Need for Percent Area Reduction and Percent Volume Reduction Measurements in Diagnostic Wound Imaging: A Statement From the Wound Care Collaborative Community—Part 1

Innovations in Research Methods and Reporting

Need for Percent Area Reduction and Percent Volume Reduction Measurements in Diagnostic Wound Imaging: A Statement From the Wound Care Collaborative Community—Part 1

Keywords

Percent Area Reduction

Percent Volume Reduction

Wound Imaging

diagnostics

February 2024

ISSN 1943-2704

Index Wounds. 2024;36(2):A3-A6. doi:10.25270/wnds/360224-2

© 2024 HMP Global. All Rights Reserved.

Any views and opinions expressed are those of the author(s) and/or participants and do not necessarily reflect the views, policy, or position of Wounds or HMP Global, their employees, and affiliates.

What is the WCCC doing about recognizing that wound PAR and PVR are very important endpoints, in addition to complete wound closure rates?

The Wound Care Collaborative Community is a non-profit, volunteer, collaborative group of clinicians, health systems, researchers, government agencies, payers, industry manufacturers, and patients closely engaged with the US FDA and Centers for Medicare and Medicaid Services. The WCCC is working to support innovation in the field through expansion of FDA-accepted trial outcomes. We are exploring the ongoing initiatives undertaken by the WCCC TWG. One of the primary focuses of the TWG is to mitigate concerns and challenges related to wound imaging, ensuring that health care professionals have access to reliable tools that enhance care decisions and ultimately improve patient outcomes. As part of this work, the TWG has prioritized the identification of validated assessment tools to measure PAR or PVR—based on their baseline criteria and/or minimum standards and/or clear evidence of effectiveness—for use in clinical trials that support use of PAR or PVR as a primary endpoint accepted by the FDA. We will explore how precise and standardized wound imaging can enhance the accuracy and reliability of these assessments, thereby contributing significantly to the advancement of wound care and improved patient outcomes. You can actively contribute to this critical effort by visiting https://www.woundcarecc.org/ and becoming a WCCC member. By joining forces with the WCCC TWG, you play a pivotal role in advancing the standards and reliability of wound imaging tools as well as many other projects, ultimately improving the quality of wound care and patient outcomes.

Abbreviations

CDRH, Center for Devices and Radiological Health; CVI, content validity index; FDA, Food and Drug Administration; L, length; PAR, percent area reduction; PUSH, Pressure Ulcer Scale for Healing; PVR, percent volume reduction; SaMD, software-as-a-medical device; TWG, Tools Work Group; W, width; WCCC, Wound Care Collaborative Community.

Introduction

With a multitude of options available, health care professionals often grapple with inconsistent image quality and measurement accuracy. In this article, we discuss the role and importance of PAR and PVR in wound care, highlighting their importance in wound assessments, clinical endpoints, and use for early intervention in wound healing.

The WCCC-TWG Hypothesis

Every day, health care professionals face the challenge of assessing wounds, monitoring their healing progress, and determining the most effective treatment strategies. Thus, the ability to accurately measure wound parameters is paramount. Because wounds are not formed in a rectangular or square fashion, ruler measurements of length and width are typically inaccurate in assessing the wounds’ true dimensions.¹ The ruler method to measure wounds has poor intrarater and interrater reliability, which calls in to question the ability to accurately measure a PAR, time to wound healing, or time to complete wound healing utilizing this antiquated method.² Wound square surface area is measured by length, where L is the length of the long axis and W is the widest width of the wound. Wound volume can be calculated using clinical measurements and the formula for volume of an ellipsoid; the volume is V = 4/3 LWDπ, where L is the length of the long axis, W is the width, and D is the depth. In a study analyzing PVR, wound area and volume reduction were calculated as percentage change from baseline wound size.³ Although using the greatest length by the greatest width improves the reliability, size alone is not the only indicator of wound progression. Wound assessment can be improved by the MEASURE tool: Measure (length, width, depth, and area), Exudate (quality and quantity), Appearance (tissue type), Suffering (pain and level), Undermining, Reevaluate (continue to monitor parameters), and Edge of the wound.⁴ Ideally, the assessment should include the use of these parameters.

