Your search keyword '"Ramondou P"' showing total 6 results

1. Kneeling-induced calf ischemia: a pilot study in apparently healthy European young subjects.

Author

Ramondou P, Hersant J, Bernardeau E, Moumneh T, Feuilloy M, Henni S, and Abraham P

Subjects

Adult, Female, France, Healthy Volunteers, Humans, Male, Pilot Projects, Prospective Studies, Ischemia physiopathology, Leg blood supply, Posture physiology

Abstract

Purpose: Many tasks, sports or leisure activities require maximal knee flexion. We hypothesized that this position could result in reduced calf perfusion, in young European subjects., Methods: We quantified calf ischemia resulting from the knee flexion with transcutaneous oxygen pressure (TcpO2) sensors by assessing the decrease from rest of TcpO2 (DROP) defined as limb changes minus chest changes. A minimal DROP (DROPm) <-15 mmHg defines the presence of ischemia. From the crawling position, participants kneeled for 3 min while bending as in prostration/prayer position (P). Thirty-five participants repeated this maneuver a second time, while 7 participants were also required to sit on their heels with the torso in the vertical position to attain knee flexion without significant groin flexion (S)., Result: In 41 healthy young volunteers (30 males), 25 [20-31] years old, 37 patients showed a DROPm < -15 mmHg from "R" to "P" in one (n = 4) or both (n = 33) calves (90.2%; 95% CI 76.9-97.3). After backward regression of the DROPm, there was no significant association with side, body weight of systolic blood pressure. However, age was strongly associated with DROPm (OR 5.34 [2.45-8.69]) so that DROPm was significantly higher in older, with a correlation ρ = 0.31 (p = 0.003)., Conclusion: Kneeling dramatically reduces calf perfusion, likely through popliteal artery kinking, possibly through muscle crushing. Eastern lifestyle includes routine flexed position since childhood. Whether or not such a chronic training reduces the risk of kneeling-induced ischemia in adults is unknown to date., (© 2021. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2021

2. Calf and non-calf hemodynamic recovery in patients with arterial claudication: Implication for exercise training.

Author

Hersant J, Ramondou P, Picquet J, Feuilloy M, Abraham P, and Henni S

Subjects

Aged, Exercise Test, Exercise Tolerance, Female, Humans, Intermittent Claudication diagnosis, Intermittent Claudication therapy, Ischemia diagnosis, Ischemia therapy, Male, Middle Aged, Peripheral Arterial Disease diagnosis, Peripheral Arterial Disease therapy, Recovery of Function, Regional Blood Flow, Severity of Illness Index, Time Factors, Hemodynamics, Intermittent Claudication physiopathology, Ischemia physiopathology, Leg blood supply, Peripheral Arterial Disease physiopathology

Abstract

Background: Previous studies in patients with arterial claudication have focused on calf hemodynamic recovery. We hypothesized that the duration of hemodynamic recovery with TcpO2 at calf and non-calf levels would be shorter than 10 min. We analyzed the factors that influence the recovery time., Methods: We monitored limb changes minus chest changes from rest (DROP) of transcutaneous oximetry on buttocks, thighs and calves, during and following a treadmill test (3.2 km/h; 10% grade). We calculated the time required to reach 50% (50%RT) and 10% (90%RT) of minimal DROP value (DROPm) from walking cessation. Regression analyses were used to determine the factors associated to 50%RT and 90%RT., Results: Of the 132 patients studied, 18.2% reported isolated non-calf pain by history. Of the 792 recovery time values, only 3 (0.4%) and 23 (2.9%) were in excess of 10 min for 50%RT and for 90%RT, respectively. A weak correlation was found between each of the 792 DROPm and 50%RT (r = -0.270, p < 0.001) as well as for 90%RT (r = -0.311 p < 0.001). Lowest DROPm and BMI (but not age, sex, the use of beta-blockers, the duration of the walking period) were associated to both 50%RT and 90%RT., Conclusion: Although recovery duration correlates significantly with the severity of ischemia of the same location, a wide discrepancy exists and the longest recovery time does not always correlate to the localization of the most severe ischemia. Non-calf ischemia should be measured when one aims at objectifying the biological effects of exercise or the effects of treatments on recovery from exercise., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

