Home Five Emerging Trends in Medical AI and Digital Health Technologies Following ChatGPT's Breakthrough

Five Emerging Trends in Medical AI and Digital Health Technologies Following ChatGPT's Breakthrough

Dec 12, 2023 10:05 CST Updated 10:07

“With the rapid advancement of AI technology and the continuous expansion of model parameters, quantitative changes have led to qualitative leaps, giving rise to emergent intelligence,” remarked Liu Junwei, General Manager of Baidu Smart Healthcare, at the Future Medical Technology Conference.

 

Although 2022 appeared to be a year of cooling sentiment in digital health, with the early-pandemic fervor subsiding from primary markets to IPOs, investors have become more cautious.In 2023, the digital technology sector once again saw a surge in momentum.Most notably, industry leaders have emerged. OpenAI’s ChatGPT fired the first shot in the deep application of AI.

 

The underlying reason isIn-Depth Exploration of Technological Value

 

Large Language Models Spark Widespread Attention in Academia and Industry


Judging by the attendees of the 2023 Future Healthcare Technology Conference, we could also sense the audience’s immense enthusiasm for digital technology. The conference rooms were packed with attendees, including scientists, investors, and corporate business development professionals.

 

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In the words of Professor Wang Guangyu from Beijing University of Posts and Telecommunications,The development of foundation (large) models has endowed machines with the capabilities to perceive, think, explore, and create, which will have a profound impact on society and industries, thereby attracting significant attention and R&D efforts from both the research community and industry.

 

At the conference, Professors Zhang Yuanting, Zhou Shaohua, Wang Guangyu, and Gong Yan—all in attendance—concurred that artificial intelligence will profoundly impact the industry as digital technologies advance. They have each conducted frontier explorations in areas such as intelligent diagnostic devices, medical imaging, healthcare services, and microscopic imaging.

 

Meanwhile, in the capital markets, digital technology has undergone a rapid surge in interest. The fervor surrounding ChatGPT has spread from the product itself to various sectors, igniting global enthusiasm starting from Silicon Valley. Google Trends data shows a sharp spike in ChatGPT’s global search interest; within the venture capital community, startups in this sector have continued to attract strong investor demand since the beginning of 2023.

 

Undoubtedly, this surge of momentum has brought opportunities to all enterprises, while also serving as a sudden breakthrough for digital technology—Identify genuine application scenarios and anticipate rapid implementation.

 

Five Major Application Trends in the Integration of Digital Technology and Healthcare


Digital technology has become deeply embedded within the healthcare industry. Taking medical services as an example, Elsevier’s “White Paper on the Future Doctor” indicates that over the next decade, three major trends will shape global healthcare development: the deep integration of digital technologies with medical services, a comprehensive improvement in patients’ health literacy, and the diversification of healthcare scenarios. Big data will be extensively integrated into population health management. The continuous accumulation of data from interconnected research datasets, electronic medical records, and medical devices will help physicians formulate more precise diagnosis and treatment plans, thereby enhancing decision-making efficiency.

 

At the Future Technology Conference, we witnessed not only the integration of digital technology with healthcare services but also its diversified convergence with intelligent diagnostics, drug development, and medical imaging.

  

1Entering the Healthcare Services Sector to Improve Patient Visit Efficiency


The Integration of Digital Technology and Medical Processes Brings Multiple Advantages.

 

From the patient’s perspective, digital healthcare not only transcends time and space to address information asymmetry between patients and providers, but also simplifies medical processes, reduces healthcare costs, and improves the care experience. From the physician’s perspective, digital healthcare enables the digitization of patient medical records and health files, thereby enhancing the efficiency of disease diagnosis and patient management, and further liberating medical productivity. From the healthcare institution’s perspective, digital healthcare facilitates refined internal management, elevating both managerial and service standards.

  

At the Future Medical Technology Conference, Professor Wang Guangyu sharedMultimodal Foundation Large Models for Healthcare”, leveraging tens of millions of biomedical data points, the BUPT team has conducted research on understanding and generation based on large-scale language models. By integrating medical knowledge with a reasoning core and multimodal intelligent semantic computing methods, they are advancing “human-centered” semantic alignment and natural interaction.

 

Currently, the BUPT team has developed ClinicalBERT 1.2B for general medical scenarios, the large language model ClinicalGPT 175B (with ClinicalGPT 7B-Base released on Hugging Face), and UniBind, a protein function analysis framework based on large-scale pre-trained models (published inNature Medicine). Furthermore, the team has explored TCM-GPT, a multimodal large language model for Traditional Chinese Medicine (TCM), built upon ClinicalGPT. It demonstrates superior performance across multiple dimensions, including TCM theory, syndrome differentiation and treatment, meridian and acupoint knowledge, and herbal compatibility.

