Research Registries: A Tool to Advance Understanding of Rare Neuro-Ophthalmic Diseases

State-of-the-Art Review Section Editors: Valérie Biousse, MD Steven Galetta, MD Research Registries: A Tool to Advance Understanding of Rare Neuro-Ophthalmic Diseases Kimberly D. Blankshain, BS, Heather E. Moss, MD, PhD Background: Medical research registries (MRR) are organized systems used to collect, store, and analyze patient information. They are important tools for medical research with particular application to the study of rare diseases, including those seen in neuro-ophthalmic practice. Evidence Acquisition: Evidence for this review was gathered from the writers' experiences creating a comprehensive neuro-ophthalmology registry and review of the literature. Results: MRR are typically observational and prospective databases of de-identified patient information. The structure is flexible and can accommodate a focus on specific diseases or treatments, surveillance of patient populations, physician quality improvement, or recruitment for future studies. They are particularly useful for the study of rare diseases. They can be integrated into the hierarchy of medical research at many levels provided their construction is well organized and they have several key characteristics including an easily manipulated database, comprehensive information on carefully selected patients, and comply with human subjects regulations. MRR pertinent to neuro-ophthalmology include the University of Illinois at Chicago neuro-ophthalmology registry, Susac Syndrome Registry, Intracranial Hypertension Registry, and larger-scale patient outcome registries being developed by professional societies. Conclusion: MRR have a variety of forms and applications. With careful planning and clear goals, they are flexible and powerful research tools that can support multiple different study designs, and this can provide the potential to advance understanding and care of neuro-ophthalmic diseases. Journal of Neuro-Ophthalmology 2016;36:317-323 doi: 10.1097/WNO.0000000000000391 © 2016 by North American Neuro-Ophthalmology Society Chicago Medical School (KDB), Rosalind Franklin University of Medicine and Science, Chicago, Illinois; and Departments of Ophthalmology and Visual Sciences (KDB, HEM) and Neurology and Rehabilitation (HEM), University of Illinois at Chicago, Chicago, Illinois. Supported by NIH Grants K12 EY 021475, K23 EY 024345, P30 EY 001792, and UL1RR029879, unrestricted departmental grant from Research to Prevent Blindness. The authors report no conflicts of interest. Address correspondence to Heather E. Moss, MD, PhD, Department of Ophthalmology (MC 648), 1855 W Taylor Street 3.158, Chicago, IL 60612; E-mail: hemoss@uic.edu Blankshain and Moss: J Neuro-Ophthalmol 2016; 36: 317-323 T he Merriam Webster Dictionary defines registry as "a book or system for keeping an official list or record of items." It logically follows that a medical research registry (MRR) is an organized system that is used to collect, store, and analyze patient information related to specific diseases, conditions, or outcomes for the purposes of research (1). Registries are popular research tools, with over 5,000 publications in PubMed that reference "registry" in the last 5 years. They are usually observational, containing information collected as part of clinical care. They are typically prospective, with data being recorded as it is collected, rather than abstracted from the chart at a future date (2). They can be cross-sectional, with a single snapshot of data for each participant or longitudinal with more data added over time. They can contain deidentified data or be coded to facilitate longitudinal data collection. RESEARCH REGISTRIES AS A RESEARCH METHODOLOGY The ubiquitous hierarchy of the research study design (Fig. 1) ranks the strength of evidence offered by different study designs, with quality of evidence (as it pertains to clinical care) increasing as the apex is approached (3). It should be emphasized that a research registry is not a study design, but rather an important tool that organizes clinical observations for research purposes. As such, it can support the study design of the investigators' choice. With reference to the hierarchy of research studies, a research registry can be considered a collection of case reports. Combining multiple cases from the registry can create a case series. Registry data can be used in more rigorous study designs by comparing across participants. For example, participants in a registry can be divided into cases and controls based on a particular feature (either baseline or outcome) and outcome or exposure compared between these groups. Alternatively, outcomes of a group of participants in a registry can be compared according to baseline defining features as a cohort study. Research 317 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. State-of-the-Art Review FIG. 1. Research pyramid. A representation of the types of human-based medical research studies that contribute knowledge regarding human health and disease. RCT, randomized clinical trials. registries can facilitate both of these latter kinds of studies in rare diseases (1). It is important to remember that the quality of these studies depends on the quality of the registry and that any selection bias or data misclassification bias inherent in the registry will impact study validity. Research registries can support randomized controlled trials (RCT) by providing important baseline data necessary for planning (e.g., sample size calculation). Additionally, registries can be used as a recruitment tool for RCTs if they incorporate a database of patients interested in participating in studies. This can ease the burden of trial recruitment, which is particularly difficult when a rare disease is being studied (4). Some have taken this a step further to use an established registry as the source of participants, baseline and follow-up data for a superimposed RCT. In these socalled randomized registries, the cost and logistics of a comparable free-standing RCT are dramatically reduced by leveraging existing registry infrastructure and resources (5). Alternatively, a registry can be created specifically for the purpose of conducting an RCT. A registry RCT can be much less expensive than a stand-alone RCT, and can accommodate more relaxed enrollment, treatment and data collection parameters than a stand-alone RCT. Although not appropriate for all treatment comparisons, it can be particularly useful for comparison of "real-world" outcomes between 2 or more approved treatments (6). TYPES OF (RESEARCH) REGISTRIES Registries are defined by the inclusion criteria applied to the enrolled participants and the type of captured data. They lend themselves to different applications. Although some registries may not be primarily designed for research purposes, many have this as a potential secondary application. Primary registry purposes other than research include surveillance and quality control. 318 Disease-based registries include participants with a certain diagnosis and can be used to study the epidemiology of diseases. These range from small ones like the European PedNet Haemophilia Registry (1) that contains just over 1,000 participants to large, broadly based databases such as the Surveillance, Epidemiology and End-Results (SEER) Program run by the National Cancer Institute that is the most comprehensive cancer registry of its kind. It began collecting data on cancer incidence and survival in 1973 and continues to actively collect data that cover 28% of the US population (7). The SEER program uses 18 population-based cancer registries across the United States (10 state registries, 5 metropolitan registries, and 3 Native American registries) and centralized database management software to collect its data. These data are periodically compared with census data to compare baseline characteristics with the general population. The information contained in the registry has been used to publish articles on cancer care/ treatment, cancer screening, cancer prevention, genetics, health disparities, and other aspects of cancer epidemiology. Investigations can stray far from traditional cancer epidemiological investigations. For example, in 1990, researchers from the SEER program published an article on the public health impact of the media coverage of colon cancer after Ronald Reagan was diagnosed with the disease (8); and in 2002, an SEER-related article was published on the overdiagnosis of prostate cancer due to prostate-specific antigen screening using incidence data of the disease (9). Surveillance registries include participants who have had certain tests and have particular application to public health as they can be used to monitor patients across care settings and monitor health across a region (10). Maintaining patient privacy is an important consideration in the design of such registries. For example, the New York City Board of Public Health created a mandatory registry for reporting laboratory results of hemoglobin A1C tests as a way to monitor diabetes in a large urban environment (11). Analysis of the registry data allows identification of features associated with poor disease control, which can inform program development with the goal of improving patient care and diabetes outcomes. A secondary capability of such registries is that they allow for comparison of care providers and sites, although these can be easily confounded by other factors that vary between sites such as disease severity and patient compliance. Risk adjustment, done through consideration of variables other than site of care that affect outcome, is one way to adjust such confounding. There is also a concern for these comparisons to produce legal repercussions for physicians or to impact reimbursement. One example of research that has come out of this registry is an RCT that studied the effectiveness of a telephone intervention improving glycemic control in patients who were in the registry (12). Provider care- or site-based registries include participants who received care from certain providers or sites and have Blankshain and Moss: J Neuro-Ophthalmol 2016; 36: 317-323 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. State-of-the-Art Review application to study of care delivery and quality improvement. Although data of this kind are critically important to advance research in the area of health care delivery, many are skeptical that the data will be applied for monitor and reimbursement purposes, which limits voluntary participation. An example of this is the American College of Surgeons National Surgical Quality Improvement Program (NSQIP), which uses a registry of information from patients who had seen particular surgeons to create specific surgeon profiles and assess quality of individual surgeons preforming various operations (13). Product registries include participants exposed to a certain product (e.g., medication, medical device). Theses not only have specific application to safety