3. A pilot study of forearm microvascular impairment and pain while using a telephone.

Author

Hersant J, Ramondou P, Guilleron C, Picquet J, Henni S, and Abraham P

Subjects

Adolescent, Adult, Female, Humans, Ischemia diagnosis, Ischemia physiopathology, Male, Middle Aged, Musculoskeletal Pain diagnosis, Musculoskeletal Pain physiopathology, Pilot Projects, Prospective Studies, Risk Factors, Thoracic Outlet Syndrome diagnosis, Thoracic Outlet Syndrome physiopathology, Time Factors, Young Adult, Cell Phone, Forearm blood supply, Forearm innervation, Ischemia etiology, Musculoskeletal Pain etiology, Posture, Thoracic Outlet Syndrome complications

Abstract

Objective: To determine if using a telephone can induce forearm pain and ischemia., Design: Prospective case-control trial., Setting: Vascular laboratory in the university hospital in Angers between September 2018 and March 2019., Participants: Fifteen apparently healthy subjects (controls) and 32 patients with suspected thoracic outlet syndrome (TOS) of vascular or non-vascular origin., Intervention: Hand-holding a cellular phone to answer a call from investigators., Main Outcome Measures: Presence of forearm fatigue or pain (primary outcome), ability to hold the phone with each hand for 1 min (secondary outcome 1) and decrease in forearm transcutaneous oxygen pressure DROP index indicating forearm ischemia (secondary outcome 2). A DROP < -15 mm Hg defined ischemia., Results: Answering a phone call resulted in 25(78%) patients with forearm fatigue or pain and in 18 (56%) cases in the inability to hold the phone for 1 min, on one or both arms in patients with suspected TOS, but never occurred in healthy volunteers (p < .05 and p < .001). The presence of ischemia was observed in one or both arms in 10 (31%) patients with proved TOS and was always associated to phone-induced pain. Three (20%) of the controls had phone-induced ischemia. All had asymptomatic TOS and remained asymptomatic during the phone test (p = .42 from suspected-TOS patients)., Conclusion: The phone conversation resulted in pain in many patients with suspected TOS. Transcutaneous oximetry can document the underlying ischemia. Forearm phone-call-induced pain may be indicative of TOS provided that no earplug or headset is used. Trial registrationClinicalTrials.govNCT03355274., Competing Interests: Declaration of competing interest No support from any organization for the submitted work; no financial relationships with any organizations that might have an interest in the submitted work in the previous three years; no other relationships or activities that could appear to have influenced the submitted work. Specifically authors have no interest or investments in companies selling earplugs, headsets or greeting postcards., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2020

4. Upper arm versus forearm transcutaneous oximetry during upper limb abduction in patients with suspected thoracic outlet syndrome

Author

Jeanne Hersant, Simon Lecoq, Pierre Ramondou, Mathieu Feuilloy, Pierre Abraham, and Samir Henni

Subjects

thoracic outlet syndrome, transcutaneous oximetry, pathophysiology, artery, ischemia, upper limb, Physiology, QP1-981

Abstract

Context: Thoracic outlet syndrome (TOS) is common among athletes and should be considered as being of arterial origin only if patients have “clinical symptoms due to documented symptomatic ischemia.” We previously reported that upper limb ischemia can be documented with DROPm (minimal value of limb changes minus chest changes) from transcutaneous oximetry (TcpO2) in TOS.Purpose: We aimed to test the hypothesised that forearm (F-) DROPm would better detect symptoms associated with arterial compression during abduction than upper arm (U-) DROPm, and that the thresholds would differ.Methods: We studied 175 patients (retrospective analysis of a cross-sectional acquired database) with simultaneous F-TcpO2 and U-TcpO2 recordings on both upper limbs, and considered tests to be positive (CS+) when upper limb symptoms were associated with ipsilateral arterial compression on either ultrasound or angiography. We determined the threshold and diagnostic performance with a receiver operating characteristic (ROC) curve analysis and calculation of the area under the ROC curve (AUROC) for absolute resting TcpO2 and DROPm values to detect CS+. For all tests, a two-tailed p < 0.05 was considered indicative of statistical significance.Results: In the 350 upper-limbs, while resting U-TcpO2 and resting F-TcpO2 were not predictive of CS + results, the AUROCs were 0.68 ± 0.03 vs. 0.69 ± 0.03 (both p < 0.01), with the thresholds being −7.5 vs. −14.5 mmHg for the detection of CS + results for U-DROPm vs. F-DROPm respectively.Conclusion: In patients with suspected TOS, TcpO2 can be used for detecting upper limb arterial compression and/or symptoms during arm abduction, provided that different thresholds are used for U-DROPm and F-DROPm.Clinical Trial Registration:ClinicalTrials.gov, identifier NCT04376177.

