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344 results on '"Alterovitz, Ron"'

1. Safe Start Regions for Medical Steerable Needle Automation

Author

Hoelscher, Janine, Fried, Inbar, Tsalikis, Spiros, Akulian, Jason, Webster III, Robert J., and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

Steerable needles are minimally invasive devices that enable novel medical procedures by following curved paths to avoid critical anatomical obstacles. Planning algorithms can be used to find a steerable needle motion plan to a target. Deployment typically consists of a physician manually inserting the steerable needle into tissue at the motion plan's start pose and handing off control to a robot, which then autonomously steers it to the target along the plan. The handoff between human and robot is critical for procedure success, as even small deviations from the start pose change the steerable needle's workspace and there is no guarantee that the target will still be reachable. We introduce a metric that evaluates the robustness to such start pose deviations. When measuring this robustness to deviations, we consider the tradeoff between being robust to changes in position versus changes in orientation. We evaluate our metric through simulation in an abstract, a liver, and a lung planning scenario. Our evaluation shows that our metric can be combined with different motion planners and that it efficiently determines large, safe start regions., Comment: 16 pages, 10 figures

Published
2024

2. A Dataset of Anatomical Environments for Medical Robots: Modeling Respiratory Deformation

Author

Fried, Inbar, Hoelscher, Janine, Akulian, Jason A., and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

Anatomical models of a medical robot's environment can significantly help guide design and development of a new robotic system. These models can be used for benchmarking motion planning algorithms, evaluating controllers, optimizing mechanical design choices, simulating procedures, and even as resources for data generation. Currently, the time-consuming task of generating these environments is repeatedly performed by individual research groups and rarely shared broadly. This not only leads to redundant efforts, but also makes it challenging to compare systems and algorithms accurately. In this work, we present a collection of clinically-relevant anatomical environments for medical robots operating in the lungs. Since anatomical deformation is a fundamental challenge for medical robots operating in the lungs, we describe a way to model respiratory deformation in these environments using patient-derived data. We share the environments and deformation data publicly by adding them to the Medical Robotics Anatomical Dataset (Med-RAD), our public dataset of anatomical environments for medical robots.

Published
2023

3. Autonomous Medical Needle Steering In Vivo

Author

Kuntz, Alan, Emerson, Maxwell, Ertop, Tayfun Efe, Fried, Inbar, Fu, Mengyu, Hoelscher, Janine, Rox, Margaret, Akulian, Jason, Gillaspie, Erin A., Lee, Yueh Z., Maldonado, Fabien, Webster III, Robert J., and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

The use of needles to access sites within organs is fundamental to many interventional medical procedures both for diagnosis and treatment. Safe and accurate navigation of a needle through living tissue to an intra-tissue target is currently often challenging or infeasible due to the presence of anatomical obstacles in the tissue, high levels of uncertainty, and natural tissue motion (e.g., due to breathing). Medical robots capable of automating needle-based procedures in vivo have the potential to overcome these challenges and enable an enhanced level of patient care and safety. In this paper, we show the first medical robot that autonomously navigates a needle inside living tissue around anatomical obstacles to an intra-tissue target. Our system leverages an aiming device and a laser-patterned highly flexible steerable needle, a type of needle capable of maneuvering along curvilinear trajectories to avoid obstacles. The autonomous robot accounts for anatomical obstacles and uncertainty in living tissue/needle interaction with replanning and control and accounts for respiratory motion by defining safe insertion time windows during the breathing cycle. We apply the system to lung biopsy, which is critical in the diagnosis of lung cancer, the leading cause of cancer-related death in the United States. We demonstrate successful performance of our system in multiple in vivo porcine studies and also demonstrate that our approach leveraging autonomous needle steering outperforms a standard manual clinical technique for lung nodule access., Comment: 22 pages, 6 figures

Published
2022

4. A Clinical Dataset for the Evaluation of Motion Planners in Medical Applications

Author

Fried, Inbar, Akulian, Jason A., and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