 

Xu Liqun, Chief Scientist at China Mobile Research Institute, also discussed “Opportunities and Challenges in the Transformation of Healthcare Services in the Era of Large Language Models,” whereinAutomated Medical Record Generation SolutionIntegrate large language models into clinical workflows to assist physicians with documentation tasks across various care settings, including outpatient, emergency, and inpatient services.

 

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Furthermore, Liu Junwei, General Manager of Baidu Smart Healthcare, also shared at the conference Baidu’s initiatives based on the Lingyi large language model in “Patient-Doctor-Drug“Regarding practical implementation in these areas, he stated, “Large language models offer higher accuracy and shorter development cycles. They will deliver new outcomes in specialized empowerment, quality and efficiency improvement, and enhanced user experience across applications such as intelligent health managers, AI-powered physician assistants, and smart enterprise services, thereby truly bringing new productive forces to the big health industry.”

 

2Upgrading Wearable Detection Devices to Predict Cardiovascular Diseases


“Health initiatives advocate for early screening, early diagnosis, and early recovery. While policies are in place, there is still a significant shortage of medical devices,” said Zhang Yuanting, Academician of the International Academy of Medical and Biological Engineering and Founder of the Hong Kong Institute of Medical Engineering.

 

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Therefore, wearable monitoring devices hold significant importance for both consumer (C-end) and business (B-end) users. For consumer users, wearable medical devices will provide users withProvide Real-Time Health Monitoring Data, enabling users to understand their health status and facilitating scientific health management. For B-side users, the real-time data provided by wearable medical health devices offers robust medical support for resource allocation in healthcare institutions, allowing physicians to conduct remote consultations and reduce treatment costs.

 

“Previous wearable detection devices were not very convenient,” said Professor Zhang Yuanting. In 2001, Professor Zhang was the first to propose non-wearable smart detection devices. He also stated thatFuture smart wearable detection devices will evolve toward miniaturization, intelligence, standardization, and non-intrusiveness.

 

3Next-Generation Optoelectronic Imaging Technology: Computational Optical Fusion Microscopy Imaging


The domestic high-end microscope market is currently monopolized by the four major German and Japanese manufacturers. Most domestically produced equipment is characterized by high volume but low quality, with an extremely low market share. Whether from a market perspective or a technological integration perspective,The Integration of Computational Optics and Microscopy Imaging Is an Inevitable Trend in the Development of the Market/Information Age

 

Traditional optical imaging is based on geometric optics and adopts the "what you see is what you get" principle of human vision, thereby neglecting much high-dimensional optical information. In the field of microscopic imaging, it fails to simultaneously meet the demands for a wide field of view and high resolution.

 

In contrast,Computational Optical ImagingGuided by specific application tasks, this approach acquires or encodes light field information across multiple dimensions (such as angle, polarization, and phase) to establish a new sensing paradigm for sensors that far surpasses human visual perception. Meanwhile, by integrating mathematics and signal processing expertise, it deeply mines light field data to break through the limits of traditional optical imaging.

 

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Gong Yan, a Distinguished Research Fellow at the Chinese Academy of Sciences, stated,Optical microscopy, characterized by its non-invasive nature and broad applicability, is currently the preferred observational tool in research fields such as biology, medicine, and pharmacy.. In this field, Professor Gong Yan’s team has comprehensively upgraded the full-chain digital manufacturing processes encompassing design, machining, assembly integration, and system testing, and has independently developed multiple series of high-end microscope objectives.

 

These include the completion of a prototype STED–two-photon composite microscope (achieving an ultra-high resolution of 47 nm and an imaging depth of 141.5 μm); focusing on asymmetric three-beam interference illumination combined with segmented half-wave plates to enhance imaging speed; and large-field-of-view optical tomography microscopy to increase the spatial resolution of the imaging system to hundreds of megapixels.

 

In the future, high-end microscopes will continue to pursue higher resolution, faster imaging speeds, and greater imaging depth. Professor Gong Yan stated that emerging technologies will be integrated with optoelectronic microscopes in the years ahead.

 

One isNovel Optical Devices and Light Field Modulation Mechanisms. Novel devices such as metalenses, metamaterials, plasmonics, and photonic crystals provide new means of optical control for computational optics. Another isEmerging Mathematical Algorithms and Computational Performance. New theories, mechanisms, and technologies for various complex real-world imaging applications are developed to establish superior multi-parameter design and optical regulation mechanisms, providing robust support for the advancement of computational imaging.

