The need for persistent and competitive scientific research is nothing brand new. Wondering how to find the perfect lab for your next big project? Here are some tips for you!
Research buildings are highly complex structures that must meet a vast range of functional, technical, economic, and legal requirements. They are expensive to build and operate due to constantly changing challenges from new regulations, technologies, personnel changes, and research projects. Contemporary research trends point towards more flexible open plan arrangements that provide greater adaptability to unpredictable future needs. Key tendencies include higher density lab work from automation; larger spatial units that better accommodate groups and legal safety requirements; proximity between office and lab spaces to encourage communication; and smaller building depths for improved daylight, flexibility, and future convertibility. Sustainability, functionality, and architectural quality are also important considerations in research building design.
Neuroscience and Laboratory of the FutureMark Kelly
Mark Kelly has 20 years of experience as an architect and designer, exhibiting work internationally and speaking at conferences on sustainable design and future trends in lab design. He was the Design Director for two major research facilities in Melbourne. The article discusses how laboratory design is shifting towards more collaborative workspaces that attract and retain top talent through amenities like natural light, comfortable meeting areas, and proximity to urban amenities rather than isolated campus locations. Laboratories of the future will be more modular and efficient with shared technical resources, flexible workspaces, and characteristics that improve well-being like access to natural light.
This document summarizes the design and features of the UCSC Biomed building, which incorporates sustainable techniques to reduce energy usage without compromising safety or the environment. The 100,000 square foot building with four floors of labs, offices, and administrative space is located near related research buildings to encourage collaboration. Care was taken to provide daylighting, views, ventilation and comfort while achieving sustainability. Constant volume ventilation systems were implemented to enhance energy efficiency at a lower cost compared to variable air volume systems. The design explored hybrid concepts like natural ventilation and chilled beams to arrive at an appropriate sustainable solution that meets research needs and safety requirements.
How Researchers Can Get Science Done Faster Using an R&D Services MarketplaceSC CTSI at USC and CHLA
Date: Feb 6, 2019
Topic: How Researchers Can Get Science Done Faster Using an R&D Services Marketplace
Speaker: Dr. Zev Wisotsky is a Senior Scientist and R&D Specialist at Science Exchange, where he assists researchers in connecting with the right R&D providers for their experiments and alerts his clients to newly available technologies. Dr. Wisotsky earned his PhD in neuroscience investigating taste detection using fruit fly and mosquito models at UC Riverside. He then completed postdoctoral research at Stanford studying the role of brain regions involved in fear memory and addiction through optogenetic silencing of different brain circuits.
Overview: Science Exchange is an open marketplace for scientific research that breaks down barriers to collaboration and innovation. The platform makes it easy for researchers to access more than 6,000 services from a network of over 2,500 qualified research providers. In this webinar, you will learn how researchers can use Science Exchange to access new technologies, get competitive quotes for specific projects, and order from any service provider under a single, pre-established contract. The presentation will also include examples of successful projects and collaborations, initiated on the Science Exchange platform, that have accelerated breakthrough
How Does California Contribute to The Research and Development of Co-Axial Bl...Semi Probes Inc
California plays a key role in the research and development of co-axial blade probes through its major institutions like Stanford University, Caltech, and UC Berkeley. These probes consist of two concentric blades that rotate independently, allowing for precise measurements. California's culture of collaboration between academia, companies, and government agencies accelerates innovation. The state's researchers are developing applications in minimally invasive surgery, medical imaging, aerodynamic testing, and space exploration. Continued miniaturization and oversight of ethical practices will guide the future of this technology.
The document discusses how architects can expand their role to better support clients' business strategies by integrating diverse knowledge and helping visualize data. It also discusses the need for science facilities to foster interaction among researchers while controlling contamination risks. The proposed design includes open labs and connecting spaces to remove barriers while maintaining separate secure lab and animal housing areas, with an internal "street" providing views of gardens. The design emphasizes flexibility to adapt to changing science needs.
This thesis examines patent trends in applied physics industries using economic models and patent citation data. It proposes an alternative, more dynamic patent policy. The thesis begins with an introduction discussing the importance but also challenges of the patent system. It then reviews the background of patent policy and commercialization of university research. The methods section outlines the use of an economic model and patent citation network analysis. The economic model predicts the response of emerging and developed countries/industries to changes in patent policy. Through case studies and empirical evidence from citation data, the thesis aims to show that a "one-size-fits-all" patent policy is insufficient, and that patent protection should vary depending on factors like industry size and growth patterns.