An extensive retrospective analysis involving 2768 wounds has shed light on a significant concern with the traditional L × W method for wound area measurement—it tends to yield an overestimation of the wound area, surpassing the actual size by a substantial 44%.⁵ This concern finds reinforcement in several other studies that have also highlighted the propensity of L × W measurements to inaccurately magnify wound dimensions.^5,6 The issue is further exacerbated when dealing with large wounds or those with irregular shapes, where the inaccuracy of this method becomes even more pronounced.⁷ When using a 3D scanner as a control, acetate tracings can improve accuracy in comparison to ruler measurement: 41% difference in measurement versus 75%.⁸ Digital planimetry and computer-assisted techniques provide greater accuracy.⁵

PAR and PVR are known indicators and important clinical endpoints with robust evidence for use in predicting wound healing. In an initial study performed by Sheehan et al, wound area measurements performed in 203 patients over a 12-week prospective randomized trial of patients with diabetic foot ulcers demonstrated a 53% percent or greater change in wound area at 4 weeks correlated with those patients who healed at 12 weeks, whereas less than that percent change in area correlated to those who failed to heal over the 12 weeks. Therefore, the percent change in foot ulcer area after 4 weeks of observation is a robust predictor of healing at 12 weeks.⁹ Similar findings concurred in a cohort study of 704 patients with diabetic wounds.¹⁰ In a recent systematic review of diabetic foot ulcers and venous leg ulcers, 6 studies reported in favor of using PAR while 5 studies demonstrated the lack of having discriminatory ability.¹¹ Some of the challenges faced when analyzing these studies was the risk of bias, heterogeneity of research design, and report of post hoc analysis of patients in randomized trials. A recent study that surveyed 628 interdisciplinary wound experts assessed 28 literature-based wound care endpoints for their relevance and importance to clinical practice, clinical research, and/or if they were patient-centered. Findings included 22 endpoints with CVIs greater than or equal to 0.75, with 15 having CVIs of greater than or equal to 0.85; those 15 were selected for further research as primary endpoints for FDA approval of future wound care interventions.¹² Additional research included a search of 485 references involving over 462 000 participants supporting FDA-required parameters for all 15 of these endpoints.¹³ More than 50 references for PAR alone and hundreds more supported FDA-required parameters qualifying the following outcomes for use in clinical trials supporting interventions for FDA clearance. These parameters include Pain reduction, Physical function and ambulation, Infection reduction, Time to heal, and Percent wound area reduction in 4 to 8 weeks.¹³ Despite these parameters, only time to heal is currently recognized by the FDA as a primary wound outcome in clinical trials.¹³

As part of the research conducted for these 15 primary endpoints, The Opinion Survey from People with Wounds¹⁴ addressed the gap between clinicians’ and patients’ clinical endpoints. Results from 438 patients identified their highest priorities were reduced infection, recurrence, and amputation. The main endpoints in terms of usefulness for measuring clinical trial success were time to heal, wound size, infection, recurrence, and pain.¹⁴ The most valuable quality-of-life outcomes were increased independence, reduced social isolation, and pain.¹⁴ Narrative responses from wound patients emphasized that the most important endpoints are those reflecting pain and the inability to perform activities of daily living.¹⁴

Support for the validity and reliability of monitoring tools to evaluate outcomes has been reported in the literature. The Spinal Cord Injury Pressure Ulcer Monitoring Tool is a validated and reliable tool developed from previously published pressure ulcer healing tools and specific to spinal cord injury.¹⁵ Similar validated monitoring tools such as the Bates-Jensen Wound Assessment Tool and PUSH tool are commonly utilized for pressure injury evaluation. Characteristics of the PUSH tool include the surface area constituting 58% of the total score when the measurements are greater than 24 cm² and the tissue-type score is highest for pressure injuries with slough or eschar. However, the tool omits undermining, tunneling, and depth, which are common clinical findings in pressure injuries.¹⁵ Subsequently, a study using the PUSH tool for measurements in venous leg ulcers has been reported.¹⁶ A prospective, multicenter study validated the use of the PUSH tool in patients with pressure injuries, diabetic ulcers, and/or venous ulcers.¹⁷ However, 3D wound measurements in comparison to other modalities demonstrated increased accuracy. Interrater reliability has been demonstrated with multiple 3D imaging devices.^18,19