The prospect of using autonomous robots to enhance the capabilities of physicians and enable novel procedures has led to considerable efforts in developing medical robots and incorporating autonomous capabilities. Motion planning is a core component for any such system working in an environment that demands near perfect levels of safety, reliability, and precision. Despite the extensive and promising work that has gone into developing motion planners for medical robots, a standardized and clinically-meaningful way to compare existing algorithms and evaluate novel planners and robots is not well established. We present the Medical Motion Planning Dataset (Med-MPD), a publicly-available dataset of real clinical scenarios in various organs for the purpose of evaluating motion planners for minimally-invasive medical robots. Our goal is that this dataset serve as a first step towards creating a larger robust medical motion planning benchmark framework, advance research into medical motion planners, and lift some of the burden of generating medical evaluation data., Comment: 4 pages, 3 figures, to appear at the workshop "Evaluating Motion Planning Performance: Metrics, Tools, Datasets, and Experimental Design" at IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Japan, October 23 - October 27, 2022

Published
2022

5. Resolution-Optimal Motion Planning for Steerable Needles

Author

Fu, Mengyu, Solovey, Kiril, Salzman, Oren, and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

Medical steerable needles can follow 3D curvilinear trajectories inside body tissue, enabling them to move around critical anatomical structures and precisely reach clinically significant targets in a minimally invasive way. Automating needle steering, with motion planning as a key component, has the potential to maximize the accuracy, precision, speed, and safety of steerable needle procedures. In this paper, we introduce the first resolution-optimal motion planner for steerable needles that offers excellent practical performance in terms of runtime while simultaneously providing strong theoretical guarantees on completeness and the global optimality of the motion plan in finite time. Compared to state-of-the-art steerable needle motion planners, simulation experiments on realistic scenarios of lung biopsy demonstrate that our proposed planner is faster in generating higher-quality plans while incorporating clinically relevant cost functions. This indicates that the theoretical guarantees of the proposed planner have a practical impact on the motion plan quality, which is valuable for computing motion plans that minimize patient trauma., Comment: arXiv admin note: text overlap with arXiv:2107.04939; to be published in ICRA 2022

Published
2021

6. Toward Certifiable Motion Planning for Medical Steerable Needles

Author

Fu, Mengyu, Salzman, Oren, and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

Medical steerable needles can move along 3D curvilinear trajectories to avoid anatomical obstacles and reach clinically significant targets inside the human body. Automating steerable needle procedures can enable physicians and patients to harness the full potential of steerable needles by maximally leveraging their steerability to safely and accurately reach targets for medical procedures such as biopsies and localized therapy delivery for cancer. For the automation of medical procedures to be clinically accepted, it is critical from a patient care, safety, and regulatory perspective to certify the correctness and effectiveness of the motion planning algorithms involved in procedure automation. In this paper, we take an important step toward creating a certifiable motion planner for steerable needles. We introduce the first motion planner for steerable needles that offers a guarantee, under clinically appropriate assumptions, that it will, in finite time, compute an exact, obstacle-avoiding motion plan to a specified target, or notify the user that no such plan exists. We present an efficient, resolution-complete motion planner for steerable needles based on a novel adaptation of multi-resolution planning. Compared to state-of-the-art steerable needle motion planners (none of which provide any completeness guarantees), we demonstrate that our new resolution-complete motion planner computes plans faster and with a higher success rate., Comment: To be published in Robotics: Science and Systems (RSS) 2021

Published
2021
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7. Computationally-Efficient Roadmap-based Inspection Planning via Incremental Lazy Search

Author

Fu, Mengyu, Salzman, Oren, and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