Research buildings are highly complex structures that must meet a vast range of functional, technical, economic, and legal requirements. They are expensive to build and operate due to constantly changing challenges from new regulations, technologies, personnel changes, and research projects. Contemporary research trends point towards more flexible open plan arrangements that provide greater adaptability to unpredictable future needs. Key tendencies include higher density lab work from automation; larger spatial units that better accommodate groups and legal safety requirements; proximity between office and lab spaces to encourage communication; and smaller building depths for improved daylight, flexibility, and future convertibility. Sustainability, functionality, and architectural quality are also important considerations in research building design.
Neuroscience and Laboratory of the FutureMark Kelly
Mark Kelly has 20 years of experience as an architect and designer, exhibiting work internationally and speaking at conferences on sustainable design and future trends in lab design. He was the Design Director for two major research facilities in Melbourne. The article discusses how laboratory design is shifting towards more collaborative workspaces that attract and retain top talent through amenities like natural light, comfortable meeting areas, and proximity to urban amenities rather than isolated campus locations. Laboratories of the future will be more modular and efficient with shared technical resources, flexible workspaces, and characteristics that improve well-being like access to natural light.
This document summarizes the design and features of the UCSC Biomed building, which incorporates sustainable techniques to reduce energy usage without compromising safety or the environment. The 100,000 square foot building with four floors of labs, offices, and administrative space is located near related research buildings to encourage collaboration. Care was taken to provide daylighting, views, ventilation and comfort while achieving sustainability. Constant volume ventilation systems were implemented to enhance energy efficiency at a lower cost compared to variable air volume systems. The design explored hybrid concepts like natural ventilation and chilled beams to arrive at an appropriate sustainable solution that meets research needs and safety requirements.
How Researchers Can Get Science Done Faster Using an R&D Services MarketplaceSC CTSI at USC and CHLA
Date: Feb 6, 2019
Topic: How Researchers Can Get Science Done Faster Using an R&D Services Marketplace
Speaker: Dr. Zev Wisotsky is a Senior Scientist and R&D Specialist at Science Exchange, where he assists researchers in connecting with the right R&D providers for their experiments and alerts his clients to newly available technologies. Dr. Wisotsky earned his PhD in neuroscience investigating taste detection using fruit fly and mosquito models at UC Riverside. He then completed postdoctoral research at Stanford studying the role of brain regions involved in fear memory and addiction through optogenetic silencing of different brain circuits.
Overview: Science Exchange is an open marketplace for scientific research that breaks down barriers to collaboration and innovation. The platform makes it easy for researchers to access more than 6,000 services from a network of over 2,500 qualified research providers. In this webinar, you will learn how researchers can use Science Exchange to access new technologies, get competitive quotes for specific projects, and order from any service provider under a single, pre-established contract. The presentation will also include examples of successful projects and collaborations, initiated on the Science Exchange platform, that have accelerated breakthrough
How Does California Contribute to The Research and Development of Co-Axial Bl...Semi Probes Inc
California plays a key role in the research and development of co-axial blade probes through its major institutions like Stanford University, Caltech, and UC Berkeley. These probes consist of two concentric blades that rotate independently, allowing for precise measurements. California's culture of collaboration between academia, companies, and government agencies accelerates innovation. The state's researchers are developing applications in minimally invasive surgery, medical imaging, aerodynamic testing, and space exploration. Continued miniaturization and oversight of ethical practices will guide the future of this technology.
The document discusses how architects can expand their role to better support clients' business strategies by integrating diverse knowledge and helping visualize data. It also discusses the need for science facilities to foster interaction among researchers while controlling contamination risks. The proposed design includes open labs and connecting spaces to remove barriers while maintaining separate secure lab and animal housing areas, with an internal "street" providing views of gardens. The design emphasizes flexibility to adapt to changing science needs.
This thesis examines patent trends in applied physics industries using economic models and patent citation data. It proposes an alternative, more dynamic patent policy. The thesis begins with an introduction discussing the importance but also challenges of the patent system. It then reviews the background of patent policy and commercialization of university research. The methods section outlines the use of an economic model and patent citation network analysis. The economic model predicts the response of emerging and developed countries/industries to changes in patent policy. Through case studies and empirical evidence from citation data, the thesis aims to show that a "one-size-fits-all" patent policy is insufficient, and that patent protection should vary depending on factors like industry size and growth patterns.
Basic design and organisation of diagnostic laboratoryRohit Hari
This document discusses the organization and design of diagnostic laboratories. It begins by introducing the importance of laboratory design and organization. Key documents like organizational charts and procedure manuals describe how personnel, equipment, and facilities are integrated. The document then discusses four major changes in laboratory design: 1) Open-plan designs for flexibility, 2) Increased automation testing, 3) Incorporation of biosafety level 3 containment, and 4) Growth of molecular testing. Ten steps for an efficient laboratory layout are also outlined. The document concludes that well-designed laboratories provide flexibility for future growth and ability to incorporate new technologies.