One of the key issues facing wound imaging in both clinical practice and in designing clinical wound healing studies is the lack of standardized protocols and guidelines across imaging devices and applications. The US FDA CDRH oversees the safety and regulates the approval of medical devices for marketing. These regulators examine the technical and design applications of the product, considering the safety of the medical device. CDRH is focused on digital medicine developers building SaMD products.²⁰ SaMD provides manufacturers links to techniques, definitions, and sources that are available to help SaMD generate appropriate evidence. Valid clinical association, analytical, and clinical validation are provided by the SaMD manufacturers. It is recommended that manufacturers perform ongoing data analysis and modify software as needed to meet these requirements. SaMD may leverage connectivity between devices and people to continuously monitor the safety, effectiveness, and performance.²⁰ The FDA does not regulate what the product does but what the organization claims the product does. The FDA classifies and regulates medical devices based on risk, whereas class I devices are subject to the lowest level of regulatory controls while class III devices are subject to the highest level of regulation. Class I devices include simple medical supplies and some devices. Class I and some class II devices do not require premarket notification; however, most class II devices require premarket notification, known as 510(k). The 510(k)-clearance process is the path for a new medical device if equivalent to legally marketed devices that predicates it. However, the FDA does allow the manufacturer of a low- to moderate-risk device without a predicate to submit a De Novo request to the FDA to make a risk-based classification of the device into class I or II. Once a De Novo request is granted, this device may then serve as a predicate for 510(k) premarket approval of similar devices in the future.²¹ Subtle differences in terminology used to describe regulatory status have underlying meaning: FDA-approved indicates successful completion of an FDA Premarket Approval process evaluating the safety and efficacy of Class III high-risk products; while FDA-cleared suggests that the device completed a 510(k) pathway for lower-risk products. Drug development tools are recognized separately from medical device development tools.

Additionally, regulation between the European Commission and the FDA may differ. Although they share a similar process for approval, every marketed medical device in the European Union (EU) holds a Conformité Européenne (CE) mark indicating that it conforms to directives set in the EC Medical Device Directives of the EU.²² Similar to SaMD, the National Institute for Health and Care Excellence in England has developed an evidence standards framework for digital health technologies through different evidence tiers the manufacturers provide. Data generated that is accurate, reproducible, and relevant to the range of values expected in the target population undergoes a second-tier review when there is also a commitment to ongoing data collection.²³

In 2016, the FDA and National Institutes of Health created outcome measures. BEST (Biomarkers, EndpointS, and Tools) defines outcomes related to measurable characteristics affected by an individual’s baseline state or/and intervention in a clinical trial.²⁴ The validation of the tool is not based on the item’s usefulness but rather its technical performance. Additionally, the listed biomarkers for diagnostic, monitoring, response, and predictive endpoints are limited. Digital biomarkers could include any of the BEST categories. However, a systematic approach to assessing the quality and usefulness of digital biomarkers is needed.²⁵ Biomarkers are a characteristic measured as an indicator of a normal or pathogenic process or responses to an intervention. An endpoint is an outcome that can be measured objectively. A clinical outcome describes how an individual feels.²⁶ Thus, digital biomarkers may help serve as an endpoint or tool.

Conclusion

As the WCCC TWG strives to address concerns and enhance wound imaging tools, it becomes evident that these tools, when meeting established criteria and undergoing proper evaluation, could be deemed as ‘digital biomarkers.’ These digital biomarkers, with their potential to provide consistent and accurate measurements, hold promise in advancing the field of wound care and improving patient outcomes. By promoting the use of PAR and PVR as primary endpoints accepted by the FDA, the WCCC aims to elevate the standards of wound assessment in clinical trials.

