at 18 days after sowing. Automated imaging and measurements were taken every two days using a PlantScreen system. Both cultivars showed similar reductions in area and photosystem II efficiency under drought, though stress effects appeared earlier in Barlach. Overall, the analysis found the two cultivars responded similarly to drought but Barlach reached a larger size. The high-throughput phenotyping platform allowed precise monitoring
PlantScreen™ Modular Systems | QubitPhenomics.com.pdftachet
Qubit Systems develops modular plant phenotyping systems called PlantScreen for automated multidimensional analysis of plant growth and physiology. The PlantScreen Modular System uses a conveyor to move plants through different imaging stations for traits like color, chlorophyll fluorescence, hyperspectral analysis, and temperature. It also has controlled environment chambers and stations for watering, weighing, and nutrient delivery. Comprehensive software controls the system and stores/analyzes imaging and environmental data. Custom systems can be designed to fit specific research needs.
The document provides an instruction manual for the FluorCam instrument, which measures chlorophyll fluorescence to study photosynthesis. It begins with an introduction to chlorophyll fluorescence techniques, explaining how fluorescence yields provide information about photosynthetic energy conversion. It then describes the FluorCam instrument and various models. The manual explains how to assemble, operate, and analyze data from the FluorCam using its software. It provides protocols for capturing fluorescence transients and imaging fluorescence to study spatial heterogeneity and kinetics of photosynthesis.
Phenotyping for crop improvement requires integrated concepts and infrastructure to fully explore its potential. The EMPHASIS project aims to implement a pan-European research infrastructure for plant phenotyping to address challenges in crop development. It is currently in the implementation phase (2019-2021) to establish long-term operations, engage member countries, and set up services to ensure sustainable access. The infrastructure will integrate specialized facilities, environmental controls, and expertise in imaging, sensor techniques, and data analysis to allow quantitative assessment of plant phenotypes across scales from single plants to fields.
This document summarizes an experiment that used an automated plant phenotyping platform to analyze the drought tolerance of different barley genotypes. Two barley accessions (W30 and Abyssinian 1125) that showed contrasting responses to drought were selected. Plants were subjected to a drought period followed by rewatering to evaluate recovery. Throughout, various traits like plant area, chlorophyll fluorescence, and leaf temperature were measured. The results showed that W30 recovered well after rewatering, while Abyssinian 1125 did not recover significantly. This demonstrated different drought tolerance strategies between the two accessions.
The document describes using an automated high-throughput phenotyping platform called PlantScreenTM Conveyer System to visualize and quantify the early stress response of Arabidopsis thaliana plants to the herbicide glyphosate. RGB imaging, chlorophyll fluorescence kinetics imaging, and hyperspectral imaging were used to analyze plant structure, growth, and photosynthetic performance over 72 hours after glyphosate application. Results showed glyphosate impaired growth dynamics after 20 hours and decreased chlorophyll content and photosynthetic performance within 10-13 hours, as indicated by changes in fluorescence parameters, NDVI, and other indices. The study demonstrated how high-throughput phenotyping can help characterize plant stress responses and accelerate crop breeding.
This study used a high-throughput phenotyping platform called PlantScreen System to analyze early plant stress responses under progressive drought conditions. Various imaging techniques were used including RGB imaging, chlorophyll fluorescence imaging, and thermal imaging. Parameters like area, compactness, and maximum fluorescence in the light-adapted state were identified as early discriminants between stressed and control plants. Changes in chlorophyll fluorescence kinetics and decreases in maximum fluorescence occurred in stressed plants after 7-8 days, indicating their potential as early drought stress markers.
1) The study used high-throughput imaging technologies to analyze the early responses of Arabidopsis thaliana plants to salt stress, comparing accessions Col-0 and the more salt-tolerant C24.
2) Within days of salt treatment, plant growth was reduced, photosynthetic performance declined, and color changes occurred, indicating stress. C24 was less affected than Col-0.
3) Quantitative analysis of chlorophyll fluorescence kinetics and imaging data revealed rapid reductions in key photosynthetic parameters and increases in non-photochemical quenching in salt-treated plants, showing immediate physiological impacts of stress.
This document summarizes research using an automated PlantScreen system to study the response of Arabidopsis plants to salt stress. Various Arabidopsis ecotypes were grown under normal conditions then exposed to salt stress. Automated kinetic phenotyping was performed using chlorophyll fluorescence imaging and RGB imaging to analyze plant growth, development, and physiology. Chlorophyll fluorescence measurements identified early response stress markers, with statistically significant differences seen in some parameters like NPQ and Rfd between treated and untreated plants within 48 hours. RGB imaging also tracked morphological changes over time.
This document describes a study that used automated plant phenotyping systems to evaluate the effects of 9 different plant-derived biostimulants on tomato plants under control conditions. High-throughput image-based analysis was used to monitor multiple morphological and physiological traits over time. Preliminary results found that 3 biostimulants (A, E, and H) significantly increased plant growth compared to controls. Additional analysis of chlorophyll fluorescence data may provide insights into effects on photosynthetic efficiency and correlate with growth responses. The automated phenotyping platform allowed detailed non-invasive analysis of biostimulant modes of action on whole plant performance.
This document summarizes an experiment that used high-throughput phenotyping to analyze the growth and photosynthetic performance of two lettuce cultivars (Aquino and Barlach) under control and drought stress conditions over 36 days. Seedlings were grown in a controlled environment chamber and divided into control and stressed plants at 18 days after sowing. Automated imaging and measurements were taken every two days using a PlantScreen system. Both cultivars showed similar reductions in area and photosystem II efficiency under drought, though stress effects appeared earlier in Barlach. Overall, the analysis found the two cultivars responded similarly to drought but Barlach reached a larger size. The high-throughput phenotyping platform allowed precise monitoring
PlantScreen™ Modular Systems | QubitPhenomics.com.pdftachet
Qubit Systems develops modular plant phenotyping systems called PlantScreen for automated multidimensional analysis of plant growth and physiology. The PlantScreen Modular System uses a conveyor to move plants through different imaging stations for traits like color, chlorophyll fluorescence, hyperspectral analysis, and temperature. It also has controlled environment chambers and stations for watering, weighing, and nutrient delivery. Comprehensive software controls the system and stores/analyzes imaging and environmental data. Custom systems can be designed to fit specific research needs.
2. คูมือการออกแบบอาคารและสภาพแวดลอม
Design and Construction Division
กองแบบแผน กรมสนับสนุนบริการ
กระทรวงสาธารณสุข ปงบประมาณ 2559
MINISTRY Of PUBLIC HEALTH
Department of Health Service Support
กรมสนับสนุนบริการบริการสุขภาพ
กระทรวงสาธารณสุข