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Yu, Hong, Lee, Lee, Lee, Seo, Kang, Kim, Cha, and Shin: Stakeholders’ Requirements for Artificial Intelligence for Healthcare in Korea

Abstract

Objectives

The outlook of artificial intelligence for healthcare (AI4H) is promising. However, no studies have yet discussed the issues from the perspective of stakeholders in Korea. This research aimed to identify stakeholders’ requirements for AI4H to accelerate the business and research of AI4H.

Methods

We identified research funding trends from the Korean National Science and Technology Knowledge Information Service (NTIS) from 2015 and 2019 using “healthcare AI” and related keywords. Furthermore, we conducted an online survey with members of the Korean Society of Artificial Intelligence in Medicine to identify experts’ opinions regarding the development of AI4H. Finally, expert interviews were conducted with 13 experts in three areas (hospitals, industry, and academia).

Results

We found 160 related projects from the NTIS. The major data type was radiology images (59.4%). Dermatology-related diseases received the most funding, followed by pulmonary diseases. Based on the survey responses, radiology images (23.9%) were the most demanding data type. Over half of the solutions were related to diagnosis (33.3%) or prognosis prediction (31%). In the expert interviews, all experts mentioned healthcare data for AI solutions as a major issue. Experts in the industrial field mainly mentioned regulations, practical efficacy evaluation, and data accessibility.

Conclusions

We identified technology, regulatory, and data issues for practical AI4H applications from the perspectives of stakeholders in hospitals, industry, and academia in Korea. We found issues and requirements, including regulations, data utilization, reimbursement, and human resource development, that should be addressed to promote further research in AI4H.

I. Introduction

The outlook of artificial intelligence for healthcare (AI4H) is very promising [1]. The size of the AI4H market with software as a medical device (SaMD) is expected to reach about US $4.9 billion in 2020 and $45.2 billion in 2026, with an annual growth rate of 44.9%. In particular, growth from US $1.9 billion to $17.8 billion (an annual growth rate of 45.6%), $1.4 billion to $12.3 billion (44.5%), and $1.2 billion to $12.0 billion (46.3%) in the United States, Europe, and Asia-Pacific in this period [2,3]. AI4H is used for many healthcare applications, such as clinical decision support, virtual assistants, computer-aided diagnosis, and robots in hospitals [4]. As a result, the number of Food and Drug Administration (FDA)-approved AI-based algorithms in the United States has increased from 41 to 68, and in South Korea from 4 to 61, between January 2018 and December 2020 [5,6]. As described previously [7], there are 130 US FDA-approved medical AI devices.
Three fundamental factors have contributed to the recent achievements of AI4H: (1) advances in AI algorithms, (2) improvements in computing power such as general-purpose computing on graphics processing units, and (3) generation of healthcare big data such as Electronic Medical Records, genomic sequencing data, and computed tomography and magnetic resonance imaging (CT/MRI) scans. These factors converge to enable research on AI-based prognosis prediction, disease diagnosis, genomics, and radiomics. Some researchers have reported that AI outperformed physicians in disease classification, demonstrating its success in detecting diseases on medical images [79].
To address the success and trends of AI4H, several white papers and reports have been published, such as the AI index report from Stanford University [10] and the AI in healthcare report from the National Academy of Medicine [11]. Recently, a survey article identifying the expected impact and value of AI4H was published, based on an online survey with 151 experts from 15 countries in Europe. They divided challenges into technical and non-technical, for example data anonymization, sharing and regulatory issues, and standardization [12]. However, most of those reports have focused on showing current issues without proposing a practical discussion for real-world use. There have been a few previous studies discussing the practicality and challenges of AI4H in Korea [13,14], but no study has yet discussed the issues of AI4H from challenge identification to solutions in terms of stakeholders’ opinions, which will be very critical for practical applications.
The aim of this study is identifying stakeholders’ requirements for AI4H in Korea by reviewing governmental research and development funding and conducting an online survey and in-depth expert interviews. This study will help to promote future research and business of AI4H in Korea.