REVOLUTIONIZING RESEARCH: CUTTING-EDGE TECHNOLOGIES IN LAB EQUIPMENTFalcon Geomatics LLC
Let's take a closer look at some of the most exciting innovations revolutionizing research in laboratories worldwide.
Know More: https://www.falcon-geosystems.com/scientific-equipment/
Designing and building a forensic laboratory is a complicated undertaking. Design issues include those considerations present when designing any building, with enhanced concern and special requirements involving environmental health and safety, hazardous materials, management, operational efficiency, adaptability, security of evidence, preservation of evidence in an uncontaminated state, as well as budgetary concerns.
A well-known incubator manufacturer in India is Microsil India. Modern tools are available from us for study, evaluation, and testing in a variety of scientific disciplines. We guarantee easy integration of our scientific equipment into various laboratory setups thanks to our broad product line and team of qualified professionals. This enables researchers to make significant advances in their specialties.
https://www.microsilindia.com/incubator-manufacturers-in-india/
Big Data, Computational Biology & the Future of Strategic Planning for ResearchNBBJDesign
The advent of computational biology in the era of “big data” is triggering a dramatic change in the strategic capital planning process and metrics for space allocation and utilization for translational science. In this presentation, Andy Snyder - Principal and NBBJ's Science & Education Practice leader, and Bruce Stevenson, VP of Research Operations at Nationwide Childrens Hospital - chart new relationships between strategic planning, programming, facility planning and scientific workplace features for biomedical research and translational medicine. The presentation sets out new best practices for navigating limited funding resources while preparing for new science directions and workforce needs, research space requirements, and advancements in scientific equipment, and they identify new ways to leverage data, metrics, analytical processes, and tools for improved program/infrastructure alignment.
This document provides an overview of industrial engineering. It begins by defining industrial engineering and its focus on increasing productivity by eliminating waste. It then discusses some of the key techniques used in industrial engineering like job design and facility layout. Several sections provide more details on topics like the evolution of scientific management, functions of industrial engineering, fields of application, and manufacturing versus outsourcing decisions. Overall, the document gives a broad introduction to the core concepts and practices of the industrial engineering profession.
The document discusses printable spacecraft using flexible printed electronics. It finds the concept viable due to commercial market growth in printed electronics. It identifies opportunities for science missions using large fleets of low-cost printed spacecraft. While sensor and subsystem capabilities vary, gaps exist but can be addressed. The document proposes a technology investment strategy focusing on system design, sensor development, and environmental testing to advance printable spacecraft.
Metadata and Semantics Research Conference, Manchester, UK 2015
Research Objects: why, what and how,
In practice the exchange, reuse and reproduction of scientific experiments is hard, dependent on bundling and exchanging the experimental methods, computational codes, data, algorithms, workflows and so on along with the narrative. These "Research Objects" are not fixed, just as research is not “finished”: codes fork, data is updated, algorithms are revised, workflows break, service updates are released. Neither should they be viewed just as second-class artifacts tethered to publications, but the focus of research outcomes in their own right: articles clustered around datasets, methods with citation profiles. Many funders and publishers have come to acknowledge this, moving to data sharing policies and provisioning e-infrastructure platforms. Many researchers recognise the importance of working with Research Objects. The term has become widespread. However. What is a Research Object? How do you mint one, exchange one, build a platform to support one, curate one? How do we introduce them in a lightweight way that platform developers can migrate to? What is the practical impact of a Research Object Commons on training, stewardship, scholarship, sharing? How do we address the scholarly and technological debt of making and maintaining Research Objects? Are there any examples
I’ll present our practical experiences of the why, what and how of Research Objects.
Access the webinar: http://goo.gl/p08pTz
These slides were presented in a webinar by Denodo in collaboration with BioStorage Technologies and Indiana Clinical and Translational Sciences Institute and Regenstrief Institute.
BioStorage Technologies, Inc., Indiana Clinical and Translational Sciences Institute, and Regenstrief Institute (CTSI) have joined Denodo to talk about the important role of technological advancements, such as data virtualization, in advancing biospecimen research.
By watching this webinar, you can gain insight into best practices around the integration of biospecimen and research data as well as technology solutions that provide consolidated views and rapid conversions of this data into valuable business insights. You will also learn how data virtualization can assist with the integration of data residing in heterogeneous repositories and can securely deliver aggregated data in real-time.
Open access policies: The role of research librariesIryna Kuchma
The document discusses various roles and services a research library can provide to support open access policies and practices at a university. It outlines how a library's scholarly communications office can provide guidance and consultations to faculty on copyright, open access publishing options, and depositing work in institutional repositories. It also discusses how libraries can help with adopting open access policies, managing open access journals and books, supporting open educational resources, and hosting open data.