assessment but also can provide an important source of data for effectiveness evaluation. The Israeli ICD (implantable cardiac-defibrillators) Registry encompasses information on all ICD implants and other ICD operative procedures throughout Israel. This registry has been used to perform research on the rate of appropriate life-saving ICD shock therapies (14). Recruitment registries are databases of potential subjects and/or potential projects that can be searched to help match eligible participants with appropriate studies. The Research Match program at University of Illinois at Chicago was started in 2009 as a means of helping researchers find participants for their projects (15). Additionally, patients who are interested in participating in research can find projects for which they are eligible. This process also facilitates research by having some of the initial subject registration steps complete before the subject ever meets the research team (16). The concept of "big health data" or data warehouse is similar to the idea of a research registry. A data warehouse consists of integrated health data from multiple sources on a large scale. One example is merging electronic medical record (EMR), scheduling, billing, and prescription filling data at the patient level. Currently, data warehouses are used for retrospective research, which can define real-world treatment patterns and responses. With these large databases, it is important to ensure that patient information is being stored and access is being regulated so that patient privacy is not being breached. In the future, data warehouses could integrate financial, social media, and other lifestyle data to add further dimensions that may be relevant for medical research and increase privacy concerns (17). A further extension of data warehouses is the Informatics for Integrating Biology and the Bedside (i2b2) database that is run by the NIH. This is a national project that is working to connect multiple data warehouses together to allow researchers to easily access and integrate large amounts of data (18). CHARACTERISTICS OF EFFECTIVE RESEARCH REGISTRIES A research registry is a collection of research data, and, as such, it should be designed and evaluated with the same Blankshain and Moss: J Neuro-Ophthalmol 2016; 36: 317-323 criteria used to design and evaluate data collection. An effective research registry from a process standpoint is one into which data can be easily entered, safely stored, easily manipulated, and easily retrieved. It is also important to carefully plan participant selection and data points to be recorded, being careful to minimize effects of bias on future research applications of the information. Human subjects regulations must be considered including the Belmont Report principles of respect for persons, beneficence, and justice. These issues must be considered during registry design, to be sure that subsequent publications are not rejected for failure to comply with regulations. Informed consent is variably necessary depending on the design of the registry. For a research registry consisting of strictly deidentified data, such as the SEER registry, informed consent may not be required. However, when identifying information is stored, for example, to permit linkage with other sources of information or follow-up, written informed consent may be required. In the United States, institutional review boards and/or human subjects committees can provide clarification and approval. Participant selection is an important design consideration for a research registry because this will contribute to both the external validity (generalizability) and internal validity (bias) of any studies based on the registry. If the registry participants do not share similar baseline characteristics with the population, they are purported to represent, then the outcome of any resulting research will not be fully generalizable. Although it can be difficult to completely eliminate selection bias, for example, one cannot include individuals who have not been diagnosed with a disease in a disease-based registry, it is important to take steps to minimize this in the planning stages and to characterize/acknowledge in the research phase. Some registries, often those of very rare conditions, may be based on voluntary reporting, and therefore can have substantial selection bias. These still have the potential to support research, for example, on the range of case features, even if they are less applicable for hypothesis-driven projects. Data management is an important consideration in any research pursuit, and is especially important for MRR, which, by definition, contain protected health information. Issues of ease of data management, data security, and cost must be considered. A commonly used platform is the Research Electronic Data Capture (REDCap), a Web-based system that can be used to build and manage secure forms for data entry and storage that is typically managed centrally (19,20). This platform includes query tools that facilitate export of deidentified data for desktop analysis (e.g., using spreadsheet or statistical packages). REDCap is broadly implemented at multiple institutions in the United States and abroad (21). Additionally, there are other programs similar to REDCap, which include Medrio (22) and OpenClinica (23). A research registry needs to contain information that is comprehensive and complete for it to be used effectively as 319 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. State-of-the-Art