Skull Base Registries: A Roadmap

• Abstract
• Introduction
• Sources of Skull Base Clinical Evidence
• Randomized Controlled Trials
• Challenges of Surgical Randomized Controlled Trials
• Skull Base Surgery Randomized Controlled Trials
• Personal, Institutional, and Multi-Institutional Series
• Administrative Database Studies
• Roadmap toward a Skull Base Registry
• Learning from Previous Registries
• Building Consensus
• Implementation
• Conclusion
• References

Abstract

Hospitals, payors, and patients increasingly expect us to report our outcomes in more detail and to justify our treatment decisions and costs. Although there are many stakeholders in surgical outcomes, physicians must take the lead role in defining how outcomes are assessed. Skull base lesions interact with surrounding anatomy to produce a complex spectrum of presentations and surgical challenges, requiring a wide variety of surgical approaches. Moreover, many skull base lesions are relatively rare. These factors and others often preclude the use of prospective randomized clinical trials, thus necessitating alternate methods of scientific inquiry. In this paper, we propose a roadmap for implementing a skull base registry, along with expected benefits and challenges.

Introduction

Before the age of the operating microscope, outcomes for skull base lesions were often poor. At the dawn of the microsurgical era, skull base surgeons focused on building the following fundamentals: anatomy, approaches, and techniques. As experience accumulated over the ensuing decades, attention was directed to the indications and goals of surgery, particularly balancing aggressive treatment with functional preservation, with an increased emphasis on patient-centered quality of life including vision, olfaction, hearing, and cranial nerve function.[1] [2] [3] [4] While this has often led to better outcomes, hospitals, payors, and patients increasingly expect us to report our outcomes in more detail and to justify our treatment decisions and costs. Although there are many stakeholders in surgical outcomes, physicians must take the lead role in defining how outcomes are assessed, as they have the most intimate knowledge of clinical behavior. The outcomes data that are collected should facilitate the development of evidence-based “best practices” and “care pathways” that optimize outcomes and costs, while at the same time preserving our freedom to innovate.[5] [6] Such an effort requires consensus which may be challenging in the field of skull base surgery due to various institutional-related preferences and schools of thought.

Because of the density of critical neurovascular structures within the skull base, lesions here may interact with surrounding anatomy to produce a complex spectrum of presentations and surgical challenges. As a result, a wide variety of surgical approaches are required to address these variations, perhaps more than any other area of human anatomy. Moreover, skull base lesions are significantly less common than other neurological conditions such as disc herniations or stroke. These factors often preclude application of the ultimate tool of evidence-based medicine: the prospective randomized clinical trial. In this paper, we propose a roadmap for implementing a skull base registry, along with the expected benefits and challenges.

Sources of Skull Base Clinical Evidence

Randomized Controlled Trials

Randomized controlled trials (RCTs) are the gold standard and the most rigorous and robust research method for determining whether a cause–effect relationship exists between an intervention and an outcome. Proper randomization ensures that comparison groups are similar in all aspects except for the intervention. This improves the probability that any difference in outcome between groups is caused by the difference in intervention rather than other important factors that influence outcome, some of which may still be unknown. Blinding the patient and treatment team can also reduce bias. This can usually be done for medication-based interventions but not surgical interventions.

Challenges of Surgical Randomized Controlled Trials

There are several practical issues that create challenges for any surgical RCT including recruitment, surgeon and patient preferences, surgeon skill set, rare or infrequent outcomes, and follow-up. These issues are magnified in the field of skull base surgery, given the relative rarity of pathologies, multispecialty care, steep surgical learning curves, and relative lack of standardized outcome measures. A predetermined timeframe for prospective recruitment of subjects into an RCT is a major challenge in this heterogenous group of relatively rare benign and malignant pathologies ([Table 1]).

The principle of equivalency between two interventions, until proven otherwise, is a necessity in RCT design. However, it also removes the surgeon's expertise from the decision-making process which could hamper the patient's trust in the surgeon's decision-making ability and authority over their care.[7] In addition to recruitment, outcomes of surgical trials are deeply dependent on the surgeons participating in the study. A surgeon's particular preference, skill set, and experience are elements of bias and may jeopardize the validity of a surgical outcomes trial, since they may directly impact their decision to participate in the trial or to enroll particular patients.