II. Methods

In order to identify the stakeholders’ requirements for AI4H in Korea, we analyzed research funding, an online survey, and in-depth interviews. First, the analysis of research funding identified resources and projects supported by the government over time, reflecting trends and demands in AI4H research. Second, the online survey investigated perspectives regarding topics, data, and solutions that should be studied in AI4H. Third, in-depth expert interviews identified the status, problems, and solutions of AI4H in Korea. We designed the interviews using the sample, phenomenon of interest, design, evaluation, and research (SPIDER) framework as a qualitative method [15]. A semi-structured interview form was also used to guarantee that the same topics were addressed in each interview and to obtain various opinions from experts. More details on the interview design are provided in Supplementary Figure S1.

1. Analysis of Korean Governmental Research Funding for AI4H

We focused on governmental research funding for AI4H in Korea to identify its trends. Research funding could be searched in the National Science and Technology Knowledge Information Service (NTIS) database platform. We searched for related AI4H projects from 2015 to 2019 using appropriate keywords [16]. More specifically, the following keywords related to AI4H were searched with synonyms and abbreviations: “healthcare AI,” “machine learning,” “standardization,” and “CDM.” We then extracted structured information, including project name, start date, subject, budget, implementation agency, and application status, from the NTIS before manually reviewing the information. Multi-year projects were counted once, in their starting year, in order to remove duplicates, and irrelevant projects were excluded. The data were categorized for analysis into pre-defined categories.

2. Survey

Between September 21 and 28, 2020, we conducted a survey to identify various expert opinions from members of the Korean Society of Artificial Intelligence in Medicine (KOSAIM) regarding the development of AI4H. The survey consisted of four questions regarding respondents’ affiliation, the target disease, the type of necessary data, and the target application (see Supplementary Figure S2). The affiliation question provided three possible answers: hospital, industry, or academia. Target diseases were submitted as free-text responses. The data types answers were divided into seven categories: laboratory test data, radiology images such as CT/MRI scans, genomic data, continuous vital signs, medical notes in free-text format including progress reports, radiology or pathology reports, and others. The target applications consisted of five items, including diagnostic prediction, prognosis prediction, treatment plan recommendation, monitoring, and others. A Google Form was used to implement the survey. We sent emails with a Google Form link to all participating members of the KOSAIM.

3. Expert Interviews

In-depth expert interviews were conducted with experts in three areas: hospitals, industry, and academia. We selected 13 experts among 30 candidates through internal meetings. Thereafter, to conduct the expert interviews, we implemented a semi-structured questionnaire consisting of five main points: introduction, initial discussion, questions about trends, essential questions, and closing. The questions identifying the status and problems of AI4H in experts’ practical environment were “What do you think of the current level of AI4H?”, “What are the limits of current AI4H?”, “What should be the directions of AI4H?”, and “What if healthcare AI expands enough, what challenges do we need to address?” All interviews were recorded with the interviewee’s agreement. We transcribed the interviews using the recorded files. According to the transcripts, the contents of the expert interviews were organized into six categories based on reviews by participant researchers: partnerships, training of human resources, technology for analysis, data, regulation, and others (see Supplementary Figure S1).

4. Data Analysis

We used R version 4.0.2 for data analysis (https://www.rproject.org/). Categorical data were expressed as frequency and percentage. The chi-square test was performed to determine the relationships of categorical variables. We used two-sided tests with a statistical significance level of p < 0.05.

5. Ethics Statement

The present study protocol was reviewed and approved by the Institutional Review Board of Samsung Medical Center (No. 2020-08-057-001), which waived the requirement for informed consent.

III. Results

1. Analysis of Governmental Research Funding

First, a total of 299 research projects were found in the NTIS database according to the inclusion criteria. After manually reviewing the candidate projects, 115 duplicated multi-year projects and 24 irrelevant projects were excluded. Finally, 160 projects were selected and analyzed.
The major data types used for AI4H during the past 5 years are shown in Table 1. As expected, among the 160 projects, the most common data type was radiology images (95 projects, 59.4%). Others (29 projects, 18.1%), including patient-reported outcome or digital phenotypes, ranked second. Laboratory data (6.9%), radiology/pathology reports (5.6%), and genomic data (5.0%) followed. The number of projects increased sharply in 2017.
Figure 1 depicts the average funding by target disease type per year. The unit of the funding scale is US $1,000. Dermatology-related diseases received the most funds (US $284,000), followed by pulmonary diseases (US $80,000), musculoskel et al system disorders (US $75,000), coronary artery diseases (US $60,000) and dementia (US $48,000).