Elizabeth Iorns (Science Exchange) - Research 2.0 presentationScience Exchange
Science Exchange is an online marketplace that connects scientists seeking specialized research services with providers that can perform those services. It allows over 1,000 providers from over 400 research institutions to list over 1,100 experiment types. Researchers can search for services, get quotes, and easily pay providers. This marketplace aims to increase access to expertise, save researchers time and money, and improve transparency around the costs of scientific experiments.
King Abdullah University of Science and Technology (KAUST) established a state-of-the-art Scientific Visualization Core Laboratory with advanced visualization facilities including a six-sided immersive virtual reality environment and multiple tiled display walls. The lab facilitates research in 3D geological structures, oceanography, and infrastructure impacts from natural hazards. It partners with the University of California, San Diego's California Institute for Telecommunications and Information Technology to develop the facilities and conduct visualization projects.
Brooks Automation and BioCision have partnered to develop new technologies for improved temperature control and standardization in sample management. Both companies bring expertise that can be combined - BioCision in mobile temperature products and Brooks Automation in automated sample storage systems. They will work together on adaptable, scalable products to meet current needs as well as integrate with existing systems. Brooks Automation also invested $4 million in BioCision. The collaboration aims to set new benchmarks in precision sample handling for industries like biobanking and cell therapy research that require stringent temperature control.
The key technological advances in assay development in recent years have been the use of magnetic microspheres and polymer beads as the solid phase in automated immunoassays. This has enabled automation, faster reactions, increased sensitivity, and shorter assay times. Magnetic beads and polymer beads allow assays to work in three dimensions, dramatically increasing surface area and sensitivity compared to traditional ELISAs or coated tubes. IVD manufacturers must consider factors like accuracy, reproducibility, stability, and ease of adaptation when developing assays for instrument systems. Forming collaborations with academic researchers is important for assay development to help discover new biomarkers and opportunities to add new tests.
The Department of Energy's Integrated Research Infrastructure (IRI)Globus
We will provide an overview of DOE’s IRI initiative as it moves into early implementation, what drives the IRI vision, and the role of DOE in the larger national research ecosystem.
The document discusses data management plan requirements for proposals submitted to the U.S. Department of Energy Office of Science for research funding. It provides context on the history of data management policies, outlines the four main requirements for inclusion of a data management plan, and suggests elements that should be included in the plan such as data types/sources, content/format, sharing/preservation, and protection. It also discusses tools like the Public Access Gateway for Energy and Science that can help manage access to research publications and data.
141008_Kane Hall Programming and Planning MeetingMKThink Strategy
This document summarizes a meeting to discuss the space blocking and program layout for University of California Hastings College of the Law. It reviews the proposed conceptual organizational model which groups clinics, centers, and other program spaces. Requirements for enclosed spaces like offices are also reviewed, noting additional walls, electrical, lighting, HVAC, and other systems needed. Standard office sizes are established for different user types. A breakdown of proposed square footage allocations is also provided.
The document discusses the growing trend of companies outsourcing their laboratory operations to independent testing providers over the past decade. It provides perspectives from industry experts on why outsourcing has become more popular. Reasons include allowing companies to reduce costs by transitioning from fixed laboratory costs to variable usage-based costs through external partners who can provide broader capabilities and expertise. Outsourcing also allows companies to avoid large capital investments and focus on their core competencies rather than laboratory administration. The trend is expected to continue growing as companies increasingly view laboratory testing as non-essential and seek to improve efficiency.
Presentation by Mike Jones (Lab Automation Assoc. Director) seconded into my team at the SmartLab Exchange Europe conference in Berlin on 8th February (https://smartlabexchangeeurope.iqpc.co.uk/). Brief overview about the future of scientific labs and how digital transformations are changing our approach to data capture, advanced analytics and collaboration across different scientific teams. Examples include exploratory work in augmented reality, next generation interaction, smart touch interfaces and sensor technologies.
Basic architectural design considerations for a laboratorydaniel921829
The document provides guidance on basic considerations for designing a laboratory. It discusses classifications of wet and dry labs and concepts for lab planning such as zoning lab and non-lab areas, circulation, and module design. Key factors covered include flexibility, functionality, safety, aesthetics, and cost-effectiveness. The document emphasizes identifying user needs, allowing for future expansion, and integrating mechanical, electrical and plumbing systems during initial planning to reduce costs and facilitate operations.