Multi-institutional study design could mitigate some of these recruitment challenges and make study findings more generalizable. On the other hand, strategies to reduce surgeon-related outcome biases such as “expertise-based design” (patients are only randomized to surgeons who are well trained in all of the procedures in question) or “randomized-surgeon design” (patients are randomized to different surgeons who are experts on the specific procedure being studied) are much more difficult to execute in a large multicenter trial. The high cost associated with multicenter RCTs is also a significant limiting factor.

Another challenge related to RCTs in skull base surgery is the rarity of the event being studied (e.g., mortality), as many skull base pathologies are benign or indolent. When the outcome is rare, the assessment of an intervention's benefit usually requires a very large sample size. A method to overcome the challenge of rare events is to use composite end points which capture patients who experience any one of several events (e.g., reoperation, hospital readmission, and death). This requires a very important assumption that the effect of each of the components will be similar, and patients will attach similar importance to each component.[8] In other words, the validity of composite outcomes is dependent on the similarity of importance to patients, frequency, and relative risks across components.[9] When studying intervention for benign conditions, long-term follow-up is necessary to prove the long-term benefits that justify the upfront surgical risks. The issue of inadequate follow-up has been a significant criticism of RCT's such as Aruba and COSS.[10] [11]

Skull Base Surgery Randomized Controlled Trials

Surgical RCTs in the field of skull base surgery are very challenging to execute for the reasons discussed above. The majority of the current RCT literature in skull base surgery is focused on perioperative management including anesthesia-related issues, use of antibiotics, pain control, and postoperative care. There are only a few studies focused on approach-related outcomes, and there are no studies assessing treatment and tumor-specific outcomes. Relevant RCTs in the field of skull base surgery are summarized in the [Table 2].

A PubMed search for the terms “skull base surgery” reveals a slow increase in the number of publications until the early 2000's with under 300 publications per year. This trend was followed by a significant increase in the number of publications in the past two decades with over 1,500 publications per year in the last 2 years ([Fig. 1]). When the search results are filtered for “Meta-Analysis,” “Review,” and “Systematic Review” we observe similar trend in the increase of publication from 36 articles in 2000 to 203 articles in 2021 ([Fig. 2]). Nevertheless, these types of articles that represent levels of evidence 2 and 3, according to the Oxford Centre for Evidence-Based Medicine,[12] only comprise 13% of the publications in “skull base surgery” in 2021. Interestingly, a similar trend is not observed in level 1 of evidence. When the results are filtered for “Clinical Trial” and “Randomized Controlled Trial” ([Fig. 3]), the number of trials published from 2000 to 2022 is variable ranging from 3 to 18 per year representing an even smaller fraction of the available literature in skull base surgery.

Personal, Institutional, and Multi-Institutional Series

The main body of literature in skull base surgery is comprised of levels 3 to 5 of evidence. The best quality of work among this group is a result of pathology-specific case series or series reporting the use of a particular approach or technique. Personal and institutional series are more common but usually have a limited number of patients due to the paucity of skull base tumors. They also have limited generalizability, given the participation of a single surgeon or few surgeons.

Despite the challenges in coordination and heterogeneity in care protocols, multi-institutional efforts have been able to study larger cohorts for more common skull base tumors such as pituitary adenomas and meningiomas. The Transsphenoidal Extent of Resection (TRANNSSPHER) study is one example of a prospective multicenter effort to compare outcomes between microscopic and endoscopic resection of nonfunctioning pituitary adenomas in adults. Surgeons performing more than 30 transsphenoidal operations at centers with more than 200 cases overall were eligible to participate in this study with the rate of gross total resection as the primary endpoint. Ultimately, it included 15 surgeons from seven centers and 259 unique patients. The study demonstrated with level-3 evidence that there was no significant difference in gross total resection rate or volume of tumor resection between the two surgical techniques. However, it was not able to be completed due to the retirement of two participating surgeons on the microscopic resection arm and the failure to recruit replacements for them.[13]

Similar effort coordinated 40 sites to gather outcomes of 987 patients with tuberculum sellae meningiomas operated through transcranial and transsphenoidal approaches. The study, which was presented as an abstract, showed that use of the transsphenoidal approach for tuberculum sellae meningiomas is increasing and is associated with better visual outcomes and decreased recurrence rates after gross total resection. However, CSF leak rates after transsphenoidal approach remain high.[14] [15] An example of a modern multi-institutional prospective data registry that could be particularly instructive for future registries is the CORISCA initiative for sinonasal malignancies. This incorporates tumor biobanking in a centralized site, oncologic outcomes, and QOL metrics[16]

Administrative Database Studies

The past decade has witnessed an increasing use of administrative databases in the surgical literature to study larger groups of patients. Although the large sample sizes can be enticing to both authors and readers, one must be cautious interpreting the findings with this approach as the content and curation of these database are often lacking which limits their scientific applications. While they offer large numbers, they lack many important details. A common criticism of these studies is “Garbage in, garbage out.”

