ABSTRACT
OBJECTIVE: To determine the effects if cycling and rowing on serum prostate-specific antigen (PSA) levels. METHODS: Male volunteers (n = 101), aged 20-80 (mean, 49.9) years were randomized to exercise at the first or second study visit. They performed 1 h of either cycling or rowing on a stationary machine. To determine exercise-induced effects on the PSA level, serum total PSA (tPSA) and free PSA (fPSA) concentrations were evaluated before and after exercise and another sampling was performed at the second study visit. Pre-exercise and postexercise tPSA and fPSA concentrations were compared using the Wilcoxon matched-pairs test. The results were analyzed using the Mann-Whitney U-test. RESULTS: A significant (p < 0.001) average increase in tPSA after exercise (1.14 ± 1.11 ng/ml to 1.24 ± 1.26 ng/ml [mean, +8.8%]) was observed after both cycling and rowing, without significant differences between the sports (p = 0.54). The exercise-induced increase in PSA concentration affected participants aged ≥50 years (difference, 0.16 ± 0.37; p < 0.001), but not those aged <50 years (difference, 0.01 ± 0.06; p = 0.23). The effect size was clinically irrelevant in all except two outliers, in whom a distinct increase of PSA level by averages of 1.80 ng/ml (+55%) for tPSA and 1.25 ng/ml (+227%) for fPSA following cycling was observed. CONCLUSION: Rowing and cycling generally do not have a clinically relevant effect on PSA levels. However, outliers exist. Our findings do not support abstaining from exercise during the days approaching PSA sampling.
Subject(s)
Prostatic Neoplasms , Water Sports , Exercise , Humans , Male , Prostate-Specific AntigenABSTRACT
Purpose: To prospectively evaluate the safety and efficacy of the TIGRIS Vascular Stent in the superficial femoral artery (SFA) and proximal popliteal artery within a treatment algorithm that reserved stent usage for more challenging patients. Materials and Methods: This prospective, single-center study enrolled 97 patients (mean age 68.7 years; 66 men) who were treated for 100 de novo or nonstented restenotic femoropopliteal lesions (≥70% stenosis) and had recoil or dissection after plain balloon predilation. The average lesion length was 5.6±2.3 cm (maximum 8 cm per protocol). The composite primary efficacy outcome was 12-month primary patency, defined as a peak systolic velocity ratio ≤2.5 at the stented target lesion on duplex ultrasound, and no clinically-driven reintervention within the stented segment. The primary safety outcome was freedom from device- and procedure-related target vessel revascularization, target limb major amputation (above the metatarsals), or death through 30 days. Secondary outcomes included secondary patency, clinically-driven target lesion revascularization (TLR), Rutherford category change relative to baseline, and binary restenosis of the target lesion. Results: All devices were successfully implanted with no device-related complications at the time of implant or within the 30-day postimplant window. The average stented length was 7.0±2.5 cm; no stent elongation was observed during deployment. One patient was lost to follow-up before 12 months and another died of an unrelated cause, leaving 95 patients (98 lesions) available for 12-month follow-up and 77 patients/lesions for the 24-month preliminary analysis. The binary primary and secondary patency rates at 12 months were 92.9% and 100%. The binary freedom from TLR was 94.9%. At 24 months, the Kaplan-Meier estimate of primary patency was 90.0%. Conclusion: This prospective study demonstrated that the TIGRIS Vascular Stent is a safe and effective device in a modern treatment algorithm that reserved bare stent use for postangioplasty dissection or recoil in distal femoropopliteal arteries.