Acknowledgments

Authors: Alisha Oropallo, MD, FSVS, FACS^1,2,3,4; Peggy Dotson, RN, BS^5,6; Tod Brindle, PhD, MSN, RN, ET, CWCN^7,8; Vickie R Driver, DPM, MS^9,10,11; and Lisa Gould, MD, PhD, FACS^8,12

Affiliations: ¹Chair, Tools Work Group, Wound Care Collaborative Community (WCCC); ²Director, Department of Vascular Surgery, Northwell Health; ³Professor, Zucker School of Medicine, Hofstra University/Northwell Health; ⁴Professor, Feinstein Institutes of Medical Research, Northwell Health; ⁵President Healthcare Reimbursement Strategy; ⁶Officer, WCCC; ⁷Global Medical Affairs Director, Ostomy Care, ConvaTec Group; ⁸Co-Chair, Tools Work Group, WCCC; ⁹Chair, WCCC; ¹⁰Professor, Washington State University, School of Medicine; ¹¹Professor, Barry University, affiliate; ¹²Attending Plastic Surgeon, South Shore Health

Disclosure: The authors disclose no financial or other conflicts of interest.

Disclaimer: The opinions and statements expressed herein are specific to the respective author(s) and not necessarily those of Wounds or HMP Global. This article was not subject to the Wounds peer-review process.

How Do I Cite This?

Oropallo A, Dotson P, Brindle T, Driver VR, Gould L. Need for percent area reduction and percent volume reduction measurements in diagnostic wound imaging: a statement from the Wound Care Collaborative Community—part 1. Wounds. 2024;36(2):A3-A6. doi:10.25270/wnds/360224-2

References

1. Ahn C, Salcido RS. Advances in wound photography and assessment methods. Adv Skin Wound Care. 2008;21(2):85-93. doi:10.1097/01.ASW.0000305411.58350.7d

2. Bryant JL, Brooks TL, Schmidt B, Mostow EN. Reliability of wound measuring techniques in an outpatient wound center. Ostomy Wound Manage. 2001;47(4):44-51.

3. Lavery LA, Murdoch DP, Kim PJ, Fontaine JL, Thakral G, Davis KE. Negative pressure wound therapy with low pressure and gauze dressings to treat diabetic foot wounds. J Diabetes Sci Technol. 2014;8(2):346-349. doi:10.1177/1932296813519012

4. Keast DH, Bowering CK, Evans AW, Mackean GL, Burrows C, D’Souza L. MEASURE: a proposed assessment framework for developing best practice recommendations for wound assessment. Wound Repair Regen. 2004;12(3 Suppl):S1-17. doi:10.1111/j.1067-1927.2004.0123S1.x

5. Rogers LC, Bevilacqua NJ, Armstrong DG, Andros G. Digital planimetry results in more accurate wound measurements: a comparison to standard ruler measurements. J Diabetes Sci Technol. 2010;4(4):799-802. doi:10.1177/193229681000400405

6. Schultz G, Mozingo D, Romanelli M, Claxton K. Wound healing and TIME; new concepts and scientific applications. Wound Repair Regen. 2005;13(4 Suppl):S1-11. doi:10.1111/j.1067-1927.2005.1304S1.x

7. DH K. Does wound surface area as measured by length and width reflect true area: analysis of a wound data base. In: Ninth Annual Conference, Canadian Association of Wound Care, Toronto, ON, November 6-9, 2003. Accessed October 1, 2023. https://cir.nii.ac.jp/crid/1573387450199152256

8. Shah A, Wollak C, Shah JB. Wound measurement techniques: comparing the use of ruler method, 2D imaging and 3D scanner. J Am Coll Clin Wound Spec. 2013;5(3):52-57. doi:10.1016/j.jccw.2015.02.001

9. Sheehan P, Jones P, Caselli A, Giurini JM, Veves A. Percent change in wound area of diabetic foot ulcers over a 4-week period is a robust predictor of complete healing in a 12-week prospective trial. Diabetes Care. 2003;26(6):1879-1882. doi:10.2337/diacare.26.6.1879

