Automatic extraction of upper-limb kinematic activity using deep learning-based markerless tracking during deep brain stimulation implantation for Parkinson’s disease: A proof of concept study

Baker, Sunderland; Tekriwal, Anand; Felsen, Gidon; Christensen, Elijah; Hirt, Lisa; Ojemann, Steven G.; Kramer, Daniel R.; Kern, Drew S.; Thompson, John A.

doi:10.1371/journal.pone.0275490

Cited by 7 publications

(4 citation statements)

References 62 publications

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“…With the introduction of DeepLabCut (DLC) [23] (and comparable tools, see [24] for a review), which is a highly accessible supervised deep learning framework extensively validated across several species [25], markerless pose tracking has now become the state-of-the-art in experimental neurosciences. In recent years, CV techniques have increasingly permeated into the realms of clinical and especially motor neuroscience [26][27][28][29][30][31][32][33]. At the core of these supervised DL frameworks commonly lie convolutional neural networks (CNNs) pretrained on several thousands to a million naturalistic images [34], which are fine-tuned by the user for specific use cases.…”

Section: Introductionmentioning

confidence: 99%

Smartphone video nystagmography using convolutional neural networks: ConVNG

et al. 2022

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Background Eye movement abnormalities are commonplace in neurological disorders. However, unaided eye movement assessments lack granularity. Although videooculography (VOG) improves diagnostic accuracy, resource intensiveness precludes its broad use. To bridge this care gap, we here validate a framework for smartphone video-based nystagmography capitalizing on recent computer vision advances. Methods A convolutional neural network was fine-tuned for pupil tracking using > 550 annotated frames: ConVNG. In a cross-sectional approach, slow-phase velocity of optokinetic nystagmus was calculated in 10 subjects using ConVNG and VOG. Equivalence of accuracy and precision was assessed using the “two one-sample t-test” (TOST) and Bayesian interval-null approaches. ConVNG was systematically compared to OpenFace and MediaPipe as computer vision (CV) benchmarks for gaze estimation. Results ConVNG tracking accuracy reached 9–15% of an average pupil diameter. In a fully independent clinical video dataset, ConVNG robustly detected pupil keypoints (median prediction confidence 0.85). SPV measurement accuracy was equivalent to VOG (TOST p < 0.017; Bayes factors (BF) > 24). ConVNG, but not MediaPipe, achieved equivalence to VOG in all SPV calculations. Median precision was 0.30°/s for ConVNG, 0.7°/s for MediaPipe and 0.12°/s for VOG. ConVNG precision was significantly higher than MediaPipe in vertical planes, but both algorithms’ precision was inferior to VOG. Conclusions ConVNG enables offline smartphone video nystagmography with an accuracy comparable to VOG and significantly higher precision than MediaPipe, a benchmark computer vision application for gaze estimation. This serves as a blueprint for highly accessible tools with potential to accelerate progress toward precise and personalized Medicine.

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Section: Introductionmentioning

confidence: 99%

Smartphone video nystagmography using convolutional neural networks: ConVNG

et al. 2022

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“…The second strategy is signal processing filters such as median filter and low pass filter Stenum et al (2021 ); Pereira et al (2019 ); Luxem et al (2022 ); Weinreb et al (2023 ); Han et al (2023a ); Li and Lee (2021 ). They can efficiently remove most of the drifted points without human intervention, but they will also remove the subtle behaviors with high-frequency features such as self-grooming in autism mouse models Huang et al (2021 ) or tremor in animal models of Parkinson’s disease Baker et al (2022 ). The third strategy is fitting the drifted frames using linear dynamic models such as Keypoint-Moseq Weinreb et al (2023 ) and adaptive Kalman filter Huang et al (2022 ).…”

Section: Introductionmentioning

confidence: 99%

Anti-drift pose tracker (ADPT): A transformer-based network for robust animal pose estimation cross-species