BEST FARMLAND FOR SALE | FARM PLOTS NEAR BANGALORE | KANAKAPURA | CHICKKABALP...knox groups real estate
welcome to knox groups real estate company in Bangalore. best farm land for sale near Bangalore and madhugiri . Managed farmland near Kanakapura and Chickkabalapur get know more details about the projects .Knox groups is a leading real estate company dedicated to helping individuals and businesses navigate the dynamic real estate market. With our extensive knowledge, experience, and commitment to excellence, we deliver exceptional results for our clients. Discover the perfect foundation for your agricultural aspirations with KNOX Groups' prime farm lands. These aren't just plots; they're the fertile grounds where vibrant crops flourish, livestock thrives, and unique agricultural ventures come to life. At KNOX, we go beyond selling land we curate sustainable ecosystems, ensuring that your journey toward agricultural success is seamless and prosperous.
Recent Trends Fueling The Surge in Farmhouse Demand in IndiaFarmland Bazaar
Embarking on the journey to acquire a farmhouse for sale is just the beginning; the real investment lies in crafting an environment that contributes to our mental and physical well-being while satisfying the soul. At Farmlandbazaar.com, India’s leading online marketplace dedicated to farm land, farmhouses, and agricultural lands, we understand the importance of transforming a humble farmland into a warm and inviting sanctuary. Let's explore the fundamental aspects that can elevate your farmhouse into a tranquil haven.
More Related Content
Similar to 5 Things to Consider When Leasing a Lab Space | BLR District
Basic design and organisation of diagnostic laboratoryRohit Hari
This document discusses the organization and design of diagnostic laboratories. It begins by introducing the importance of laboratory design and organization. Key documents like organizational charts and procedure manuals describe how personnel, equipment, and facilities are integrated. The document then discusses four major changes in laboratory design: 1) Open-plan designs for flexibility, 2) Increased automation testing, 3) Incorporation of biosafety level 3 containment, and 4) Growth of molecular testing. Ten steps for an efficient laboratory layout are also outlined. The document concludes that well-designed laboratories provide flexibility for future growth and ability to incorporate new technologies.
REVOLUTIONIZING RESEARCH: CUTTING-EDGE TECHNOLOGIES IN LAB EQUIPMENTFalcon Geomatics LLC
Let's take a closer look at some of the most exciting innovations revolutionizing research in laboratories worldwide.
Know More: https://www.falcon-geosystems.com/scientific-equipment/
Designing and building a forensic laboratory is a complicated undertaking. Design issues include those considerations present when designing any building, with enhanced concern and special requirements involving environmental health and safety, hazardous materials, management, operational efficiency, adaptability, security of evidence, preservation of evidence in an uncontaminated state, as well as budgetary concerns.
A well-known incubator manufacturer in India is Microsil India. Modern tools are available from us for study, evaluation, and testing in a variety of scientific disciplines. We guarantee easy integration of our scientific equipment into various laboratory setups thanks to our broad product line and team of qualified professionals. This enables researchers to make significant advances in their specialties.
https://www.microsilindia.com/incubator-manufacturers-in-india/
Big Data, Computational Biology & the Future of Strategic Planning for ResearchNBBJDesign
The advent of computational biology in the era of “big data” is triggering a dramatic change in the strategic capital planning process and metrics for space allocation and utilization for translational science. In this presentation, Andy Snyder - Principal and NBBJ's Science & Education Practice leader, and Bruce Stevenson, VP of Research Operations at Nationwide Childrens Hospital - chart new relationships between strategic planning, programming, facility planning and scientific workplace features for biomedical research and translational medicine. The presentation sets out new best practices for navigating limited funding resources while preparing for new science directions and workforce needs, research space requirements, and advancements in scientific equipment, and they identify new ways to leverage data, metrics, analytical processes, and tools for improved program/infrastructure alignment.
This document provides an overview of industrial engineering. It begins by defining industrial engineering and its focus on increasing productivity by eliminating waste. It then discusses some of the key techniques used in industrial engineering like job design and facility layout. Several sections provide more details on topics like the evolution of scientific management, functions of industrial engineering, fields of application, and manufacturing versus outsourcing decisions. Overall, the document gives a broad introduction to the core concepts and practices of the industrial engineering profession.
The document discusses printable spacecraft using flexible printed electronics. It finds the concept viable due to commercial market growth in printed electronics. It identifies opportunities for science missions using large fleets of low-cost printed spacecraft. While sensor and subsystem capabilities vary, gaps exist but can be addressed. The document proposes a technology investment strategy focusing on system design, sensor development, and environmental testing to advance printable spacecraft.