Review a data set. This must be considered in the planning stages and may require intermediate steps to organize and code the data. A registry containing only clinical data could fail to meet standards for defining certain diagnoses or examination findings in a future research endeavor (24). Furthermore, significant data manipulation is required to extract data points from paper clinical records or free-text electronic records to create a meaningful database. Some investigators may be able to take advantage of their electronic medical record's collection of "minable" data. Many institutions now have data warehouses that have compiled and integrated patient data from multiple sources to facilitate this. For example, the University of Utah has a Data Resource Center, which electronically houses patient visit, and clinical and financial data in one place (25). CASE STUDY: THE UIC NEURO-OPHTHALMOLOGY REGISTRY The University of Illinois at Chicago (UIC) NeuroOphthalmology Registry was developed in response to 2 challenges faced in our research efforts involving human subjects. First, we struggled with identifying research subjects for prospective studies. In particular, we found relying on appropriate patients to be seen in clinic to be unpredictable and that many eligible and interested patients often declined because of not planning for a longer visit and not wishing to return for an extra visit. Second, we found the use of billing records to be an unreliable way to identify patients for retrospective studies. Therefore, the UIC registry was designed with 2 parts-a database of potential subjects for future investigational projects and a database of longitudinal clinical information for use in future retrospective studies. The registry structure and procedures were developed in consultation with our institutional review board to ensure compliance with human subjects regulations. It was determined that because our data collection is prospective and because we record identifying information for the purposes of contacting patients who have expressed interest in future research participation, that prospective, written informed consent was necessary. Due in part to involvement of appropriate experts on the front end, our human subjects protocol was easily approved. Although the overall population of interest is individuals with neuro-ophthalmic diseases, for practical reasons, the population from which we are sampling is patients receiving neuro-ophthalmic care at our institution. We recognize and acknowledge the selection bias implicit in this design decision. There is a second level of selection bias within our registry because our current requirement for informed consent excludes potential subjects who are unable and/or unwilling to provide informed consent. We assessed the extent of this bias through demographic analysis of the registry participants compared with clinic attendees and found that older and Hispanic patients were underrepre320 sented in the registry compared with the clinic population (26). This bias is attributable to our consent procedures, and we are exploring options to enable informed consent in other languages besides English and by designates in cases in which the patient lacks capacity to provide consent. There was no demographic bias of patients unwilling to provide informed consent compared with the clinic population. Our current workflow for enrollment is as follows. A research assistant screens the clinic schedule in advance and flags all nonenrolled patients. At the conclusion of each clinic encounter, the provider discusses the registry with any patient who is flagged, stressing that it is voluntary and separate from clinical care. This takes 1-2 minutes. Interested patients are immediately escorted to a research assistant who obtains written informed consent and collects background data. Strengths of this system include minimal impact on clinic flow and high recruitment yield. Weaknesses of this system include the requirement for an on-site research assistant and space during clinic hours. We found that having the provider completing the informed consent adds an additional 5-10 minutes to each clinic visit, making it impractical from a clinic flow perspective. We also found that distributing an institutional review board-approved recruitment flyer to clinic attendees to solicit volunteers did not generate very many volunteers. On occasion, we have given patient study enrollment materials to take home, and we have found that these rarely convert to an enrollment. For data management, we are using Research Electronic Data Capture (REDCap), a Web-based system that is hosted centrally at our institution. Multiple research assistants have found the platform to be user-friendly for building, maintaining, and querying the databases. At this time, many of the fields in our database consist of free-text fields, which facilitate direct copy from our EMR. After enrollment, data from the initial enrollment form and EMR are copied into REDCap. After follow-up visits, updated data are copied from the EMR into REDCap. Two shortcomings of our current database are the restriction to clinical data, which is subject to missing data if certain parameters were not recorded clinically, and predominance of free-text entries, which limits searchability. To improve our database, we are working to code the free-text fields, starting with patient symptoms, signs, tests, and diagnoses. This will facilitate database queries. Although Current Procedural