The inspection-planning problem calls for computing motions for a robot that allow it to inspect a set of points of interest (POIs) while considering plan quality (e.g., plan length). This problem has applications across many domains where robots can help with inspection, including infrastructure maintenance, construction, and surgery. Incremental Random Inspection-roadmap Search (IRIS) is an asymptotically-optimal inspection planner that was shown to compute higher-quality inspection plans orders of magnitudes faster than the prior state-of-the-art method. In this paper, we significantly accelerate the performance of IRIS to broaden its applicability to more challenging real-world applications. A key computational challenge that IRIS faces is effectively searching roadmaps for inspection plans -- a procedure that dominates its running time. In this work, we show how to incorporate lazy edge-evaluation techniques into \iris's search algorithm and how to reuse search efforts when a roadmap undergoes local changes. These enhancements, which do not compromise IRIS's asymptotic optimality, enable us to compute inspection plans much faster than the original IRIS. We apply IRIS with the enhancements to simulated bridge inspection and surgical inspection tasks and show that our new algorithm for some scenarios can compute similar-quality inspection plans 570x faster than prior work., Comment: to be published in ICRA 2021

Published
2021

8. A Recurrent Neural Network Approach to Roll Estimation for Needle Steering

Author

Emerson, Maxwell, Ferguson, James M., Ertop, Tayfun Efe, Rox, Margaret, Granna, Josephine, Lester, Michael, Maldonado, Fabien, Gillaspie, Erin A., Alterovitz, Ron, III., Robert J. Webster, and Kuntz, Alan

Subjects
Computer Science - Robotics, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing, Electrical Engineering and Systems Science - Systems and Control
Abstract

Steerable needles are a promising technology for delivering targeted therapies in the body in a minimally-invasive fashion, as they can curve around anatomical obstacles and hone in on anatomical targets. In order to accurately steer them, controllers must have full knowledge of the needle tip's orientation. However, current sensors either do not provide full orientation information or interfere with the needle's ability to deliver therapy. Further, torsional dynamics can vary and depend on many parameters making steerable needles difficult to accurately model, limiting the effectiveness of traditional observer methods. To overcome these limitations, we propose a model-free, learned-method that leverages LSTM neural networks to estimate the needle tip's orientation online. We validate our method by integrating it into a sliding-mode controller and steering the needle to targets in gelatin and ex vivo ovine brain tissue. We compare our method's performance against an Extended Kalman Filter, a model-based observer, achieving significantly lower targeting errors.

Published
2021

9. Robust Navigation of a Soft Growing Robot by Exploiting Contact with the Environment

Author

Greer, Joseph D., Blumenschein, Laura H., Alterovitz, Ron, Hawkes, Elliot W., and Okamura, Allison M.

Subjects
Computer Science - Robotics
Abstract

Navigation and motion control of a robot to a destination are tasks that have historically been performed with the assumption that contact with the environment is harmful. This makes sense for rigid-bodied robots where obstacle collisions are fundamentally dangerous. However, because many soft robots have bodies that are low-inertia and compliant, obstacle contact is inherently safe. As a result, constraining paths of the robot to not interact with the environment is not necessary and may be limiting. In this paper, we mathematically formalize interactions of a soft growing robot with a planar environment in an empirical kinematic model. Using this interaction model, we develop a method to plan paths for the robot to a destination. Rather than avoiding contact with the environment, the planner exploits obstacle contact when beneficial for navigation. We find that a planner that takes into account and capitalizes on environmental contact produces paths that are more robust to uncertainty than a planner that avoids all obstacle contact., Comment: 15 pages, 18 figures, supplementary video included and higher resolution available at https://youtu.be/XdTdFLz2TWU

Published
2019
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10. Toward Asymptotically-Optimal Inspection Planning via Efficient Near-Optimal Graph Search

Author

Fu, Mengyu, Kuntz, Alan, Salzman, Oren, and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

