AI models could be biased in algorithm design: Vandana Iyer

  • Interviews
  • Oct 28,24
In conversation with Sanskriti Ramachandran, Vandana Iyer, Research Director-TechVision, Frost & Sullivan, talks about the extensive use of AI and automation in the pharmaceutical industry.
AI models could be biased in algorithm design: Vandana Iyer

AI-models tend to be variable and complex and are often associated with lack of transparency in the algorithms that are deployed. This impacts the reproducibility of results and prediction, leading to lack of consistency, says Vandana Iyer, Research Director-TechVision, Frost & Sullivan.

What specific automation technologies are being developed for the pharmaceutical industry?

There are a wide range of automation technologies that are being developed for the pharmaceutical industry. These technologies can largely be classified into:

  • Use of AI & automation for drug discovery: AI is being increasingly used for drug discovery and clinical development of small molecule and biological therapies. Recursion, US, uses ML algorithms to accelerate drug discovery and currently has a lead candidate in phase 2/3 clinical studies for Neurofibromatosis treatment. Automated high throughput screening is widely used for screening large drug libraries for discovery of new therapies. Companies such as Thermo Fisher Scientific, US, already offer advanced HTS platforms for drug screening applications. Lab automation and robotics are also being increasingly used for liquid handling, pipetting and sample preparation.
  • Use of AI & automation across clinical development: AI and automation can help improve clinical trial design and outcomes, apart from enabling improved patient recruitment for clinical trials. Use of Robotic Process Automation (RPA) can help automated data entry and compliance reporting during clinical trials or other pharma processes.
  • Use of automation for pharma manufacturing: There is rising use of automation across various pharma manufacturing processes. Robots and co-bots are currently being used for packing and pelletising applications, and automating quality control and testing applications
  • Use of automation for improving pharma surveillance: AI can help automate the generation of safety reports and adverse events reporting post product launch, which will help enable improved patient safety practices.
  • Use of automation for supply chain and inventory management: IoT sensors-based automated tracking systems and real time supply chain monitoring will help improve inventory management in the pharma industry. It will also help improve compliance with laws pertaining to drug traceability.

What are the primary barriers to automation adoption in pharmaceutical manufacturing?

Some of the key barriers to automation adoption include:
  • Data security, privacy and integrity challenges: Data breach and cyber attacks continue to be critical challenges across all industries that are increasingly adopting AI and automation. The challenge is amplified in the pharmaceutical industry as data integrity has a direct impact on patient safety and well-being. 
  • Large scale transition to AI & automated manufacturing: Large and established pharmaceutical companies will need to invest significantly towards the infrastructure and skills to successfully transition towards automated manufacturing platforms. This is likely to be time consuming and cost-intensive, as it would need deep customisation to ensure seamless integration of AI and automation into their legacy manufacturing practices and processes.
  • Variability of AI models: AI-models tend to be variable and complex and are often associated with lack of transparency in the algorithms that are deployed. This impacts the reproducibility of results and prediction, leading to lack of consistency. AI models could also be biased in algorithm design which could adversely impact the actionable insights or process automation linked to these algorithms. 
  • Complexity of biological systems: AI’s efficacy is limited by the human understanding of complex biological systems. Factors such as genetic variation, environmental conditions, demographic variability and other factors may influence individual responses to drugs, which is difficult to incorporate in AI algorithms. Small molecule drug interactions with biological components cannot be completely simulated in a virtual environment using docking algorithms and scoring functions, as they are very complex, which may lead to identification of inactive molecules.
  • Ethical concerns: Data ownership, privacy, and user consent need to be defined clearly and transparently to ensure high compliance with regional privacy mandates and regulatory guidance. Ethics and regulatory guidance are still being developed across several regions and hence the adoption of AI and automation across such regions are likely to be more challenging due to the ambiguity of the regulatory landscape for such technologies.

How do you ensure that your automation solutions comply with regulatory standards?
There is a rising need to define regulatory standards for the use of AI and automation across the global pharmaceutical landscape. Regulatory agencies such as the US FDA are already drafting guidelines such as ‘Using Artificial Intelligence & Machine Learning in the Development of Drug and Biological Products’ to ensure structured regulatory standards which helps improve compliance. Continuous monitoring of quality standards, partnering with vendors that have the necessary regulatory compliance, such as the 21 CFR Part 11 for US FDA helps improve outcomes for automated processes. Ensuring and implementing GAMP5 (Good Automated Manufacturing Practice) guidelines and following ALCOA+ principles (Attributable, Legible, Contemporaneous, Original, Accurate, plus Complete, Consistent, Enduring, and Available) help improve regulatory compliance for automation. Conducting regular audits, securing virtual data repositories, rigorous documentation and periodic risk-based validation are also some practices that can be adopted to improve regulatory compliance.

What trends do you foresee in automation technology specifically tailored for pharma?
Some of the key automation trends in pharma will be:
  • Rising use of data-centric approach to address challenges across the pharma value chain
  • Growing focus on platform-based automation tools for the pharma industries as opposed to product-based solutions for driving new drug discovery and development
  • Increasing tech-bio partnerships across the IT and healthcare sectors for both diagnostic and precision medicine applications
  • Personalisation of wellness and healthcare solutions across defined population cohorts and rising individualisation of treatment design using advanced AI and automation tools.

How do you address the need for scalability in your automation offerings for pharma manufacturers?
Scalability in automation offerings can be achieved by:
  • Modular & flexible manufacturing design: Modular plug-n-play manufacturing models can be easily scaled up or down to suit production needs and workflows. Use of single-use reactors and continuous manufacturing protocols can help scale production needs in an agile manner. 
  • Standardized protocols and interoperability: Well-defined protocols for AI and automation can help add or remove components within manufacturing processes to scale up existing systems. Built-in compliance and validation across such systems will also help achieve regulatory standards and ensure optimal product quality during the implementation of the scaling operations.
  • AI for predictive scaling: Use of AI and digital twin systems can help understand the impact of scaling in virtual environment and help minimise operational risks during implementation in real world scenarios

As AI technologies evolve at a rapid pace, it is necessary to continuously upskill personnel and upgrade equipment and software periodically to ensure seamless manufacturing at the desired scale. 

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