Number of pages: 100 | Report Format: PDF | Published date: June 06, 2023
Historical Years – 2021 | Base Year – 2022 | Forecasted Years – 2023-2031
Report Attribute |
Details |
CAGR |
8.53% |
Base Year for Estimation |
2022 |
Forecast Period |
2023 to 2031 |
Historical Year |
2021 |
Segments Covered |
Product Type, Operation, End User, and Region |
Regional Scope |
North America, Europe, Asia Pacific, Latin America, and the Middle East & Africa |
According to the deep-dive market assessment study by Growth Plus Reports, the global automated colony picking systems market is expected to register a revenue CAGR of 8.53% during the forecast period of 2023 to 2031.
Automated Colony Picking Systems Market Fundamentals
Colony selection or selection is the most important aspect of identifying microorganisms (mostly bacteria). It is described as the procedure of selecting one pure colony to copy for future usage. In the microbiology laboratory, seeing, choosing, and counting colonies following inoculation in any culture media are crucial procedures. Automated colony pickers are pieces of equipment that assist in selecting the desired colony from a cluster of multiple colonies in any culture media without the need for manual labor.
Automated Colony Picking Systems Market Dynamics
The need for high-throughput screening in various fields, including pharmaceuticals, biotechnology, and academic research, is driving the adoption of automated colony picking systems. These systems allow researchers to process a large number of samples in a shorter time, increasing efficiency and productivity. Developing advanced robotics and automation technologies has enabled the design of more sophisticated and efficient colony picking systems. These systems offer improved accuracy, precision, and speed, reducing the potential for errors and increasing overall productivity. Additionally, the pharmaceutical industry continuously seeks ways to enhance drug discovery and development. Automated colony picking systems aid in identifying and isolating specific colonies for further analysis, accelerating the drug discovery pipeline. For instance, in January 2022, BD and Company received 510(k) clearance from the U.S. Food and Drug Administration (FDA) for the BD Kiestra IdentifA system, designed to automate microbiology bacterial identification testing preparation. The field of personalized medicine is gaining traction, focusing on tailoring treatments to individual patients. Microbial identification is essential in various industries, such as food and beverage, healthcare, and environmental monitoring. Moreover, the field of synthetic biology is expanding rapidly, with applications in biofuels, bioplastics, and biopharmaceuticals. Furthermore, these automated colony picking systems often incorporate advanced imaging technologies, such as high-resolution cameras and image analysis algorithms. These advancements enhance the accuracy and reliability of colony detection, ensuring precise colony picking even in complex sample matrices.
Automated colony picking systems can involve substantial upfront costs, including the purchase of equipment, software, and maintenance. Thus, integrating automated colony picking systems may require modifications to the laboratory infrastructure, including software integration with other instruments and laboratory management systems. The complexity of implementation can slow down the adoption of these systems. Automated colony picking systems may need help in handling various sample types, such as complex microbial communities or mixed cultures. Achieving accurate and reliable colony detection and picking in such samples can be challenging, impacting the system's overall performance and effectiveness. Moreover, strict protocols and regular maintenance are necessary to mitigate this risk. The need for standardized protocols and methods for colony picking can pose challenges for automated systems. Different research laboratories or industries may have unique requirements and preferences, making it difficult for manufacturers to develop universally applicable systems. Customization and adaptation to specific workflows can be time-consuming and costly. Operating and maintaining automated colony picking systems may require specialized skills and expertise. Training personnel to effectively use the systems and troubleshoot potential issues can be challenging, particularly in research laboratories with high staff turnover or limited resources for training. Furthermore, the need for more awareness about these systems' benefits and potential applications can hinder their market growth in specific geographical locations.
Automated Colony Picking Systems Market Ecosystem
The global automated colony picking systems market has been analyzed from the following perspectives: product type, operation, end user, and region.