Inspection planning, the task of planning motions that allow a robot to inspect a set of points of interest, has applications in domains such as industrial, field, and medical robotics. Inspection planning can be computationally challenging, as the search space over motion plans that inspect the points of interest grows exponentially with the number of inspected points. We propose a novel method, Incremental Random Inspection-roadmap Search (IRIS), that computes inspection plans whose length and set of inspected points asymptotically converge to those of an optimal inspection plan. IRIS incrementally densifies a motion planning roadmap using sampling-based algorithms, and performs efficient near-optimal graph search over the resulting roadmap as it is generated. We demonstrate IRIS's efficacy on a simulated planar 5DOF manipulator inspection task and on a medical endoscopic inspection task for a continuum parallel surgical robot in anatomy segmented from patient CT data. We show that IRIS computes higher-quality inspection paths orders of magnitudes faster than a prior state-of-the-art method., Comment: RSS 2019

Published
2019
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11. Enabling Robots to Understand Incomplete Natural Language Instructions Using Commonsense Reasoning

Author

Chen, Haonan, Tan, Hao, Kuntz, Alan, Bansal, Mohit, and Alterovitz, Ron

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Computation and Language
Abstract

Enabling robots to understand instructions provided via spoken natural language would facilitate interaction between robots and people in a variety of settings in homes and workplaces. However, natural language instructions are often missing information that would be obvious to a human based on environmental context and common sense, and hence does not need to be explicitly stated. In this paper, we introduce Language-Model-based Commonsense Reasoning (LMCR), a new method which enables a robot to listen to a natural language instruction from a human, observe the environment around it, and automatically fill in information missing from the instruction using environmental context and a new commonsense reasoning approach. Our approach first converts an instruction provided as unconstrained natural language into a form that a robot can understand by parsing it into verb frames. Our approach then fills in missing information in the instruction by observing objects in its vicinity and leveraging commonsense reasoning. To learn commonsense reasoning automatically, our approach distills knowledge from large unstructured textual corpora by training a language model. Our results show the feasibility of a robot learning commonsense knowledge automatically from web-based textual corpora, and the power of learned commonsense reasoning models in enabling a robot to autonomously perform tasks based on incomplete natural language instructions., Comment: 7 pages, 4 figures, ICRA 2020

Published
2019

12. Probability-Weighted Temporal Registration for Improving Robot Motion Planning and Control Learned from Demonstrations

Author

Bowen, Chris, Alterovitz, Ron, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Morales, Marco, editor, Tapia, Lydia, editor, Sánchez-Ante, Gildardo, editor, and Hutchinson, Seth, editor

Published
2020
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13. Concurrent Nearest-Neighbor Searching for Parallel Sampling-Based Motion Planning in SO(3), SE(3), and Euclidean Spaces

Author

Ichnowski, Jeffrey, Alterovitz, Ron, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Morales, Marco, editor, Tapia, Lydia, editor, Sánchez-Ante, Gildardo, editor, and Hutchinson, Seth, editor

Published
2020
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14. Cloud-based Motion Plan Computation for Power-Constrained Robots

Author

Ichnowski, Jeffrey, Prins, Jan, Alterovitz, Ron, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Goldberg, Ken, editor, Abbeel, Pieter, editor, Bekris, Kostas, editor, and Miller, Lauren, editor

Published
2020
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15. Following Surgical Trajectories with Concentric Tube Robots via Nearest-Neighbor Graphs

Author

Niyaz, Sherdil, Kuntz, Alan, Salzman, Oren, Alterovitz, Ron, Srinivasa, Siddhartha, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, and Xiao, Jing, editor

Published
2020
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16. Fast Anytime Motion Planning in Point Clouds by Interleaving Sampling and Interior Point Optimization

Author

Kuntz, Alan, Bowen, Chris, Alterovitz, Ron, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Amato, Nancy M., editor, Hager, Greg, editor, Thomas, Shawna, editor, and Torres-Torriti, Miguel, editor

Published
2020
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17. Accelerating Motion Planning for Learned Mobile Manipulation Tasks Using Task-Guided Gibbs Sampling