Metadata and Semantics Research Conference, Manchester, UK 2015
Research Objects: why, what and how,
In practice the exchange, reuse and reproduction of scientific experiments is hard, dependent on bundling and exchanging the experimental methods, computational codes, data, algorithms, workflows and so on along with the narrative. These "Research Objects" are not fixed, just as research is not “finished”: codes fork, data is updated, algorithms are revised, workflows break, service updates are released. Neither should they be viewed just as second-class artifacts tethered to publications, but the focus of research outcomes in their own right: articles clustered around datasets, methods with citation profiles. Many funders and publishers have come to acknowledge this, moving to data sharing policies and provisioning e-infrastructure platforms. Many researchers recognise the importance of working with Research Objects. The term has become widespread. However. What is a Research Object? How do you mint one, exchange one, build a platform to support one, curate one? How do we introduce them in a lightweight way that platform developers can migrate to? What is the practical impact of a Research Object Commons on training, stewardship, scholarship, sharing? How do we address the scholarly and technological debt of making and maintaining Research Objects? Are there any examples
I’ll present our practical experiences of the why, what and how of Research Objects.
Access the webinar: http://goo.gl/p08pTz
These slides were presented in a webinar by Denodo in collaboration with BioStorage Technologies and Indiana Clinical and Translational Sciences Institute and Regenstrief Institute.
BioStorage Technologies, Inc., Indiana Clinical and Translational Sciences Institute, and Regenstrief Institute (CTSI) have joined Denodo to talk about the important role of technological advancements, such as data virtualization, in advancing biospecimen research.
By watching this webinar, you can gain insight into best practices around the integration of biospecimen and research data as well as technology solutions that provide consolidated views and rapid conversions of this data into valuable business insights. You will also learn how data virtualization can assist with the integration of data residing in heterogeneous repositories and can securely deliver aggregated data in real-time.
Open access policies: The role of research librariesIryna Kuchma
The document discusses various roles and services a research library can provide to support open access policies and practices at a university. It outlines how a library's scholarly communications office can provide guidance and consultations to faculty on copyright, open access publishing options, and depositing work in institutional repositories. It also discusses how libraries can help with adopting open access policies, managing open access journals and books, supporting open educational resources, and hosting open data.
Elizabeth Iorns (Science Exchange) - Research 2.0 presentationScience Exchange
Science Exchange is an online marketplace that connects scientists seeking specialized research services with providers that can perform those services. It allows over 1,000 providers from over 400 research institutions to list over 1,100 experiment types. Researchers can search for services, get quotes, and easily pay providers. This marketplace aims to increase access to expertise, save researchers time and money, and improve transparency around the costs of scientific experiments.
King Abdullah University of Science and Technology (KAUST) established a state-of-the-art Scientific Visualization Core Laboratory with advanced visualization facilities including a six-sided immersive virtual reality environment and multiple tiled display walls. The lab facilitates research in 3D geological structures, oceanography, and infrastructure impacts from natural hazards. It partners with the University of California, San Diego's California Institute for Telecommunications and Information Technology to develop the facilities and conduct visualization projects.
Brooks Automation and BioCision have partnered to develop new technologies for improved temperature control and standardization in sample management. Both companies bring expertise that can be combined - BioCision in mobile temperature products and Brooks Automation in automated sample storage systems. They will work together on adaptable, scalable products to meet current needs as well as integrate with existing systems. Brooks Automation also invested $4 million in BioCision. The collaboration aims to set new benchmarks in precision sample handling for industries like biobanking and cell therapy research that require stringent temperature control.
The key technological advances in assay development in recent years have been the use of magnetic microspheres and polymer beads as the solid phase in automated immunoassays. This has enabled automation, faster reactions, increased sensitivity, and shorter assay times. Magnetic beads and polymer beads allow assays to work in three dimensions, dramatically increasing surface area and sensitivity compared to traditional ELISAs or coated tubes. IVD manufacturers must consider factors like accuracy, reproducibility, stability, and ease of adaptation when developing assays for instrument systems. Forming collaborations with academic researchers is important for assay development to help discover new biomarkers and opportunities to add new tests.
The Department of Energy's Integrated Research Infrastructure (IRI)Globus
We will provide an overview of DOE’s IRI initiative as it moves into early implementation, what drives the IRI vision, and the role of DOE in the larger national research ecosystem.
The document discusses data management plan requirements for proposals submitted to the U.S. Department of Energy Office of Science for research funding. It provides context on the history of data management policies, outlines the four main requirements for inclusion of a data management plan, and suggests elements that should be included in the plan such as data types/sources, content/format, sharing/preservation, and protection. It also discusses tools like the Public Access Gateway for Energy and Science that can help manage access to research publications and data.
141008_Kane Hall Programming and Planning MeetingMKThink Strategy
This document summarizes a meeting to discuss the space blocking and program layout for University of California Hastings College of the Law. It reviews the proposed conceptual organizational model which groups clinics, centers, and other program spaces. Requirements for enclosed spaces like offices are also reviewed, noting additional walls, electrical, lighting, HVAC, and other systems needed. Standard office sizes are established for different user types. A breakdown of proposed square footage allocations is also provided.
