下载PDF
A High-Dimensional Space-filling DOE for Assay Development
技术
- 分析与建模 - 预测分析
- 应用基础设施与中间件 - 数据可视化
- 功能应用 - 远程监控系统
适用行业
- 药品
- 生命科学
适用功能
- 产品研发
- 质量保证
用例
- 预测性维护
- 过程控制与优化
- 数字孪生
服务
- 系统集成
- 软件设计与工程服务
挑战
Pharmaceutical assay development groups work under constant time pressure and face increasing complexity without a commensurate increase in resources. As a result, these groups often adopt powerful statistical approaches such as DOE to shorten assay development cycles. DOE investigations enable the rapid optimization of many inputs and parameters simultaneously, offering the ability to quickly and easily execute and analyze higher-granularity, multifactorial characterizations of biological processes. Yet conventional DOE campaigns executed by hand still require weeks of iterative cycles, as the number of runs possible per cycle is limited by the need to minimize the complexity of manual calculation, liquid handling, and data collection tasks to avoid human error. The challenge for assay development is to increase the speed and accuracy of DoE campaigns by reducing time spent on planning, data aggregation, protocol execution, and liquid handling.
关于客户
SPT Labtech is a leading provider of lab automation solutions, specializing in the development of innovative technologies to streamline laboratory workflows. The company focuses on creating efficient and robust solutions to enhance the productivity and accuracy of scientific research. SPT Labtech's products are designed to address the challenges faced by pharmaceutical and life sciences industries, particularly in the areas of assay development and high-throughput screening. By leveraging advanced automation and data management tools, SPT Labtech aims to reduce the time and resources required for complex experimental processes, enabling researchers to achieve faster and more reliable results.
解决方案
SPT Labtech combined dragonfly® discovery dispenser capabilities with Synthace experiment platform to increase speed, accuracy, and flexibility to execute a 6-factor space-filling DOE. Synthace experiment platform allows users to rapidly prototype complex automated liquid handling workflows by providing modules that can be easily rearranged and customized. Synthace could rapidly and flexibly generate an automated liquid handling protocol from the input DOE design file to send instructions to execute that campaign on the dragonfly® discovery, reducing the need for physical dry-runs to validate the protocol. The dragonfly® discovery allows teams to develop their assays using the same dispenser and high-density plates (384 or 1,536-well) as would be used in subsequent high-throughput workflows. Synthace automatically generates a detailed, digital record of every liquid handling and data aggregation step in that process, which significantly reduces risk of assays failing when transferring protocols into HTS. The 6-factor space-filling DOE required 3,456 runs in total for two sets of triplicates of 384 runs and the corresponding blanks. This amounts to 20,745 liquid handling steps, 2,305 for each of nine 384-well plates. Synthace guides users on required reagents, volumes, and labware with detailed schematics of how to set up the liquid dispenser and reagent reservoirs, and when to swap out the dispensing heads. The in silico simulation allows the user to validate the experimental workflow prior to physical execution. All low-level decisions are taken care of by Synthace so that the user isn’t required to manually determine plate maps and reservoir set-up before conducting a physical run in the lab, thereby reducing risk of human error or the need for repetitive dry-run physical testing in the lab before executing with valuable reagents. Synthace prompts the user to change the reservoirs when necessary, allowing more than 10 liquids to be layered onto the experiment plate. In the last step of the simulation, the user can select any well to inspect all the details of the liquids added during the protocol.
运营影响
数量效益
相关案例.
Case Study
Case Study: Pfizer
Pfizer’s high-performance computing software and systems for worldwide research and development support large-scale data analysis, research projects, clinical analytics, and modeling. Pfizer’s computing services are used across the spectrum of research and development efforts, from the deep biological understanding of disease to the design of safe, efficacious therapeutic agents.
Case Study
Fusion Middleware Integration on Cloud for Pharma Major
Customer wanted a real-time, seamless, cloud based integration between the existing on premise and cloud based application using SOA technology on Oracle Fusion Middleware Platform, a Contingent Worker Solution to collect, track, manage and report information for on-boarding, maintenance and off-boarding of contingent workers using a streamlined and Integrated business process, and streamlining of integration to the back-end systems and multiple SaaS applications.
Case Study
Process Control System Support
In many automated production facilities, changes are made to SIMATIC PCS 7 projects on a daily basis, with individual processes often optimised by multiple workers due to shift changes. Documentation is key here, as this keeps workers informed about why a change was made. Furthermore, SIMATIC PCS 7 installations are generally used in locations where documentation is required for audits and certification. The ability to track changes between two software projects is not only an invaluable aid during shift changes, but also when searching for errors or optimising a PCS 7 installation. Every change made to the system is labour-intensive and time-consuming. Moreover, there is also the risk that errors may occur. If a change is saved in the project, then the old version is lost unless a backup copy was created in advance. If no backup was created, it will no longer be possible to return to the previous state if and when programming errors occur. Each backup denotes a version used by the SIMATIC PCS 7 system to operate an installation. To correctly interpret a version, information is required on WHO changed WHAT, WHERE, WHEN and WHY: - Who created the version/who is responsible for the version? - Who released the version? - What was changed in the version i.e. in which block or module of the SIMATIC PCS 7 installation were the changes made? - When was the version created? Is this the latest version or is there a more recent version? - Why were the changes made to the version? If they are part of a regular maintenance cycle, then is the aim to fix an error or to improve production processes? - Is this particular version also the version currently being used in production? The fact that SIMATIC PCS 7 projects use extremely large quantities of data complicates the situation even further, and it can take a long time to load and save information as a result. Without a sustainable strategy for operating a SIMATIC PCS 7 installation, searching for the right software version can become extremely time-consuming and the installation may run inefficiently as a result.
Case Study
Drug Maker Takes the Right Prescription
China Pharm decided to build a cloud-based platform to support the requirements of IT planning for the next five to ten years which includes a dynamic and scalable mail resource pool platform. The platform needed to have the following functions: all nodes support redundancy, ensuring service continuity and good user experience, simple and easy-to-use user interfaces for end users and administrators and good compatibility and supports smooth capacity expansion.
Case Study
ELI LILLY ADOPTS MICROMEDIA’S ALERT NOTIFICATION SYSTEM
Pharmaceutical production is subject to a strict set of enforced rules that must be adhered to and compliance to these standards is critically necessary. Due to the efforts of WIN 911’s strategic partner Micromedia, Lilly was able to adopt an alarm notification infrastructure that integrated smoothly with their existing workflows and emergency hardware and protocols. These raw energy sources enable the industrial process to function: electricity, WIN-911 Software | 4020 South Industrial Drive, Suite 120 | Austin, TX 78744 USA industrial steam, iced water, air mixtures of varying quality. Refrigeration towers, boilers and wastewater are monitored by ALERT. Eli Lilly identified 15000 potential variables, but limitations compelled them to chisel the variable list down to 300. This allowed all major alarms to be covered including pressure, discharge, quantity of waste water discharged,temperature, carbon dioxide content, oxygen & sulphur content, and the water’s pH.