Author

Bowen, Chris, Alterovitz, Ron, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Amato, Nancy M., editor, Hager, Greg, editor, Thomas, Shawna, editor, and Torres-Torriti, Miguel, editor

Published
2020
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18. The Economic Case for Cloud-Based Computation for Robot Motion Planning

Author

Ichnowski, Jeffrey, Prins, Jan, Alterovitz, Ron, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, Amato, Nancy M., editor, Hager, Greg, editor, Thomas, Shawna, editor, and Torres-Torriti, Miguel, editor

Published
2020
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19. Interleaving Optimization with Sampling-Based Motion Planning (IOS-MP): Combining Local Optimization with Global Exploration

Author

Kuntz, Alan, Bowen, Chris, and Alterovitz, Ron

Subjects
Computer Science - Robotics
Abstract

Computing globally optimal motion plans for a robot is challenging in part because it requires analyzing a robot's configuration space simultaneously from both a macroscopic viewpoint (i.e., considering paths in multiple homotopic classes) and a microscopic viewpoint (i.e., locally optimizing path quality). We introduce Interleaved Optimization with Sampling-based Motion Planning (IOS-MP), a new method that effectively combines global exploration and local optimization to quickly compute high quality motion plans. Our approach combines two paradigms: (1) asymptotically-optimal sampling-based motion planning, which is effective at global exploration but relatively slow at locally refining paths, and (2) optimization-based motion planning, which locally optimizes paths quickly but lacks a global view of the configuration space. IOS-MP iteratively alternates between global exploration and local optimization, sharing information between the two, to improve motion planning efficiency. We evaluate IOS-MP as it scales with respect to dimensionality and complexity, as well as demonstrate its effectiveness on a 7-DOF manipulator for tasks specified using goal configurations and workspace goal regions., Comment: 8 pages, 4 figures

Published
2016

21. Two Large Open-Access Datasets for Fitts Law of Human Motion and a Succinct Derivation of the Square-Root Variant

Author

Goldberg, Ken, Faridani, Siamak, and Alterovitz, Ron

Subjects
Fitts' law, human-computer interfaces, human movement time, time and motion studies, Information and Computing Sciences, Engineering, Psychology and Cognitive Sciences, Artificial Intelligence & Image Processing
Abstract

© 2014 IEEE. Fitts' law specifies a logarithmic relationship between motion duration and the ratio of target distance over target size. This paper introduces two large open-access datasets from experimental user studies: first a controlled (in-lab) study with 46 participants, and second an uncontrolled online study using a Java applet. We present a succinct derivation of the square-root variant of Fitts' law using optimal control theory and compare three models that relate motion duration to the ratio of target distance over target size: LOG (Fitts' original logarithmic function), SQR (square-root), and LOG' (McKenzie's logarithmic plus 1.0). We find that: 1) the data from the controlled and uncontrolled studies are consistent; 2) for homogeneous targets (with fixed size and distance), the SQR model yields a significantly better fit than LOG or LOG', except with the most difficult targets (where the ratio of target distance over target size is large) where the models are not significantly different; and 3) for heterogeneous targets (with varying size and distance), SQR yields a significantly better fit than LOG for easy targets and LOG yields a significantly better fit for targets of medium difficulty, while the LOG' model yields a significantly better fit than both LOG and SQR on very difficult targets. The anonymized datasets including 94 580 human reaching motion timing measurements are, to our knowledge, the largest collected to date.