10. Coerper S, Beckert S, Küper MA, Jekov M, Königsrainer A. Fifty percent area reduction after 4 weeks of treatment is a reliable indicator for healing--analysis of a single-center cohort of 704 diabetic patients. J Diabetes Complications. 2009;23(1):49-53. doi:10.1016/j.jdiacomp.2008.02.001

11. Gwilym BL, Mazumdar E, Naik G, Tolley T, Harding K, Bosanquet DC. Initial reduction in ulcer size as a prognostic indicator for complete wound healing: a systematic review of diabetic foot and venous leg ulcers. Adv Wound Care. 2023;12(6):327-338. doi:10.1089/wound.2021.0203

12. Driver VR, Gould LJ, Dotson P, et al. Identification and content validation of wound therapy clinical endpoints relevant to clinical practice and patient values for FDA approval. Part 1. Survey of the wound care community. Wound Repair Regen. 2017;25(3):454-465. doi:10.1111/wrr.12533

13. Driver VR, Gould LJ, Dotson P, Allen LL, Carter MJ, Bolton LL. Evidence supporting wound care end points relevant to clinical practice and patients’ lives. Part 2. Literature survey. Wound Repair Regen. 2019;27(1):80-89. doi:10.1111/wrr.12676

14. Gould LJ, Liu J, Wan R, Carter MJ, Dotson MP, Driver VR. Evidence supporting wound care end points relevant to clinical practice and patients’ lives. Part 3: the patient survey. Wound Repair Regen. 2021;29(1):60-69. doi:10.1111/wrr.12872

15. Thomason SS, Luther SL, Powell-Cope GM, Harrow JJ, Palacios P. Validity and reliability of a pressure ulcer monitoring tool for persons with spinal cord impairment. J Spinal Cord Med. 2014;37(3):317-327. doi:10.1179/2045772313Y.0000000163

16. Ratliff CR, Rodeheaver GT. Use of the PUSH tool to measure venous ulcer healing. Ostomy Wound Manage. 2005;51(5):58-60, 62-63.

17. Hon J, Lagden K, McLaren AM, et al. A prospective, multicenter study to validate use of the PUSH in patients with diabetic, venous, and pressure ulcers. Ostomy Wound Manage. 2010;56(2):26-36.

18. Anghel EL, Kumar A, Bigham TE, et al. The reliability of a novel mobile 3-dimensional wound measurement device. Wounds. 2016;28(11):379-386.

19. Bills JD, Berriman SJ, Noble DL, Lavery LA, Davis KE. Pilot study to evaluate a novel three-dimensional wound measurement device. Int Wound J. 2016;13(6):1372-1377. doi:10.1111/iwj.12534

20. Software as a Medical Device (SaMD): Key Definitions. International Medical Device Regulators Forum. Published December 18, 2013. Accessed October 1, 2023. https://www.imdrf.org/documents/software-medical-device-samd-key-definitions

21. Allen B. The role of the FDA in ensuring the safety and efficacy of artificial intelligence software and devices. J Am Coll Radiol. 2019;16(2):208-210. doi:10.1016/j.jacr.2018.09.007

22. Van Norman GA. Drugs and devices. JACC Basic Transl Sci. 2016;1(5):399-412. doi:10.1016/j.jacbts.2016.06.003

23. Nwe K, Larsen ME, Nelissen N, Wong DCW. Medical mobile app classification using the national institute for health and care excellence evidence standards framework for digital health technologies: interrater reliability study. J Med Internet Res. 2020;22(6):e17457. doi:10.2196/17457

24. FDA-NIH Biomarker Working Group. BEST (Biomarkers, EndpointS, and Other Tools) Resource. Food and Drug Administration (US); 2016. Accessed October 1, 2023. http://www.ncbi.nlm.nih.gov/books/NBK326791/

25. Coravos A, Khozin S, Mandl KD. Developing and adopting safe and effective digital biomarkers to improve patient outcomes. NPJ Digit Med. 2019;2(1):14. doi:10.1038/s41746-019-0090-4

26. Coravos A, Goldsack JC, Karlin DR, et al. Digital medicine: a primer on measurement. Digit Biomark. 2019;3(2):31-71. doi:10.1159/000500413