Terminology (CPT), Systematized Nomenclature of Medicine-Clinical Terms (SNOMED), Unified Medical Language System (UMLS) codes, and International Classification of Disease codes associated with the records help to some extent, we have found that they are lacking with respect to many neuroophthalmology details. We are developing a list of relevant neuro-ophthalmic codes through an iterative process between the research assistant and provider based on enrolled patient records. Our goal is to compile coding pages that the provider can quickly complete/confirm for each patient at the time of enrollment and follow-up. Blankshain and Moss: J Neuro-Ophthalmol 2016; 36: 317-323 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. State-of-the-Art Review We have begun to use the registry for the purposes of recruitment for prospective studies. To accomplish this, the database is queried for the diagnosis of interest to generate a list of potential subjects. These individuals are contacted through phone and e-mail. The yield has been higher than it was using our prior strategy of screening clinic patients for potential participation. We attribute this to restricting our efforts to patients who have previously agreed to entertain participation in a study and being able to provide advance notice about time commitment. care costs associated with IIH (29). Another was published in the Journal of Women's Health concerning the association between weight gain and the appearance of new visual field defects (30). A recent study examined the association between acetazolamide and nephrolithiasis (31). Again, a registry of this kind is useful as IIH is a relatively rare disease affecting only approximately in 100,000 people. A similar registry is being instituted in the United Kingdom (32). EXAMPLES OF REGISTRIES RELEVANT TO NEURO-OPHTHALMOLOGY The National Registry of Drug-Induced Ocular Side Effects was established in 1976 and is currently funded by the Casey Eye Institute at the University of Oregon and the American Academy of Ophthalmology (AAO). Its goal is to create a comprehensive database of information on adverse ocular side effects of drugs, chemicals, and herbals through the use case reports to identify the earliest signs of adverse reactions. It has an easily accessible Web site through which physicians can submit case reports using a standardized form. No specific identifying patient information is requested on the form, so it seems that individual physicians and their patients must not complete a consent process. The registry also builds its database by monitoring reports sent to the World Health Organization, the Food and Drug Administration, and pharmaceutical companies. Information gathered from the registry has been used to publish a book, "Drug-Induced Ocular Side Effects" that physicians can purchase for reference (33). The registry Web site also provides a drug consent form that physicians can use to help educate their patients on potential side effects of medications they may be taking and provide a way for physicians to obtain informed consent from a patient before prescribing a specific drug. An example of a research application from this type of registry is a study on the ocular side effects of a drug, such as optic neuritis associated with the use of adalimumab (34) or bortezomib therapy and eyelid chalazia (35). Susac Syndrome Registry The Susac Syndrome Registry is a 2-part disease-based registry run by the Cleveland Clinic and designed to study the natural history of Susac syndrome, a rare disease with approximately 310 cases reported in the literature as of 2014. The registry is composed of both a retrospective/ prospective cohort database and a list a patients who are interested in participating in future research endeavors. Patients from across the world can either be referred to the study by their physicians or self-enroll in the study. REDCap is used to manage the databases. The consent process involves the participant contacting the research team, signing a consent form and signing a medical records release form. The research team then obtains the participants' medical records and transfers them to the secure, deidentified REDCap database (27). Intracranial Hypertension Registry The Intracranial Hypertension (IH) Registry was established in 2003 in partnership with the Oregon Health and Science University as an exclusively research oriented, disease-based registry designed to further our knowledge of IH and attempt to find more effective treatments for the disease (28). It is an international registry with 2309 enrolled patients from 26 different counties. It comprises both a patient information database and neuro-imaging library with over 8,000 imaging studies from patients with both idiopathic IH (90% of enrolled patients) and secondary IH. Patients can either be referred to the registry by their physician or self-enroll in the registry. At the time of enrollment, patients are sent paperwork explaining the registry, a consent form, authorization for medical records, and a patient questionnaire. Before enrollment, the research team verifies the diagnosis of IH by reviewing the patient's medical records. Patients are contacted annually by the registry team with a questionnaire and repeat authorization for updated medical records. The data are managed in a secure, deidentified database with REDCap (E. Tanne, personal communication). As of 2010, information in its database has been used to publish 2 studies. One study was published in