Published
2015

23. A Recurrent Neural Network Approach to Roll Estimation for Needle Steering

Author

Emerson, Maxwell, primary, Ferguson, James M., additional, Ertop, Tayfun Efe, additional, Rox, Margaret, additional, Granna, Josephine, additional, Lester, Michael, additional, Maldonado, Fabien, additional, Gillaspie, Erin A., additional, Alterovitz, Ron, additional, Webster, Robert J., additional, and Kuntz, Alan, additional

Published
2021
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30. Orthotropic Thin Shell Elasticity Estimation for Surface Registration

Author

Zhao, Qingyu, Pizer, Stephen, Alterovitz, Ron, Niethammer, Marc, Rosenman, Julian, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Niethammer, Marc, editor, Styner, Martin, editor, Aylward, Stephen, editor, Zhu, Hongtu, editor, Oguz, Ipek, editor, Yap, Pew-Thian, editor, and Shen, Dinggang, editor

Published
2017
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33. ResBoost: characterizing and predicting catalytic residues in enzymes

Author

Alterovitz, Ron, Arvey, Aaron, Sankararaman, Sriram, Dallett, Carolina, Freund, Yoav, and Sjölander, Kimmen

Subjects
Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Biotechnology, Bioengineering, Binding Sites, Catalysis, Computational Biology, Databases, Protein, Enzymes, Software, Mathematical Sciences, Information and Computing Sciences, Bioinformatics, Biological sciences, Information and computing sciences, Mathematical sciences
Abstract

BackgroundIdentifying the catalytic residues in enzymes can aid in understanding the molecular basis of an enzyme's function and has significant implications for designing new drugs, identifying genetic disorders, and engineering proteins with novel functions. Since experimentally determining catalytic sites is expensive, better computational methods for identifying catalytic residues are needed.ResultsWe propose ResBoost, a new computational method to learn characteristics of catalytic residues. The method effectively selects and combines rules of thumb into a simple, easily interpretable logical expression that can be used for prediction. We formally define the rules of thumb that are often used to narrow the list of candidate residues, including residue evolutionary conservation, 3D clustering, solvent accessibility, and hydrophilicity. ResBoost builds on two methods from machine learning, the AdaBoost algorithm and Alternating Decision Trees, and provides precise control over the inherent trade-off between sensitivity and specificity. We evaluated ResBoost using cross-validation on a dataset of 100 enzymes from the hand-curated Catalytic Site Atlas (CSA).ConclusionResBoost achieved 85% sensitivity for a 9.8% false positive rate and 73% sensitivity for a 5.7% false positive rate. ResBoost reduces the number of false positives by up to 56% compared to the use of evolutionary conservation scoring alone. We also illustrate the ability of ResBoost to identify recently validated catalytic residues not listed in the CSA.

Published
2009

34. Autonomous medical needle steering in vivo

Author

Kuntz, Alan, primary, Emerson, Maxwell, additional, Ertop, Tayfun Efe, additional, Fried, Inbar, additional, Fu, Mengyu, additional, Hoelscher, Janine, additional, Rox, Margaret, additional, Akulian, Jason, additional, Gillaspie, Erin A., additional, Lee, Yueh Z., additional, Maldonado, Fabien, additional, Webster, Robert J., additional, and Alterovitz, Ron, additional

Published
2023
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35. Interactive simulation of surgical needle insertion and steering

Author

Chentanez, Nuttapong, Alterovitz, Ron, Ritchie, Daniel, Cho, Lita, Hauser, Kris K, Goldberg, Ken, Shewchuk, Jonathan R, and O'Brien, James F

Subjects
Information and Computing Sciences, Graphics, Augmented Reality and Games, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Prostate Cancer, Urologic Diseases, Bioengineering, Cancer
Published
2009

37. The Endoscopogram: A 3D Model Reconstructed from Endoscopic Video Frames

Author

Zhao, Qingyu, Price, True, Pizer, Stephen, Niethammer, Marc, Alterovitz, Ron, Rosenman, Julian, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Ourselin, Sebastien, editor, Joskowicz, Leo, editor, Sabuncu, Mert R., editor, Unal, Gozde, editor, and Wells, William, editor

Published
2016
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41. Optimization of HDR brachytherapy dose distributions using linear programming with penalty costs

Author

Alterovitz, Ron, Lessard, Etienne, Pouliot, Jean, Hsu, I‐Chow Joe, O'Brien, James F, and Goldberg, Ken