Automated Colony Picking Systems Market by Product Type
Based on the product type, the global automated colony picking systems market is segmented into multi colony picking system, single pin system, and pipette tip-based system.
The single pin system accounts for a sizeable revenue share in the global market. Single pin systems are relatively simple in design and operation compared to multi-pin systems. They typically use a single pin or probe to pick and transfer individual colonies from a culture plate. This simplicity makes them easier to use and maintain, reducing operational complexities and costs. As a result, single pin systems are often more cost-effective, making them a popular choice for research laboratories with budget constraints. Single pin systems are compatible with a wide range of culture plate formats and colony types. They can handle various agar plate sizes and colony densities, making them versatile for different applications. This compatibility allows researchers to work with diverse sample types and customize their experiments, contributing to the widespread adoption of single pin systems. Single pin systems offer flexibility in colony picking. Researchers can easily adjust the picking parameters, such as picking location, depth, and speed, to optimize the process for their specific needs. Additionally, single pin systems can be scalable, allowing users to pick colonies from a few plates to hundreds or even thousands of plates in a high-throughput manner. This scalability makes them suitable for both small-scale and large-scale experiments. Single pin systems minimize the risk of cross-contamination between colonies. With a single pin dedicated to picking each colony, the chances of unintentionally transferring contaminants between colonies are significantly reduced. This advantage is particularly important in applications where maintaining the purity of colonies is crucial, such as genetic engineering or drug discovery. Single pin systems have been available in the market longer than other advanced picking technologies. They have a well-established user base and are widely accepted and trusted by researchers. This familiarity and market presence contribute to the significant revenue share of single pin systems in the global market.
Automated Colony Picking Systems Market by Operation
Based on the operation, the global automated colony picking systems market is segmented into plate replication, colony picking, re-arraying, and others.
The colony picking segment accounts for significant revenue shares in the global market. Colony picking is a fundamental step in microbial analysis and research. It involves identifying and isolating individual colonies from a culture plate for further analysis, such as genomics, proteomics, drug discovery, or synthetic biology. As colony picking is a crucial process in multiple scientific disciplines, the demand for automated systems that can perform this task efficiently and accurately is high. Colony picking plays a crucial role in applications such as antibiotic screening, genetic engineering, strain optimization, microbial identification, and production of recombinant proteins. The broad range of applications drives the demand for automated colony picking systems across different sectors, contributing to its significant revenue share. Automated colony picking systems offer high-throughput capabilities, allowing researchers to process many samples in a shorter time than manual picking methods. These systems can handle multiple culture plates simultaneously and pick colonies at a rapid pace. The ability to scale up the colony picking process enhances efficiency and productivity, making them attractive to laboratories and industries that require large-scale screening and analysis. The emphasis on accuracy and reproducibility drives the adoption of automated colony picking systems in research and industrial settings. Automated colony picking systems streamline the picking process and minimize the labor and time required for colony selection. This efficiency saves research laboratories and industries significant time and cost savings. By automating the colony picking step, researchers can allocate their time and resources to other critical tasks, increasing overall productivity and accelerating research and development processes. This integration ensures the smooth and efficient transfer of picked colonies to subsequent processes, reducing manual handling and potential errors. The ability to integrate with existing laboratory infrastructure and workflows makes colony picking systems more attractive to end-users.
Automated Colony Picking Systems Market by End User
Based on the end user, the global automated colony picking systems market is segmented into hospital laboratories, diagnostic laboratories, research laboratories, and others.