The NIS database is a part of the Healthcare Cost and Utilization Project, dating back to 1988. It contains diagnosis and procedure codes, patient demographics, total charges, length of stay, discharge status, and hospital characteristics. It samples 20% of discharges from U.S. community hospitals with the goal of reporting national estimates. Only inpatient morbidity and mortality is studied, and readmissions are not tracked secondary to the lack of availability of patient identifiers. The database was redesigned in 2012 to improve the margin of error, but there is still concern that the data are curated solely by nonclinicians and hospital billing. There is no information in this database regarding specifics of presentation, conditions, treatments, or outcomes beyond the index hospital stay.

The surveillance, epidemiology, and end results (SEER) cancer database began collecting data in 1973 in geographic regions chosen to mimic the general population.[17] Initially, Caucasian patients represented a high proportion of the patients, although, over time, it was expanded and adjusted to better reflect ethnic and racial diversity. It currently represents 48% of the U.S. population. Data collected include patient demographics, primary tumor site, tumor morphology, stage at diagnosis, first course of treatment, and survival. In addition to lack of clinician involvement in data curation, another concern is the lack of central pathology review, and the lack of policies on how malignant central nervous system (CNS) tumors are reported. Reporting of surgery, radiation therapy, and chemotherapy lack important details that may impact outcomes and thus significantly limit the usefulness of any conclusions derived from this database.

As a clinical database, the American College of Surgeons—National Surgical Quality Improvement Project (ACS-NSQIP) is superior to administrative databases with respect to accuracy. However, the use of databases such as ACS-NSQIP to address the important questions of our specialty is difficult because it was not constructed with input from skull base surgeons, hence there is a lack of relevant disease-specific variables.

Roadmap toward a Skull Base Registry

Although registries cannot match the power of RCTs to address head-to-head comparisons, they facilitate accrual of relatively rare cases into a series that demonstrates the spectrum of disease behavior, practice patterns, and treatment responses. These are usually designed by physicians with expertise in the conditions and their treatments, so appropriate disease-specific variables are much more likely to be included than in administrative databases. Registries may allow quick identification of a subgroup of patients that can be recruited into an RCT. For example, skull base chordomas cases, which have very limited treatment options, could be quickly identified when a promising new intervention becomes available, accelerating enrollment into the RCT.

Learning from Previous Registries

There are several prospective surgical registries that have been developed by neurosurgeons. The largest are the Quality Outcomes Database (QOD) which includes degenerative spine conditions, brain tumors, and neurovascular diseases; the Stereotactic Radiosurgery (SRS) registry, and Registry for the Advancement of Deep Brain Stimulation in Parkinson's Disease (RAD-PD). The American Spine Registry (ASR) is a collaborative effort between neurosurgery and orthopaedic surgery which seeks to expand enrollment volume compared with QOD, although with more limited follow-up. These registries represent broad geographical regions across North America and have structured administration, coordination, and auditing to ensure completeness and accuracy. They are designed to track the outcomes of neurosurgical procedures and place them on an evidence-based footing that can withstand the scrutiny of all stakeholders. The data from these large registries can also be used to guide clinical decision-making and cost-effectiveness initiatives. Although the spine registry is the largest, the tumor registry is most relevant to this discussion. This registry contains six categories, including intracranial metastasis, high-grade glioma, low-grade glioma, meningioma, pituitary tumor, and other intracranial tumors. These categories are divided and tracked based on general anatomical location, rather than disease type or invasion of surrounding anatomical structures, factors that are vital in clinical decision-making for the skull base surgeon. The outcomes measured in the QOD Tumor Registry include LOS, discharge disposition, inpatient complications, and patient-reported outcomes (PROs). This registry a good starting point for a national registry for intracranial tumor and sets a good model for organization, auditing, and oversight for maintaining a quality high-volume database. However, it is limited in its clinical decision-making utility, as it fails to account for determinants of extent of surgical resection and neurological outcome in patients with complex skull base lesions. Given the nature of skull base lesions, details of anatomical involvement, disease pathology, as well as anatomical approach, are important determinants of outcome and factors pertinent to research investigations.[18] Tracking lesions in such detail would involve the development of numerous data collection schemes up front at the time of registry development.