2. Survey

A total of 101 KOSAIM members participated in the survey, 54 (53.5%) of whom worked in hospitals, 28 (27.7%) in academia, and 19 (18.8%) in industry.
Among the data demands in hospitals and academia, most of the responses indicated image types (27.6% and 20.5%) and laboratory data (22.1% and 16.7%). In contrast, researchers in industry expressed the highest demand for laboratory data (20.8%), followed by free-text reports (18.8%) and radiology/pathology reports (18.8%). The demand for free-text report analysis was higher than that for vital signs in hospitals and industry, but lower in academia (Table 2).
Figure 2 shows the results of a comparison of demand for data types between NTIS and survey responses. The patterns of data demands were significantly different (p < 0.05), especially regarding medical image data (59.4% for NTIS and 23.9% for survey responses).
Over half of AI4H software was related to the diagnosis prediction (33.3%) or prognosis prediction (31%). Interestingly, researchers in the hospital field, who comprised one-fifth of the respondents, chose treatment plan recommendations (19.4%) (Table 3).

3. Expert Interviews

Thirteen experts in the field of medical AI participated in the expert interviews, of whom three (23.1%) worked in hospitals, four (30.8%) in academia, and six (46.1%) in industry.
We identified the major topics, organizing them into five items by interviewer affiliation, as shown in Table 4.
Half of the major topics for AI4H related to data among experts in hospitals. In industry, regulation was the most commonly identified problem (34.0%), followed by data (23.4%). In academia, data were often identified as a problem (36.0%), but respondents also frequently mentioned education (28.0%) and regulation (20.0%). Other topics included medical charges, marketability, practical applications, medicolegal issues, and organization of governance for AI4H.
Table 5 shows the specific keywords. In the hospital field, most experts mentioned needs related to data, such as standardization, a common data model, and data certification. They specifically mentioned that available domestic open datasets are insufficient for technology development and performance evaluation. Moreover, they pointed out that common data models and data standards such as Health Level Seven (HL7) are required. Furthermore, the necessity of an internal organization in charge of hospital data governance was proposed.
In the industrial field, experts mainly mentioned regulations, practical efficacy evaluation, and data accessibility. Although the Korean Privacy Information Protection Act has been amended, it is still difficult to use clinical data in practice. Because of this limitation, it is difficult to evaluate medical AI solutions. There is a need for proactive deregulation. The participants also proposed changing the insurance reimbursement plan to promote the adoption of AI4H.
Experts in academia argued for privacy protection and long-term funds. They mentioned the necessity of long-term collaboration between academia, hospitals, and industry. Moreover, some of them discussed the practical applications and responsibilities of AI4H.
Most interviewees, regardless of their position, emphasized the importance of training for AI4H experts. AI4H is a multidisciplinary field requiring knowledge of medical areas and AI technology. Specifically, academically oriented needs of education require more options in methodology of fundamental technology. In contrast, the market needs practical courses for employees who want to develop essential AI4H techniques.