Tang,

Han,

Liu

et al. 2024

Preprint

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Deep learning-based methods for animal pose estimation have recently made substantial progress in improving the accuracy and efficiency of quantitative descriptions of animal behavior. However, these methods commonly suffer from tracking drifts, i.e., sudden jumps in the estimated position of a body point due to noise, thus reducing the reliability of behavioral study results. Here, we present a transformer-based animal pose estimation tool, called Anti-Drift Pose Tracker (ADPT), for eliminating tracking drifts in behavior analysis. To verify the anti-drift performance of ADPT, we conduct extensive experiments in multiple cross-species datasets, including long-term recorded mouse and monkey behavioral datasets collected by ourselves, as well as two public Drosophilas and macaques datasets. Our results show that ADPT greatly reduces the rate of tracking drifts, and significantly outperforms the existing deep-learning methods, such as DeepLabCut, SLEAP, and DeepPoseKit. Moreover, ADPT is compatible with multi-animal pose estimation, enabling animal identity recognition and social behavioral study. Specifically, ADPT provided an identification accuracy of 93.16% for 10 unmarked mice, and of 90.36% for free-social unmarked mice which can be further refined to 99.72%. Compared to other multi-stage network-based tools like multi-animal DeepLabCut, SIPEC and Social Behavior Atlas, the end-to-end structure of ADPT supports its lower computational costs and meets the needs of real-time analysis. Together, ADPT is a versatile anti-drift animal behavior analysis tool, which can greatly promote the accuracy, robustness, and reproducibility of animal behavioral studies. The code of ADPT is available at https://github.com/tangguoling/ADPT.

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“…like ataxia in mice and men [12][13][14][15] . For example, a recent study applied DLC to identify tremors and abnormal ataxic behaviors in an ataxic and tremor rodent model called the shaker and a mouse model for Spinocerebellar ataxia type 3 (SCA3) 12 .…”

mentioning

confidence: 99%

“…Additionally, another group used the machine learning-based system JAABA (Janelia Atomatic Animal Behavior Annotator) to characterize the ataxic phenotype in a Purkinje cell-specific knockout of calcium/calmodulin-activated protein-phosphatase-2B (PP2B) mouse model for ataxia 16 . A more recent study in Parkinson's patients utilized DLC and algorithms to objectively correlate neural signals with movement to ideally place deep brain stimulation electrodes 13 .…”

mentioning

confidence: 99%

Phenotypic analysis of ataxia in spinocerebellar ataxia type 6 mice using DeepLabCut

Piotrowski,

Clemensson,

Nguyen

et al. 2024

Sci Rep

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This study emphasizes the benefits of open-source software such as DeepLabCut (DLC) and R to automate, customize and enhance data analysis of motor behavior. We recorded 2 different spinocerebellar ataxia type 6 mouse models while performing the classic beamwalk test, tracked multiple body parts using the markerless pose-estimation software DLC and analyzed the tracked data using self-written scripts in the programming language R. The beamwalk analysis script (BAS) counts and classifies minor and major hindpaw slips with an 83% accuracy compared to manual scoring. Nose, belly and tail positions relative to the beam, as well as the angle at the tail base relative to the nose and tail tip were determined to characterize motor deficits in greater detail. Our results found distinct ataxic abnormalities such as an increase in major left hindpaw slips and a lower belly and tail position in both SCA6 ataxic mouse models compared to control mice at 18 months of age. Furthermore, a more detailed analysis of various body parts relative to the beam revealed an overall lower body position in the SCA684Q compared to the CT-longQ27PC mouse line at 18 months of age, indicating a more severe ataxic deficit in the SCA684Q group.

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Automatic extraction of upper-limb kinematic activity using deep learning-based markerless tracking during deep brain stimulation implantation for Parkinson’s disease: A proof of concept study

Cited by 7 publications

References 62 publications

Smartphone video nystagmography using convolutional neural networks: ConVNG

Smartphone video nystagmography using convolutional neural networks: ConVNG

Anti-drift pose tracker (ADPT): A transformer-based network for robust animal pose estimation cross-species

Phenotypic analysis of ataxia in spinocerebellar ataxia type 6 mice using DeepLabCut

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