Mayo Clinic describes a system across their multicity hospital system, Mayo Clinic Enterprise Neurosurgery Registry. The database includes categories of cranial, spine, peripheral nerve, and revision surgeries. The cranial category subdivides lesions by broad anatomical region, not specific pathology or anatomical detail. In this registry, the electronic health record (EHR) is directly linked to the central database, allowing data to be automatically pulled from the EHR and recorded in the database. This facilitates efficiency by minimizing the need for manual chart review and manual entry into the database. This system allows integration of computerized adaptive testing (CT) questionnaires and their automated scores assessing patient reported outcomes to be input directly into the EHR. The registry involves a multidisciplinary team for technical support, administration, and clinical oversight to monitor for clinical relevance and completeness in data collection, somewhat like the QOD registries. Designated teams at each clinical site aim to increase patient enrollment in the online patient portal where patients would participate in the CT survey questionnaires. Alternatively, patients would complete questionnaires electronically on arrival for their in-person initial clinic visit and at designated time intervals following any surgical intervention. This model at Mayo was also expanded to include the creation of a “dashboard report,” summarizing provider productivity, total cost, and charges from a given provider or clinical site, providing an example of how large and detailed registries can be utilized to analyze and streamline health care costs.[19]

Building Consensus

“Not everything that can be counted counts, and not everything that counts can be counted.”

Perhaps the most difficult part of laying the groundwork for a registry, particularly one that includes a wide variety of pathologies and treatment strategies, is building consensus on what data to collect at each phase of the patient's timeline. We must first characterize the patient's condition at the time of diagnosis and at future points in time that are determined by a protocol or by clinical events. This typically involves grading scales and classification schemes, both objective and patient reported. Commonly used indicators of overall health include age, comorbidities, the Karnofsky Performance Status, American Society of Anesthesiologists (ASA) Class,[20] and quality of life instruments such as the Euroqol Five-Dimensional Questionnaire (EQ-5D). But it is usually also necessary to characterize the status of the lesion, including anatomical involvement, radiographic features, and disease-specific symptoms that have a significant impact on the anatomical approach, extent of maximal safe resection, and associated morbidities.[2] [21] [22] [23] [24] [25] Clearly, radiologic assessments will play an extremely important role in a successful skull base registry, but these are still lacking in some areas. In particular, our increasing ability to visualize cranial nerve involvement will hopefully lead to a consensus on classification systems for perineural spread of skull base lesions that have clinical or prognostic significance.[26]

The Knosp classification scheme for cavernous sinus invasion by pituitary lesions is an example of an attempt to create clinically meaningful categories of anatomical involvement, which has been shown to be related to the extent of surgical resection achieved.[27] [Table 3] lists common skull base lesions and the anatomical classification scales that attempt to describe them with concise uniform scoring systems. There are some lesions presented in this table that do not have widely accepted scales for characterization.

There are several objective scales for neurological function that may be relevant to a skull base registry. The Gardner–Robertson Scale and American Academy of Otolaryngology—Head and Neck Surgery hearing test[28] [29] combine pure-tone averages and speech discrimination to define categories of auditory nerve function that are clinically relevant to patients harboring a vestibular schwannoma. The House–Brackmann[30] facial paralysis scale is widely used to report facial nerve weakness. However, there are not widely adopted objective scales in place for reporting and measuring all relevant neurological deficits encountered in skull base surgery. The objective scales found in our search of the literature are represented in [Table 4]. This illustrates several gaps in assessment, including the lack of scales that measure the motor and sensory function of the trigeminal nerve, as well as lower cranial nerve function. On the other hand, there are two widely used scales for trigeminal nerve pain.

Subjective, patient-reported outcome measures (PROMs) that may relate to specific symptoms, such the visual analogue pain scale (VAS), or general quality of life, such as the EQ-5D, collect important information about the impact of disease that may not be captured by the clinician during office visits. Nondisease-specific measures also allow ranking the impact of interventions in various medical subspecialties on quality of life which could have implications in a healthcare rationing environment. Several relevant patient reported scales and outcome measures are represented in [Table 5].

