An infrared 3D scanning device as a novel limb volume measurement tool in breast cancer patients.

BACKGROUND: Lymphedema is a common complication of breast cancer treatment that affects one in five breast cancer survivors, yet there is no reliable method to detect lymphedema in the subclinical range. The objective of this study was to determine the feasibility and reliability of using an infrared 3D scanning device (ISD) as a peri-operative limb volume measurement tool. METHODS: Fifteen patients were analyzed based on inclusion criteria. Peri-operative measurements were obtained using tape measure and an ISD. Volumes were calculated using a standard algorithm for tape measure and a custom algorithm for ISD measurements. Linear regression models were used to assess ISD and tape measurement volume and circumference correlation. One-way ANOVA was used to compare change in percent difference at set time points post-operatively (2-3 weeks, 4-6 weeks, and 7-12 weeks) for both ISD and tape measure. t tests for unequal variances with the Bonferroni correction were performed among these groups. RESULTS: There is a positive linear correlation (R2 = 0.8518) between absolute volume measurements by the ISD and tape measure. Analyses over 2-10 weeks post-operatively showed that the ISD was able to detect volume changes in both the unaffected and the affected arm. Furthermore, the affected arm tended to have a greater increase in volume in the majority of patients, indicating these patients could be at risk for lymphedema. CONCLUSIONS: Technology utilizing infrared 3D scanners can reliably measure limb volume pre- and post-treatment similarly to tape measure in a small sample of patients. Further research using 3D scanning technology with a longer follow up is warranted.

Monitoring Leg Lymphedema Over the Course of Therapy Using an Infrared System.

Background: There are many techniques of monitoring leg lymphedema during physical therapy. Taking volumetric measurements with a tape measure is among the most common clinically, and changes in volume are typically used to measure therapy efficacy. This study shows how the Kinect infrared (IR) sensor with custom algorithms can assess leg circumferences and volumes comparable with tape measurements taken by a trained therapist while exploring regional leg changes to determine uniformity of change. Methods and Results: Leg volumes were measured in 38 lymphedema patients using the tape measure circumference method and the Kinect IR system. Changes in circumferences in various leg regions over the course of therapy were analyzed in 23 patients. The leg circumferences (R2 = 0.9522) and volumes ( R2 = 0.9847) strongly correlated between the two methods. The Bland-Altman analysis indicated a circumference percent different bias of 1.6 (6.2%), requiring a minor correction factor between the two methods. Over the course of therapy, patients with a reduction in leg volume, defined as a change >6.5% have greater reduction most distal to the body. Conclusion: The Kinect IR system explored can be used clinically for leg volume measurements to monitor leg lymphedema patients over the course of their therapy. Implementing analysis of regional leg changes can better inform physical therapy to improve efficacy of treatment.

Assessment of Upper Extremity Swelling Among Breast Cancer Survivors with a Commercial Infrared Sensor.

Background: There are various methods of detecting and monitoring arm lymphedema after breast cancer (BC) treatment. Using volumetric measurements is the most common method performed clinically in the United States, and several techniques exist. Recently, the use of infrared cameras has been explored by several groups. This study shows the use of this technology and its ability to assess arm volume measurements comparable to the Perometer while being more inexpensive, having a smaller footprint in clinics, and being easy to use. Methods and Results: Seventy-three BC survivors were scanned with the Perometer and the Kinect IR system, and arm volumes of 146 arms were calculated using their respective algorithms. Good correlation in the arm volume (R-squared = 0.8799) and percent difference (R-squared range 0.6277-0.7098) in the ranges where lymphedema diagnosis is made, and good clinical agreement of lymphedema status based on commonly used thresholds were found between the two modalities. The Cohen's kappa coefficient indicates that based on a 10% arm volume difference, there was a fair agreement (κ = 0.2663), and based on a 200 mL difference, there was a moderate agreement (κ = 0.5475) between the clinical outcomes of these two modalities. The Bland-Altman analysis of volume differences indicated a bias of 6.016 mL; thus, only a minor correction factor is necessary between the two modalities. Conclusion: The Kinect IR system presented can be used clinically for arm volume measurements to detect and monitor patients at risk for or managing lymphedema.

An integrated in vitro imaging platform for characterizing filarial parasite behavior within a multicellular microenvironment.

Lymphatic Filariasis, a Neglected Tropical Disease, is caused by thread-like parasitic worms, including B. malayi, which migrate to the human lymphatic system following transmission. The parasites reside in collecting lymphatic vessels and lymph nodes for years, often resulting in lymphedema, elephantiasis or hydrocele. The mechanisms driving worm migration and retention within the lymphatics are currently unknown. We have developed an integrated in vitro imaging platform capable of quantifying B. malayi migration and behavior in a multicellular microenvironment relevant to the initial site of worm injection by incorporating the worm in a Polydimethylsiloxane (PDMS) microchannel in the presence of human dermal lymphatic endothelial cells (LECs) and human dermal fibroblasts (HDFs). The platform utilizes a motorized controllable microscope with CO2 and temperature regulation to allow for worm tracking experiments with high resolution over large length and time scales. Using post-acquisition algorithms, we quantified four parameters: 1) speed, 2) thrashing intensity, 3) percentage of time spent in a given cell region and 4) persistence ratio. We demonstrated the utility of our system by quantifying these parameters for L3 B. malayi in the presence of LECs and HDFs. Speed and thrashing increased in the presence of both cell types and were altered within minutes upon exposure to the anthelmintic drug, tetramisole. The worms displayed no targeted migration towards either cell type for the time course of this study (3 hours). When cells were not present in the chamber, worm thrashing correlated directly with worm speed. However, this correlation was lost in the presence of cells. The described platform provides the ability to further study B. malayi migration and behavior.