Obesity Review concerning the health Blankshain and Moss: J Neuro-Ophthalmol 2016; 36: 317-323 National Registry of Drug-Induced Ocular Side Effects IRIS and Axon Registries The AAO implemented the Intelligent Research in Sight Registry (IRIS) in 2014 as a comprehensive outpatient clinical registry of ophthalmologic diseases (36). IRIS is a physician-centered registry with an emphasis on physician education and quality improvement. As part of its quality care emphasis, it allows physicians to report to the federal Physician Quality Reporting System (PQRS). The AAO intends to use information gathered from the registry to plan new continuing medical education (CME) courses for ophthalmologists. The registry also plans to give physicians' feedback and information about their practices. For example, from the AAO Web site, "What is the rate of return to the operating room for patients undergoing cataract surgery?" (37). Additionally, it can be used both to further advances in knowledge on the diagnosis and management of eye 321 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. State-of-the-Art Review diseases and as a tool to assess physicians and educate them on best practices (38). IRIS is designed as a centralized system through which physicians are able to enter information about their patients with little impact on their overall workload (39). For those physicians whose practices use an electronic health records system (EHR), deidentified data can be pulled directly from their EHR to the IRIS database after the proper software has been installed. Because the data are deidentified and a purpose is quality improvement, there is no consent process with patients. An early publication from the IRIS database highlights how IRIS data can be combined with Medicare claims records to identify areas of quality improvement; specifically, with regard to cases of endophthalmitis after cataract surgery and monitoring outcomes after less common surgical procedures like cataract surgery combined with vitrectomy (40). The American Academy of Neurology (AAN) is currently implementing the Axon registry. It will be similar to the IRIS registry as it is a physician-based registry with a main focus on physician education and quality improvement. It also will allow physicians to report to the federal PQRS. The AAN also plans to expand the Axon registry to create CME courses for neurologists. The Axon registry will also be linked with physician's EHR systems to automatically pull data into the Axon database. A major effort has been the development of outcome measures to include in the registry (41). The AAN will only have access to physician and practice data and will not see any individual patient data, so there is no patientinformed consent process (42). FUTURE DIRECTIONS Although there are some disease specific registries relevant to neuro-ophthalmology, not all diseases are represented. The neuro-ophthalmology community would benefit from registries that include more patients and more diseases. One way to minimize the selection bias associated with disease specific registries would be multisite efforts to construct inclusive registries of neuro-ophthalmic patients. This broader effort would support study of all neuro-ophthalmic disease by facilitating identification of patients with rare diseases for prospective trials and establishing large observational cohorts. Construction of a centralized registry might be logistically prohibitive given privacy concerns of transmitting identified data. An alternative would be to have each institution manage its own registry using a standard coding set to facilitate future combining of deidentified data for study purposes. Coordinated institutional neuro-ophthalmic registries would also facilitate randomized registries trials as a way to compare nonnovel treatments in a cost-effective and flexible way. CONCLUSIONS MRR are a means to gather, store, and analyze patient data. Although they have typically been used as prospective, 322 observational tools, they have a variety of forms and applications that can fit into the traditional hierarchy of medical research in different ways. They are particularly useful for studying rare diseases, but are by no means limited to these. With careful planning and clear goals, a research registry can be an invaluable tool in medical research. STATEMENT OF AUTHORSHIP Category 1: a. Conception and design: K. D. Blankshain, H. E. Moss; b. Acquisition of data: K. D. Blankshain, H. E. Moss; c. Analysis and interpretation of data: K. D. Blankshain, H. E. Moss. Category 2: a. Drafting the manuscript: K. D. Blankshain, H. E. Moss; b. Revising it for intellectual content: K. D. Blankshain, H. E. Moss; Category 3: a. Final approval of the completed manuscript; K. D. Blankshain, H. E. Moss. REFERENCES 1. Fischer K, Ljung R, Platokouki H, Liesner R, Claeyssens S, Smink E, van den Berg HM. Prospective observational cohort studies for studying rare diseases: the European PedNet Haemophilia Registry. Haemophilia. 2014;20:e280-e286. 2. List of Registries. 2015. Available at: http://www.nih.gov/ health-information/nih-clinical-research-trials-you/listregistries. Accessed November 24, 2015. 3. Tomlin G, Borgetto B. Research Pyramid: a new evidence-based practice model for occupational therapy. Am J Occup Ther. 2011;65:189-196. 4. Malek AM, Stickler DE, Antao VC, Horton DK. The National ALS Registry: a recruitment tool for research. Muscle Nerve. 2014;50:830-834. 5. 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