Laboratory Robotics Market Size, Future Trends and Regional Study

The global laboratory robotics market size was reached at around USD 2.38 billion in 2023 and is projected to hit around USD 4.74 billion by 2033, growing at a CAGR of 7.13% from 2024 to 2033.

The increasing demand for efficient & cost-effective laboratory operations, the need for automation in high-throughput testing, and the growing adoption of robotic systems in healthcare industry are some of the key drivers of the market.

Laboratory Robotics Market Report Highlights:

• Regional Dominance: North America currently holds the lion's share (41%) of the market in 2023, showcasing its strong adoption of automation solutions.
• Workstation Supremacy: Lab automation workstations reigned supreme in 2023, capturing 38% of the market revenue. This highlights the focus on streamlined workflows.
• Drug Discovery Drives Demand: The drug discovery segment led the application market in 2023, holding 29% of the share. This reflects the crucial role of robotics in accelerating drug development.
• Clinical Diagnosis on the Rise: While drug discovery is strong now, the clinical diagnosis segment is poised for the most significant growth in the coming years. This suggests a growing emphasis on automation in medical diagnostics.
• Clinics Lead the Way: In 2023, clinical laboratories held the majority share (56%) of the market by end-use. This signifies the widespread adoption of robotics in clinical settings.
• Research Labs Embrace Automation: The research laboratory segment is projected to experience the fastest growth (CAGR) from 2024 to 2033. This indicates a rising emphasis on automation in academic and research institutions.

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U.S. Laboratory Robotics Market Size 2024 to 2033

The U.S. laboratory robotics market size was estimated at USD 0.68 billion in 2023 and it is expected to surpass around USD 1.36 billion by 2033, poised to grow at a CAGR of 7.17% from 2024 to 2033.?

Laboratory Robotics Example

There are many ways that robots are used in laboratories to automate tasks and improve efficiency. Here are two common examples:

1. Liquid handling robots: These robots are essentially automated pipettors. They can aspirate (suck up) and dispense liquids with high precision and accuracy, which is crucial for many biological and chemical experiments. For instance, a liquid handling robot could be programmed to move tiny amounts of DNA samples between different wells on a plate for genetic analysis.
2. Plate handling robots: These robots specialize in moving microplates, which are trays containing multiple wells that can hold samples or reagents. They can load and unload plates from different instruments, stack them for storage, and transport them around the lab. This frees up scientists from repetitive tasks and allows them to focus on more complex aspects of their research.

Laboratory Robotics Market Future Trends:

Growing demand for automation: Laboratories are increasingly under pressure to improve efficiency and throughput while maintaining accuracy. Repetitive tasks are prime candidates for automation, and laboratory robots can consistently perform these tasks with high precision, freeing up scientists for more complex work.

Advancements in artificial intelligence (AI) and machine learning (ML): Integration of AI and ML can enhance the capabilities of laboratory robots. For instance, robots equipped with AI can learn and adapt to changing environments, improving their ability to handle complex tasks and making them more user-friendly.

Focus on personalized medicine: The growing field of personalized medicine necessitates flexible laboratory automation solutions. Laboratory robots can be programmed to handle smaller sample volumes and perform more intricate procedures required for personalized treatments.

Rise of microfluidics: Microfluidics deals with the manipulation of fluids in microscopic channels. Laboratory robots are becoming instrumental in automating microfluidic processes, which are crucial for various applications such as drug discovery and point-of-care diagnostics.

Growing emphasis on laboratory safety: Laboratory robots can minimize human exposure to hazardous materials by automating tasks involving pathogens, toxins, and radioactive materials. This plays a vital role in ensuring worker safety in research laboratories.

Laboratory Robotics Equipment:

Laboratory robotics equipment encompasses a diverse range of automated systems designed to perform various tasks in a laboratory setting. These improve efficiency, precision, and throughput in research and development processes. Here are some of the common types:

• Liquid handling robots: As mentioned previously, these essentially function as automated pipettors. They precisely dispense and aspirate liquids, a vital step in numerous biological and chemical experiments.? Programmed with specific protocols, they can move minute volumes of samples between well plates for tasks like genetic analysis.
• Plate handling robots: These specialize in manipulating microplates, trays containing multiple wells used to hold samples or reagents. They efficiently load and unload plates from various instruments, stack them for storage, and transport them throughout the lab. This frees up scientists from repetitive tasks, allowing them to focus on more intricate aspects of their research.
• Robotic arms: These versatile systems equipped with multiple degrees of freedom allow for sample manipulation, movement of plates, and integration with other laboratory instruments. They are commonly used for pharmaceutical applications, such as drug discovery and protein analysis.

Other specialized laboratory robotic equipment includes:

• Automated laboratory workstations - Integrate various robotic systems with analytical instruments to create a self-contained processing environment.
• Automated sample preparation systems - Expedite sample preparation for analysis through automated processes like dilution, filtration, and aliquoting.
• Robotic microscopes - Automate microscopy tasks such as image capture and analysis of samples like cells or tissue sections. These are used in applications like high-content screening and digital pathology.

Sensors Used in Robotics

Robots rely on a variety of sensors to perceive their environment and interact with the world around them. These sensors can be broadly categorized into two main groups:

Exteroceptive sensors: These sensors gather information about the robot's external environment. Examples of exteroceptive sensors include:

• LiDAR (Light Detection and Ranging): LiDAR sensors use light pulses to measure distance to an object. They are often used in autonomous vehicles and robots for navigation and obstacle avoidance.
• Cameras: Cameras capture visual data of the robot's surroundings. This data can be used for tasks such as object recognition, object manipulation, and path planning.
• Ultrasonic sensors: Ultrasonic sensors emit high-frequency sound waves and measure the time it takes for the waves to reflect off an object and return. They are used for short-range obstacle detection and proximity sensing.
• Infrared sensors: Infrared sensors detect infrared radiation, which is heat. They can be used for tasks such as line following, object detection, and people counting.

Proprioceptive sensors: These sensors provide information about the robot's internal state, such as its position, velocity, and acceleration. Examples of proprioceptive sensors include:

• Gyroscopes: Gyroscopes measure the robot's orientation and angular rate.
• Accelerometers: Accelerometers measure the robot's linear acceleration.
• Encoders: Encoders are attached to the robot's joints and measure the position and speed of the joint.

Laboratory Robotics Market Regional Study

North America stands out as the global leader in laboratory robotics, holding a commanding 41% market share in 2023. This dominance is fueled by two key forces: a continuous stream of technological advancements and a growing appetite for automation within laboratories. Additionally, strategic partnerships between major players in the field are further accelerating this expansion.

Meanwhile, the Asia-Pacific region is emerging as a major player in the laboratory robotics market. This growth is largely driven by a surge in funding and investment directed towards innovative technologies. This financial backing is empowering key players in the region to develop cutting-edge robotic solutions specifically designed for laboratory automation.

Laboratory Robotics Market Top Companies

• Peak Analysis & Automation
• PerkinElmer Inc.
• Thermo Fisher Scientific Inc.
• Hudson Robotics
• Anton Paar GmbH
• Beckman Coulter, Inc.
• Siemens Healthcare Private Limited
• AB Controls, Inc.
• Abbott
• Biomérieux

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