The document discusses the growing trend of companies outsourcing their laboratory operations to independent testing providers over the past decade. It provides perspectives from industry experts on why outsourcing has become more popular. Reasons include allowing companies to reduce costs by transitioning from fixed laboratory costs to variable usage-based costs through external partners who can provide broader capabilities and expertise. Outsourcing also allows companies to avoid large capital investments and focus on their core competencies rather than laboratory administration. The trend is expected to continue growing as companies increasingly view laboratory testing as non-essential and seek to improve efficiency.
Presentation by Mike Jones (Lab Automation Assoc. Director) seconded into my team at the SmartLab Exchange Europe conference in Berlin on 8th February (https://smartlabexchangeeurope.iqpc.co.uk/). Brief overview about the future of scientific labs and how digital transformations are changing our approach to data capture, advanced analytics and collaboration across different scientific teams. Examples include exploratory work in augmented reality, next generation interaction, smart touch interfaces and sensor technologies.
Basic architectural design considerations for a laboratorydaniel921829
The document provides guidance on basic considerations for designing a laboratory. It discusses classifications of wet and dry labs and concepts for lab planning such as zoning lab and non-lab areas, circulation, and module design. Key factors covered include flexibility, functionality, safety, aesthetics, and cost-effectiveness. The document emphasizes identifying user needs, allowing for future expansion, and integrating mechanical, electrical and plumbing systems during initial planning to reduce costs and facilitate operations.
Similar to 5 Things to Consider When Leasing a Lab Space | BLR District (20)
BEST FARMLAND FOR SALE | FARM PLOTS NEAR BANGALORE | KANAKAPURA | CHICKKABALP...knox groups real estate
welcome to knox groups real estate company in Bangalore. best farm land for sale near Bangalore and madhugiri . Managed farmland near Kanakapura and Chickkabalapur get know more details about the projects .Knox groups is a leading real estate company dedicated to helping individuals and businesses navigate the dynamic real estate market. With our extensive knowledge, experience, and commitment to excellence, we deliver exceptional results for our clients. Discover the perfect foundation for your agricultural aspirations with KNOX Groups' prime farm lands. These aren't just plots; they're the fertile grounds where vibrant crops flourish, livestock thrives, and unique agricultural ventures come to life. At KNOX, we go beyond selling land we curate sustainable ecosystems, ensuring that your journey toward agricultural success is seamless and prosperous.
Recent Trends Fueling The Surge in Farmhouse Demand in IndiaFarmland Bazaar
Embarking on the journey to acquire a farmhouse for sale is just the beginning; the real investment lies in crafting an environment that contributes to our mental and physical well-being while satisfying the soul. At Farmlandbazaar.com, India’s leading online marketplace dedicated to farm land, farmhouses, and agricultural lands, we understand the importance of transforming a humble farmland into a warm and inviting sanctuary. Let's explore the fundamental aspects that can elevate your farmhouse into a tranquil haven.
Discover Yeni Eyup Evleri 2, nestled among the rising values of Eyupsultan, offering the epitome of modern living in Istanbul.
With its spacious living areas, contemporary architecture, and meticulous details, Yeni Eyup Evleri 2 is poised to be the star of your happiest moments. Situated in the new favorite district of Eyupsultan, claim your spot and unlock the doors to a peaceful life alongside your loved ones. Nestled next to the historical and natural beauties of Eyupsultan, embrace the comfort of modern living and rediscover life.
Social Amenities:
Yeni Eyup 2 offers a life filled with joy with its green landscaping areas, gym, sauna, children’s play areas, café, outdoor pool, and basketball court. Reserve your place for unforgettable moments!
Reliable Structure:
With 1+1, 2+1, and 3+1 apartment options, Yeni Eyup Evleri 2 is designed with first-class materials and craftsmanship. The doors to a safe and comfortable life are here! Choose the option that suits you best and step into your dream home.
Project:
Yeni Eyup 2 is conveniently located, with Istanbul Airport just 26 minutes away, the Mecidiyeköy Metro Line 4 minutes away, and the Tram Stop 5 minutes away, making your life easier with its central location.
Location:
Your home is positioned in a privileged location, providing easy access to the city center, shopping malls, restaurants, schools, and other important places.
Yeni Eyup 2 offers 1+1, 2+1, and 3+1 apartment options designed to meet different needs. Find an option suitable for every lifestyle and open the doors to a comfortable life in your dream home.
https://listingturkey.com/property/yeni-eyup-evleri-2/
AVRUPA KONUTLARI ESENTEPE - ENGLISH - Listing TurkeyListing Turkey
Looking for a new home in Istanbul? Look no further than Avrupa Konutlari Esentepe! Our beautifully designed homes provide the perfect blend of luxury and comfort, making them the perfect choice for anyone looking for a high-quality home in the city.