Diagnostic laboratories account for notable revenue shares in the global market. Diagnostic laboratories play a crucial role in identifying and diagnosing infectious diseases, monitoring antimicrobial resistance, and conducting environmental surveillance. Diagnostic laboratories often handle a large volume of samples daily. Thus, the increased efficiency and productivity provided by automated colony picking systems are highly valuable in diagnostic settings where timely and reliable results are essential. Since manual colony picking methods are prone to errors and contamination risks, which can compromise the accuracy and reliability of test results. Automated colony picking systems minimize these risks by providing consistent and precise colony picking, reducing the potential for cross-contamination and sample mix-ups. This improvement in accuracy and reliability is vital for diagnostic laboratories to ensure the integrity of their testing processes. Thus, optimizing resources and workflow enables diagnostic laboratories to handle a larger volume of samples efficiently, leading to improved operational efficiency and cost savings. Diagnostic laboratories often employ various automated systems and instruments, such as liquid handling systems, robotic platforms, and automated identification systems. Automated colony picking systems can integrate seamlessly with these other laboratory automation systems, creating a cohesive and efficient workflow. Integrating with existing laboratory infrastructure and workflows is crucial for diagnostic laboratories to maximize efficiency and streamline their processes. Diagnostic laboratories operate in a highly regulated environment with stringent quality standards and compliance requirements. Automated systems ensure traceability, accuracy, and reproducibility of results, which are essential for maintaining regulatory compliance and quality assurance. The field of microbial identification has witnessed significant technological advancements, such as advanced imaging technologies, improved image analysis algorithms, and advanced microbial identification databases. Automated colony picking systems leverage these advancements, enabling diagnostic laboratories to enhance microbial identification processes' accuracy, speed, and efficiency. Furthermore, the global prevalence of infectious diseases and antimicrobial resistance is increasing, leading to a greater demand for diagnostic testing in healthcare settings. For instance, according to WHO report, in 2020, Tuberculosis (TB) infection caused by mycobacterium tuberculosis was estimated that 10 million people were affected with TB globally, with 1.5 million dying from the disease. Similarly, according to UNAIDS, in 2020, approximately 38 million people were diagnosed with HIV globally, with approximately 680,000 AIDS-related deaths in the same year. Automated colony picking systems enable diagnostic laboratories to process numerous samples efficiently, contributing to the timely and accurate detection and management of infectious diseases and antimicrobial resistance.
Automated Colony Picking Systems Market by Region
The global automated colony picking systems market is segmented based on the region into North America, Europe, Asia Pacific, Latin America, and Middle East & Africa.
North America dominates the global market, with a revenue share of 38% majorly attributed to rapid growth in the prevalence of infectious diseases. For instance, according to a CDC report, in 2019, the recorded cases of tuberculosis and salmonella cases 2019 were 8,916 and 58,371, respectively. North America has a well-developed healthcare infrastructure with a strong emphasis on research and development. The region has numerous renowned research institutions, pharmaceutical companies, and diagnostic laboratories. The presence of these advanced healthcare facilities drives the demand for automated colony picking systems to enhance efficiency, accuracy, and productivity in their research and diagnostic processes. North America strongly emphasizes research and development, with significant investments in biomedical and life sciences research. The region's academic institutions and research centers actively engage in cutting-edge research projects, which require advanced technologies and tools for efficient colony picking and analysis. The demand for automated colony picking systems in North America is driven by the need to accelerate research processes and enhance scientific discoveries. The pharmaceutical and biotechnology industries in North America are well-established and globally recognized. These industries heavily rely on automated colony picking systems for various applications, such as drug discovery, genetic engineering, and high-throughput screening.
Competitive Landscape
The prominent players operating in the global automated colony picking systems market are:
Automated colony pickers are pieces of equipment that assist in selecting the desired colony from a cluster of multiple colonies in any culture media without the need for manual labor.
Hudson Robotics Inc., K Biosystems Ltd., Molecular Devices LLC., and SciRobotics are some of the major market players in the global automated colony picking systems market.
High cost for the automated colony picking systems system and lack of skilled professionals are some of the restraints obstructing the growth of the global market.
The diagnostic laboratories segment dominates the global automated colony picking systems market.
Growing technological advancement and the increasing prevalence of infectious diseases are some of the major factors driving the global market.
*Insights on financial performance are subject to the availability of information in the public domain