 

4Generative AI Enters Medical Imaging, Breaking Spatial and Temporal Barriers


Another prominent application of digital technology is in medical imaging. The global frenzy surrounding software such as ChatGPT has demonstrated the capacity of generative AI to produce text or images from complex user prompts, highlighting its broad application prospects and significant achievements already realized in the healthcare sector.

 

In 2023, Siemens Healthineers showcased innovative concepts and technical prototypes based on generative AI. Unlike other companies that focus on text or image generation, Siemens Healthineers enables users to quickly locate and highlight corresponding areas in reports by clicking on medical images, through the loading, linking, and preparation capabilities of its intelligent chat system. Even more noteworthy is that Siemens HealthineersLeverage AI to dynamically generate diagnostic imaging reports and prioritize them by clinical significance, enabling physicians to process information more efficiently.

 

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At this conference, Professor Zhou Shaohua, Chair Professor at the University of Science and Technology of China and Member of the U.S. National Academy of Inventors, outlined two potential forms of AI-generated medical imaging: one is medical image restoration, and the other isMedical Image Synthesis

 

Currently, Professor Zhou Shaohua’s team is exploring novel methods for synthesizing MRI images. “We measure various parameters, including demographics, genomic sequencing data, biomarkers, and imaging data. It is evident that causal relationships exist among these categories of measurements. The resulting images can reflect both demographic information and biomarker data.” By leveraging causal models to regulate different parameters, this approach also overcomes the limitations of time and space.Imaging data from ten years ago can also be synthesized using computational methods.。”

   

5Digital Technologies Empower Drug Development


Drug discovery and development are key research areas for pharmaceutical companies and medicinal chemists. However, inefficiency and high costs have long been obstacles in this field.

 

Many individuals engaged in drug research and development acknowledge that the digital era is transforming the pharmaceutical industry. Machine learning and deep learning algorithms have been applied to various stages of drug discovery, including peptide synthesis, virtual screening, toxicity prediction, drug monitoring and release, pharmacophore modeling, quantitative structure-activity relationship (QSAR) analysis, drug repurposing, and the assessment of polypharmacological and physiological activities.Significantly Shorten Drug Time-to-Market and Enhance Safety

 

Wang Taifeng, Head of AI Algorithms at BioMap, is another example. At the Future Medical Technology Conference, Wang shared his insights on “AI Foundation Models for Target Discovery and Drug Design.” He stated that natural language alone is insufficient to help pharmaceutical companies leverage more information. Therefore, BioMap has developed aBillion-Parameter Protein Language Large Model, leveraging this model to advance protein prediction and design, and further utilizing AI-driven drug generation systems to screen compounds for novel drug development.

 

Key to the Implementation of Digital Technologies

 

Above, we have described the integration of digital technology with multiple application scenarios. Despite its diverse innovations, immense power to create miracles, and boundless creativity, it has failed to escape a critical bottleneck:How to Rapidly Implement Digital Technologies While Ensuring Information Accuracy and Security

 

In terms of technological commercialization, China’s large language model (LLM) industry is currently plagued by intense cutthroat competition. In contrast, international vendors are more focused on the practical deployment and application of LLMs.From the intense competition in the technology itself to the fierce rivalry in application scenarios, this is an inevitable stage in the commercialization of China’s data technology.

 

Regarding information accuracy, Wang Guangyu stated: “General-purpose large language models still lack domain-specific knowledge.“Although ChatGPT can, to some extent, answer medical questions, it remains significantly deficient in highly specialized areas, such as optimizing the diagnosis of patient symptoms or formulating treatment plans. Current large language models still lack genuine professional reasoning capabilities, as well as the domain-specific accuracy, compliance, and safety required in healthcare. Transitioning from general-purpose foundational models to specialized large models for the health sector still presents numerous technical challenges that require further exploration and resolution.”

 

On ethical and moral issues,The training and application of generative AI require large amounts of patient data, which may raise concerns about data privacy and confidentiality.. To ensure the security of patient information, healthcare institutions and enterprises must implement stringent data management measures and comply with relevant laws and regulations.

 

Revolutionary Changes Often Coexist with Risks. Although digital technology is facing certain challenges and ethical concerns, industry stakeholders are addressing this field with a focus on safety, fairness, evidence-based practice, and privacy. With proper planning and management, digital technology is poised to propel the healthcare industry into a new era characterized by greater efficiency, precision, and personalization.