With a wide range of apartment types available, from 1+1 to 4+1, we have something to suit every need and budget. Each apartment is designed with attention to detail and features spacious and bright living areas, making them the perfect place to relax and unwind after a long day.
One of the things that sets Avrupa Konutlari Esentepe apart from other developments is our focus on creating a community that is both comfortable and convenient. Our homes are surrounded by lush green spaces, perfect for enjoying a peaceful stroll or having a picnic with friends and family. Additionally, our complex includes a variety of social and recreational amenities, such as swimming pools, sports fields, and playgrounds, making it easy for residents to stay active and socialize with their neighbors.
https://listingturkey.com/property/avrupa-konutlari-esentepe/
The SVN® organization shares a portion of their new weekly listings via their SVN Live® Weekly Property Broadcast. Visit https://svn.com/svn-live/ if you would like to attend our weekly call, which we open up to the brokerage community.
Serviced Apartment Ho Chi Minh For RentalGVRenting
GVRenting is the leading rental real estate company in Vietnam. We help you to find a serviced apartment for rent in Ho Chi Minh & Saigon. Discover our broad range of rental properties in Vietnam.
For more details https://gvrenting.com/
5 Things to Consider When Leasing a Lab Space | BLR District
1. Things to Consider When Leasing a Lab Space
The COVID-19 pandemic propelled a whole round of research labs, and this isn’t some random
fact pulled out of thin air. In fact, according to the reports by The Wall Street Journal, more than
31 million square feet of life-science spaces were under development by the fourth quadrant of
2021.
Source: (https://www.wsj.com/articles/demand-for-science-lab-buildings-soars-during-covid-
19-pandemic-11646139601)
The need for persistent and competitive scientific research is nothing brand new. Although two
years of a global pandemic under our belts skyrocketed the demand for quality life science lab
space, the need for science lab rental was always on the rise. However, finding the perfect space
to complement your R&D objectives is no easy feat. Wondering how to find the perfect lab for
your next big project? Here are some tips for you!
Location and Accessibility:
When it comes to leasing a lab space, location is of utmost importance. Consider the proximity
of the lab space to other research institutions, universities, and industrial hubs. A location that
fosters collaboration and provides access to resources, expertise, and potential partnerships can
be invaluable in advancing your research. Additionally, ensure that the lab space is easily
accessible for your team and any visitors, considering factors such as transportation, parking,
and proximity to amenities.
Infrastructure and Facilities:
2. A well-designed and equipped laboratory infrastructure is essential for carrying out life science
research effectively. Evaluate the layout and functionality of the lab space, ensuring it is
adaptable to your specific research requirements. Consider factors such as the availability of
fume hoods, safety features, temperature, and humidity control, waste disposal systems, and
adequate storage space for chemicals, reagents, and equipment. Furthermore, assess the
availability and quality of utilities, such as electricity, water, and ventilation systems, as they
directly impact the reliability and efficiency of your experiments.
Compliance and Regulations:
In the life sciences field, adherence to regulatory guidelines and compliance with safety
standards are paramount. Before leasing a lab space, familiarize yourself with the relevant local,
state, and federal regulations that govern research facilities. Ensure the lab space meets these
requirements and has the necessary certifications, permits, and licenses. Compliance with
regulations not only ensures the safety of your team but also safeguards the integrity and
validity of your research.
Scalability and Flexibility:
As your research progresses and your team grows, it is crucial to consider the scalability and
flexibility of the lab space. Assess the potential for expansion or modification of the space to
accommodate future needs. This could include the availability of additional rooms, benches, or
office spaces. Flexibility in terms of lease terms and the ability to customize the space according
to your research requirements can be advantageous in the long run.
Supportive Ecosystem:
Consider the ecosystem surrounding the lab space. Are there opportunities for collaboration,
networking, and knowledge sharing with other researchers or companies in the area? An
ecosystem that fosters innovation and provides access to resources, funding, and mentorship
can significantly enhance your research capabilities. Look for nearby academic institutions,
incubators, or technology parks that can offer support and create synergistic relationships.
Conclusion
Reconfiguring biotech labs for concise R&D results worked in the past, but now it’s simply time-
consuming and expensive. As life science companies increasingly eschew conventional lab
design to keep up with the pace of innovation, finding the best life science real estate
developers for agile lab spaces has become imperative.
The need to shorten product pipelines and cost pressures have become the changing definition
of a desirable laboratory facility, and leasing a science lab can open new doors for innovation,
technology, and top talents to be dynamic and accommodate the change in their life science
research facility.
Blog Source Url:- https://blrdistrict.in/blog/things-to-consider-when-leasing-a-lab-space/