IV. Discussion

According to the increasing demand and interest in AI4H, we aimed to identify the practical needs of AI4H stakeholders. Previous studies have examined the status of AI4H, and our study expanded the research further to address practical issues regarding the AI4H development. We identified demands and trends through an analysis of NTIS data, survey responses, and expert interviews.
The analysis of 5 years of NTIS data showed that many studies focused on disease diagnosis using radiology image data, as shown in Table 1. AI solutions using image data already have high accuracy and have been commercialized [56]. Research using radiology image data has tended to decrease from 2018, which could indicate that the research on radiology images has already reached a certain level. As the level of research and technology advances, research on genomic data, psychology, mental illness, and digital phenotypes, which are areas where demand was relatively low, is also increasing. This trend can be seen in the results of the survey; the data demands are diverse, as shown in Figure 2.
As presented in Table 2, the data demands of hospitals and academia have similar patterns, but those of industry are different in terms of a focus on non-image data. European researchers also reported the strongest demand for electronic health records and patient-generated data [12]. Through these results, it can be expected that the research demand and diversity of AI4H will increase further in the future, as exemplified by multi-modal research using radiology images with various data including laboratory results and free text.
The identified issues and requirements are presented in Table 6. In AI4H, medical data are an essential resource for the development and evaluation of AI models. Since developing new drugs and diagnostic technologies through healthcare big data will eventually lead to improvements in public health, research in this field should be accessible. To address this need, the government must clarify the related laws and regulations. It is also important to strengthen privacy protection using various recent technologies, such as federated learning, homomorphic encryption, synthetic data, differential privacy, and dynamic consent [1721]. Other countries also have been arguing for regulations including data protection and data sovereignty which are very similar considerations [12].
We identified needs for cohort and open dataset development supported by the government and the expansion of data quality certification for hospitals. To promote access to patient data in hospitals, it is necessary to establish a national healthcare big data system, such as the “All of Us” project in the United States [22]. The data should be FAIR (findable, accessible, interoperable, and reusable) [23]. With the FAIR guideline, data quality should also be guaranteed. Efforts for data quality management through standardization are also needed. To accelerate data quality management, a data certification program might be considered. The Korea Data Agency already runs a data certification center that screens and certifies data quality, data management, and data security to ensure the quality of the information systems used at institutions or companies [24]. Furthermore, a governance organization is required to manage and supervise the data evaluation methods and standardization of medical data [25].
Reimbursement for AI SaMD is the biggest issue in Korea, where there were 61 approved AI SaMDs in 2020, but none of them were listed in the National Health Insurance register [26]. Without reimbursement, it is difficult for hospitals in Korea to use these AI SaMDs. Therefore, a forward-looking policy is necessary. The Digital Health Applications of Germany [27], US Centers for Medicare & Medicaid Service New Technology Add-on Payment [28], and US Medicare Coverage of Innovative Technology [29] could be considered as benchmarks for insurance reimbursement. In terms of real-world applications and regulations, it is also necessary to develop data de-identification technology and ethical guidelines on AI4H.
Well-known institutions offer various AI courses. However, most courses are conducted in the short term and have limited options regarding methodologies of fundamental technology. Furthermore, there are few courses designed for the medical field with accompanying medical domain education. In order to lead and sustain AI4H in the future, long-term human resources development programs should be implemented.
There are several limitations of this study. First, there is the issue of selection bias with participants who presented opinions supporting AI4H. However, we selected KOSAIM members, who are experts in the field of medical AI, in order to obtain reliable results. In addition, the sample sizes of the survey and the expert interviews were relatively small. Second, as we examined research funding only in the NTIS database using the keyword “healthcare AI,” some research projects might have been excluded. Finally, meaningful opinions might have been excluded because the frequency of the terms in the interviews was used for analysis; however, the interview content was sufficiently discussed.
In conclusion, we identified technology, regulatory, and data issues for practical AI4H applications from the perspectives of experts in the hospital, industry, and academia fields in Korea. We found four main issues—laws and regulations, data utilization, reimbursement, and human resource development—and identified requirements for further research in AI4H.

Supplementary Materials

Supplementary materials can be found via https://doi.org/10.4258/hir.2022.28.2.143.
Figure S1. Semi-structured format of the expert interviews.
Figure S2. Survey format for the members of the Korean Society of Artificial Intelligence in Medicine (KOSAIM).
hir-2022-28-2-143-suppl.pdf

Acknowledgments

This research was supported by a grant from the Korea Health Information Service (2020).

Notes

Conflict of interest

No potential conflict of interest relevant to this article was reported.