After arriving at a consensus on how to characterize lesions, we must agree how on how to characterize the treatment that is delivered. At a minimum, this should include details of what approach(es) was used, extent of resection, texture of the lesion, technique used to address the lesion, preservation of neurovascular structures, blood loss, duration of surgery, and complications. For malignancies, this should also include details on histopathologic findings, adjuvant therapies, recurrence and survival. For radiosurgery, this should include dose and the treated isodose line, and for fractionated radiation, the treatment volume, total dose, and number of fractions. Ideally, the various costs associated with the treatment should be collected, though this can often be difficult to define due to the complexities of hospital charging algorithms for various payors.

Finally, there should be consensus on how to measure outcomes at various points in time. Typically, assessments used to describe the patient's condition at baseline should be repeated during follow-up evaluations. There will also be a need to collect new data that measures complications of the treatment, such as a postoperative cerebrospinal fluid leak or delayed radiation effects. We must carefully assess whether the classification schemes we employ capture all the important aspects of the conditions that we are assessing. In some cases, we may need to devise new assessments.

Implementation

Before final implementation of a data collection system, bylaws regulating the use of the data should be established. In some cases, each institution may own their own data, but may be required to obtain approval from the registry before publishing their institutional series. Guidelines regarding authorship for registry papers should also be discussed and agreed on before data collection begins. Some journals limit the number of authors that can appear on a paper which creates additional logistical challenges for large collaborative studies. Finally, operational costs should be clearly understood and funding sources secured. Funding may come from grants, industry, professional societies, and participating institutions, each of which must be sustained through ongoing effort.

Once consensus has been achieved to determine what information should be collected, the next step is to build a functional repository to hold the actual data to be analyzed. There are several existing options which are commonly employed to collect and store data. Data from multi-institutional clinical studies are typically stored in an online database such as REDCap (Nashville, Tennessee, United States) which provide web-based forms that can be built and deployed according to a protocol. Alternatively, personal database files built using software such as Microsoft Access or Filemaker Pro can be used. The most accessible, though rudimentary, method is to use a spreadsheet with columns for each data element and rows for each observation event. As long as the same data elements are collected, data from each of these systems can be combined for later analysis.

There are varying costs, security considerations, and backup strategies associated with each of these types of repositories. In an age when security breaches are reported on a daily basis, simple password protection to protect acquired data are inadequate. Advanced encryption and two-factor authentication should be considered to protect clinical data and to remain compliant with institutional regulations. Additionally, data redundancy and a sound backup strategy should be a consideration with any future registry, giving cloud-based systems, such as REDCap or other similar solutions, a significant advantage over spreadsheet files or standalone databases which can be more easily deleted, overwritten, or corrupted.

The most labor intensive and expensive aspect of building a registry is usually data collection which often involves directing personnel to abstract data from clinical records and enter it into a database. This person also serves as a semi-independent third party who may obtain more truthful answers from patients during follow-up interviews since some patients may minimize their symptoms to avoid disappointing their doctors. Traditionally, patient-reported data has been collected on forms that are filled out during clinic visits or through a telephone interview. Although telephone interviews generally produce high quality data, they are labor intensive and thus more costly. More recent alternatives include tablet entry in the clinic or hospital setting, though the patient may not be present for such visits during the desired time point in the protocol. Finally, web-based forms linked to a patient portal can be solicited with emails, or outcome data can be entered into a dedicated phone application.

Conclusion

Skull base lesions can be difficult to study because they vary significantly in presentation, anatomical involvement, and treatment approaches. Moreover, there is still no consensus on how to characterize these lesions, the interventions used to treat them and assessments of outcomes. Many of these lesions are rare, making it difficult to collect sufficient numbers for each type of presentation and treatment approach. Despite these difficulties, the value of skull base procedures will need to be proven in the current climate of rationing and cost reduction. Therefore, we should combine our data in skull base registries that make it easier for us to learn from our collective experiences. Increasingly, machine learning will be used to predict outcomes and augment decision-making, and a registry is our best option for creating the quantity and quality of data that will make this possible. Even so, it may take decades to accumulate enough data to answer certain questions. There are significant challenges, but the rewards will justify our efforts. We should begin as soon as possible.

Conflict of Interest

None declared.

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Address for correspondence

Publication History

Received: 13 August 2022

Accepted: 29 August 2022

Accepted Manuscript online:
31 August 2022

Article published online:
12 November 2022

© 2022. Thieme. All rights reserved.

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

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