Subjects
Medical and Biological Physics, Physical Sciences, Prostate Cancer, Urologic Diseases, Cancer, Algorithms, Body Burden, Brachytherapy, Computer Simulation, Humans, Male, Models, Biological, Organ Specificity, Programming, Linear, Prostatic Neoplasms, Quality Assurance, Health Care, Quality Control, Radiometry, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Relative Biological Effectiveness, HDR, optimization, conformal radiotherapy, prostate therapy, IPSA, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging, Biomedical engineering, Medical and biological physics
Abstract

Prostate cancer is increasingly treated with high-dose-rate (HDR) brachytherapy, a type of radiotherapy in which a radioactive source is guided through catheters temporarily implanted in the prostate. Clinicians must set dwell times for the source inside the catheters so the resulting dose distribution minimizes deviation from dose prescriptions that conform to patient-specific anatomy. The primary contribution of this paper is to take the well-established dwell times optimization problem defined by Inverse Planning by Simulated Annealing (IPSA) developed at UCSF and exactly formulate it as a linear programming (LP) problem. Because LP problems can be solved exactly and deterministically, this formulation provides strong performance guarantees: one can rapidly find the dwell times solution that globally minimizes IPSA's objective function for any patient case and clinical criteria parameters. For a sample of 20 prostates with volume ranging from 23 to 103 cc, the new LP method optimized dwell times in less than 15 s per case on a standard PC. The dwell times solutions currently being obtained clinically using simulated annealing (SA), a probabilistic method, were quantitatively compared to the mathematically optimal solutions obtained using the LP method. The LP method resulted in significantly improved objective function values compared to SA (P = 1.54 x 10(-7)), but none of the dosimetric indices indicated a statistically significant difference (P < 0.01). The results indicate that solutions generated by the current version of IPSA are clinically equivalent to the mathematically optimal solutions.

Published
2006

42. Registration of MR prostate images with biomechanical modeling and nonlinear parameter estimation

Author

Alterovitz, Ron, Goldberg, Ken, Pouliot, Jean, Hsu, I-Chow Joe, Kim, Yongbok, Noworolski, Susan Moyher, and Kurhanewicz, John

Subjects
deformable image registration, prostate finite element model, registration, nonlinear image warping, prostate therapy
Abstract

Magnetic resonance imaging (MRI) and magnetic resonance spectroscopic imaging (MRSI) have been shown to be very useful for identifying prostate cancers. For high sensitivity, the MRI/MRSI examination is often acquired with an endorectal probe that may cause a substantial deformation of the prostate and surrounding soft tissues. Such a probe is removed prior to radiation therapy treatment. To register diagnostic probe-in magnetic resonance (MR) images to therapeutic probe-out MR images for treatment planning, a new deformable image registration method is developed based on biomechanical modeling of soft tissues and estimation of uncertain tissue parameters using nonlinear optimization. Given two-dimensional (2-D) segmented probe-in and probe-out images, a finite element method (FEM) is used to estimate the deformation of the prostate and surrounding tissues due to displacements and forces resulting from the endorectal probe. Since FEM requires tissue stiffness properties and external force values as input, the method estimates uncertain parameters using nonlinear local optimization. The registration method is evaluated using images from five balloon and five rigid endorectal probe patient cases. It requires on average 37 s of computation time on a 1.6 GHz Pentium-M PC. Comparing the prostate outline in deformed probe-out images to corresponding probe-in images, the method obtains a mean Dice Similarity Coefficient (DSC) of 97.5% for the balloon probe cases and 98.1% for the rigid probe cases. The method improves significantly over previous methods (P < 0.05) with greater improvement for balloon probe cases with larger tissue deformations.

Published
2006

50. Conclusion

Author

Alterovitz, Ron, Goldberg, Ken, Siciliano, Bruno, editor, Khatib, Oussama, editor, Groen, Frans, editor, Alterovitz, Ron, and Goldberg, Ken

Published
2008
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