Systematic review of effects of current transtibial prosthetic socket designs—Part 2: Quantitative outcomes

Safari, Reza; Meier,

doi:10.1682/jrrd.2014.08.0184

Cited by 30 publications

(34 citation statements)

References 50 publications

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“…For example, footwear may substantially affect regional and overall stiffness and damping of prosthetic feet, in some instances normalizing the mechanical function across designs 35, 37, 39, 70 . Additionally, the choice of suspension system and constituent components 71 will play a role in determining the residuum-prosthesis interface properties and behavior 72, 73 , and this is especially relevant with the advent of bone-anchored prostheses (osseointegration) 74 . Therefore, a first application of the optimization process relates to evidence-based practice.…”

Section: Optimizing Passive Prosthesis Design Through Parametric Smentioning

confidence: 99%

Considering passive mechanical properties and patient user motor performance in lower limb prosthesis design optimization to enhance rehabilitation outcomes

Major

Fey

2017

Physical Therapy Reviews

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Background Selection of prosthesis mechanical characteristics to restore function of persons with lower-limb loss can be framed as an optimization problem to satisfy a given performance objective. However, the choice of a particular objective is critical, and considering only device and generalizable outcomes across users without accounting for inherent motor performance likely restricts a given patient from fully realizing the benefits of a prosthetic intervention. Objectives This review presents methods for optimizing passive below-knee prosthesis designs to maximize rehabilitation outcomes and how considerations on patient motor performance may enhance these outcomes. Major Findings Available literature supports that considering patient-specific variables pertaining to motor performance permits a multidimensional landscape relating device characteristics and user function, which may yield more accurate predictions of rehabilitation outcomes for individual patients. Moreover, the addition of targeted physical therapeutic interventions that encourage user self-organization may further improve these outcomes. We note the potential of existing paradigms to address these additional dimensions, and we encourage investigators to consider the many different performance objectives available for prosthesis optimization. Conclusions By considering user motor performance in combination with prosthesis mechanical characteristics, a staged optimization approach can be formulated which acknowledges that device modifications may only improve outcomes to a certain extent and user self-organization is a critical component to complete rehabilitation. An iterative process that can be integrated within existing rehabilitative practices accounts for changes in patient status through combined targeted prosthetic solutions and physical therapeutic techniques, and embodies the concept of personalized intervention for patients with lower limb-loss.

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Section: Optimizing Passive Prosthesis Design Through Parametric Smentioning

confidence: 99%

Considering passive mechanical properties and patient user motor performance in lower limb prosthesis design optimization to enhance rehabilitation outcomes

Major

Fey

2017

Physical Therapy Reviews

View full text Add to dashboard Cite

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“…To overcome the disadvantages of a PTB prosthesis, a TSB prosthesis has been widely used for the stability of suspension via a silicon liner with a pin-attachment locked-adapter, which can coordinate the precise muscle force-generated as an increase in muscle strength during voluntary thigh muscle contractions. A TSB prosthesis with vacuum-assisted suction sockets may improve gait symmetry, residual limb activity [48]; therefore, we assumed that a TSB prosthesis with good fixation by a socket-silicon linear connecting thigh-stump may improve functional voluntary thigh muscle force/power during knee extension compared with a PTB prosthesis. Consequently, it was seen that proper thigh-stump muscle contraction induced LBF increases through stability with thigh stump exercise.…”

Section: Possible Explanation For the Difference In Exercising Lbf Bymentioning

confidence: 99%

Voluntary Thigh Muscle Strength with Resection Stump-Dependent Blood Flow and Vasodilation in an Amputated Lower Leg with Total Surface Bearing Prosthesis during Dynamic Knee Extensor: A Case Trial

Osada¹,

Ishiyama²,

Ueno³

2019

OJTR

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Background: The magnitude of the hyperemic response due to repeated thigh stump exercise on incremental contraction intensity might be useful information in localized exercise tolerance for devising cardiovascular physical therapy for amputees. The effect of exercise on amputated leg blood flow (LBF) may potentially be altered due to voluntary muscle contractions after loss of the lower leg compared with the healthy leg. Case Presentation: A 57-year-old male patient with Burger disease attempted 3 min unilateral repeat/dynamic knee extensor exercise at a target muscle contraction frequency (1 s thigh muscle contraction and 1 s relaxation, 90 repetitions) with each leg at six different contraction intensities (rubber resistance belt). Simultaneous measurement of blood velocity/flow (Doppler ultrasound) in the femoral artery, blood pressure, leg vascular conductance (LVC), and peak muscle strength (PMS) were performed during the 3 min exercise period. The maximum voluntary contraction by one-legged isometric knee muscle contraction was 14.7 kg in non-AL and 7.9 kg in the AL with prosthesis. The relative PMS was defined as "PMS/maximum voluntary contraction × 100 (%)". Pre-exercise LBF was lower in the AL (200 ± 25 ml/min) than the non-AL (275 ± 74 ml/min). Both the non-AL and AL showed good positive linear relationships between absolute-/relative-PMS and LBF or LVC during 30 s at steady-state before the end of the exercise period. Furthermore, there was also similarity seen in the increase rate in LBF and/or LVC for the incremental relative PMS compared with the absolute PMS. Conclusion: In

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“…Despite the recent research efforts in this field, no fully satisfactory technological solutions exist at present. A comparison between the existing sockets, analyzing their merits and drawbacks, has been made by Safari et al [6], Al-Fakin et al [7] and Chatterjee et al [8] concerning transtibial prostheses.…”

Section: Introductionmentioning

confidence: 99%

Sockets for Limb Prostheses: A Review of Existing Technologies and Open Challenges

Paternò

Ibrahimi

Gruppioni

et al. 2018

IEEE Trans. Biomed. Eng.

187

204

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In the prosthetics field, one of the most important bottlenecks is still the human-machine interface, namely the socket. Indeed, a large number of amputees still rejects prostheses or points out a low satisfaction level, due to a sub-optimal interaction between the socket and the residual limb tissues. The aim of this paper is to describe the main parameters (displacements, stress, volume fluctuations and temperature) affecting the stump-socket interface and reducing the comfort/stability of limb prostheses. In this review, a classification of the different socket types proposed in the literature is reported, together with an analysis of advantages and disadvantages of the different solutions, from multiple viewpoints. The paper then describes the technological solutions available to face an altered distribution of stresses on the residual limb tissues, volume fluctuations affecting the stump overtime and temperature variations affecting the residual tissues within the socket. The open challenges in this research field are highlighted and the possible future routes are discussed, towards the ambitious objective of achieving an advanced socket able to self-adapt in real-time to the complex interplay of factors affecting the stump, during both static and dynamic tasks.

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Systematic review of effects of current transtibial prosthetic socket designs—Part 2: Quantitative outcomes

Cited by 30 publications

References 50 publications

Considering passive mechanical properties and patient user motor performance in lower limb prosthesis design optimization to enhance rehabilitation outcomes

Considering passive mechanical properties and patient user motor performance in lower limb prosthesis design optimization to enhance rehabilitation outcomes

Voluntary Thigh Muscle Strength with Resection Stump-Dependent Blood Flow and Vasodilation in an Amputated Lower Leg with Total Surface Bearing Prosthesis during Dynamic Knee Extensor: A Case Trial

Sockets for Limb Prostheses: A Review of Existing Technologies and Open Challenges

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