Figure 1
Average funding by target disease per year.
hir-2022-28-2-143f1.jpg
Figure 2
Comparison of data types between NTIS (from 2015 to 2019) and the KOSAIM members’ survey in 2020.
hir-2022-28-2-143f2.jpg
Table 1
Major data types during the past 5 years
2015 2016 2017 2018 2019 All
CT/MRI 2 (66.7) 2 (40.0) 22 (57.9) 37 (62.7) 32 (58.2) 95 (59.4)
Lab data 0 (0) 0 (0) 4 (10.5) 4 (6.8) 3 (5.5) 11 (6.9)
Genome 0 (0) 1 (20.0) 1 (2.6) 2 (3.4) 4 (7.3) 8 (5.0)
Vital 0 (0) 0 (0) 2 (5.3) 2 (3.4) 3 (5.5) 7 (4.4)
Radiology/pathology reports 1 (33.3) 0 (0) 2 (5.3) 2 (3.4) 4 (7.3) 9 (5.6)
Free text reports 0 (0) 1 (20.0) 0 (0) 0 (0) 0 (0) 1 (0.6)
Othersa 0 (0) 1 (20.0) 7 (18.4) 12 (20.3) 9 (16.4) 29 (18.1)
All 3 (100) 5 (100) 38 (100) 59 (100) 55 (100) 160 (100)

Values are presented as number (%).

a Others contain patient reported outcome, digital phenotype, and so on.

Table 2
Data demands for AI development
Hospital Industry Academia All
CT/MRI 45 (27.6) 8 (16.7) 16 (20.5) 69 (23.9)
Lab data 36 (22.1) 10 (20.8) 13 (16.7) 59 (20.4)
Genome 10 (6.1) 4 (8.3) 12 (15.4) 26 (9.0)
Vital 22 (13.5) 7 (14.6) 13 (16.7) 42 (14.5)
Radiology/pathology reports 23 (14.1) 9 (18.8) 10 (12.8) 42 (14.5)
Free text reports 25 (15.3) 9 (18.8) 10 (12.8) 44 (15.2)
Othersa 2 (1.2) 1 (2.1) 4 (5.1) 7 (2.4)
All 163 (100) 48 (100) 78 (100) 289 (100)

Values are presented as number (%).

AI: artificial intelligence.

a Others contain patient reported outcome, digital phenotype, and so on.

Table 3
Solution demands for AI development
Hospital Industry Academia All
Diagnosis prediction 35 (32.4) 8 (32.0) 14 (36.8) 57 (33.3)
Prognosis prediction 32 (29.6) 8 (32.0) 13 (34.2) 53 (31.0)
Monitoring 16 (14.8) 5 (20.0) 6 (15.8) 27 (15.8)
Treatment plan recommendation 21 (19.4) 4 (16.0) 4 (10.5) 29 (17.0)
Othersa 4 (3.7) 0 (0) 1 (2.6) 5 (2.9)
All 108 (100) 25 (100) 38 (100) 171 (100)

Values are presented as number (%).

AI: artificial intelligence.

a Others contain education material for students, solution for the text processing.

Table 4
Comparison of major topics by affiliation in the expert interviews
Hospital Industry Academia All
Partnership 2 (5.0) 5 (10.6) 0 (0) 7 (6.3)
Education 3 (7.5) 6 (12.8) 7 (28.0) 16 (14.3)
Analysis technology 9 (22.5) 9 (19.1) 4 (16.0) 22 (19.6)
Data 20 (50.0) 11 (23.4) 9 (36.0) 40 (35.7)
Regulation 6 (15.0) 16 (34.0) 5 (20.0) 27 (24.1)
All 40 (100) 47 (100) 25 (100) 112 (100)

Values are presented as number (%).

Table 5
Keywords of expert interviews
Hospital Industry Academia
Data Efficiency evaluation Data security
Data certification AI clinical application Deregulation
Clinical decision support system Deregulation Anonymity
Data standardization Data open Pseudonymization
Common data model Manpower
Vitalization the private-led market
Minimize government intervention
Partnership with foreign institutions

AI: artificial intelligence.

Table 6
Identified issues and requirements of stakeholders
Issue Requirement
Laws & regulations Clarify the related laws and regulations
Strengthen the privacy protection using the advanced technologies
Utilizing data Build the FAIR healthcare big data at national level
Establish data governance organization
Reimbursement Reimburse AI SaMDs
Human resource development Need long-term educations on AI4H

FAIR: findable, accessible, interoperable, and reusable, AI: artificial intelligence, SaMD: software as a medical device, AI4H: artificial intelligence for healthcare.

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