Published

2022

5. Relationship Between Inflow Impairment and Skin Oxygen Availability to the Upper Limb During Standardized Arm Abduction in Patients With Suspected Thoracic Outlet Syndrome

Author

Jeanne Hersant, Simon Lecoq, Pierre Ramondou, Xavier Papon, Mathieu Feuilloy, Pierre Abraham, and Samir Henni

Subjects

finger pulse plethysmography, transcutaneous oxygen measurement, thoracic oulet syndrome, thoracic outlet compression, ischemia, pathophysiology, Physiology, QP1-981

Abstract

ObjectiveThoracic outlet syndrome (TOS) should be considered of arterial origin only if patients have clinical symptoms that are the result of documented symptomatic ischemia. Simultaneous recording of inflow impairment and forearm ischemia in patients with suspected TOS has never been reported to date. We hypothesized that ischemia would occur in cases of severely impaired inflow, resulting in a non-linear relationship between changes in pulse amplitude (PA) and the estimation of ischemia during provocative attitudinal upper limb positioning.DesignProspective single center interventional study.MaterialFifty-five patients with suspected thoracic outlet syndrome.MethodsWe measured the minimal decrease from rest of transcutaneous oximetry pressure (DROPm) as an estimation of oxygen deficit and arterial pulse photo-plethysmography to measure pulse amplitude changes from rest (PA-change) on both arms during the candlestick phase of a “Ca + Pra” maneuver. “Ca + Pra” is a modified Roos test allowing the estimation of maximal PA-change during the “Pra” phase. We compared the DROPm values between deciles of PA-changes with ANOVA. We then analyzed the relationship between mean PA-change and mean DROPm of each decile with linear and second-degree polynomial (non-linear) models. Results are reported as median [25/75 centiles]. Statistical significance was p

Published

2022

6. Arterial Digital Pulse Photoplethysmography in Patients with Suspected Thoracic Outlet Syndrome: A Study of the 'Ca+Pra' Maneuver

Author

Jeanne Hersant, Pierre Ramondou, Francine Thouveny, Mickael Daligault, Mathieu Feuilloy, Patrick Saulnier, Pierre Abraham, and Samir Henni

Subjects

thoracic outlet syndrome, transcutaneous oximetry, photoplethysmography, pathophysiology, ischemia, arterial inflow, Medicine (General), R5-920

Abstract

The level of pulse amplitude (PA) change in arterial digital pulse plethysmography (A-PPG) that should be used to diagnose thoracic outlet syndrome (TOS) is debated. We hypothesized that a modification of the Roos test (by moving the arms forward, mimicking a prayer position (“Pra”)) releasing an eventual compression that occurs in the surrender/candlestick position (“Ca”) would facilitate interpretation of A-PPG results. In 52 subjects, we determined the optimal PA change from rest to predict compression at imaging (ultrasonography +/− angiography) with receiver operating characteristics (ROC). “Pra”-PA was set as 100%, and PA was expressed in normalized amplitude (NA) units. Imaging found arterial compression in 23 upper limbs. The area under ROC was 0.765 ± 0.065 (p < 0.0001), resulting in a 91.4% sensitivity and a 60.9% specificity for an increase of fewer than 3 NA from rest during “Ca”, while results were 17.4% and 98.8%, respectively, for the 75% PA decrease previously proposed in the literature. A-PPG during a “Ca+Pra” test provides demonstrable proof of inflow impairment and increases the sensitivity of A-PPG for the detection of arterial compression as determined by imaging. The absence of an increase in PA during the “Ca” phase of the “Ca+Pra” maneuver should be considered indicative of arterial inflow impairment.

Published

2021