Your search keyword '"Crea, Emanuela"' showing total 4 results

1. Reply to the letter from Manferdelli et al.: 'Muscle O 2 diffusion capacity by NIRS: a new approach in the air'.

Author

Pilotto AM, Adami A, Mazzolari R, Brocca L, Crea E, Zuccarelli L, Pellegrino MA, Bottinelli R, Grassi B, Rossiter HB, and Porcelli S

Subjects

Oxygen Consumption physiology, Muscles metabolism

Published

2022

2. Near‐infrared spectroscopy estimation of combined skeletal muscle oxidative capacity and O2 diffusion capacity in humans

Author

Pilotto, Andrea M, Adami, Alessandra, Mazzolari, Raffaele, Brocca, Lorenza, Crea, Emanuela, Zuccarelli, Lucrezia, Pellegrino, Maria A, Bottinelli, Roberto, Grassi, Bruno, Rossiter, Harry B, and Porcelli, Simone

Subjects

Health Sciences, Sports Science and Exercise, Clinical Research, Humans, Muscle, Skeletal, Oxidative Stress, Oxygen, Oxygen Consumption, Spectroscopy, Near-Infrared, biopsy, capillary density, mitochondria, recovery kinetics, skeletal muscle, Biological Sciences, Medical and Health Sciences, Physiology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

The final steps of the O2 cascade during exercise depend on the product of the microvascular-to-intramyocyte PO2${P}_{{{\rm{O}}}_{\rm{2}}}$ difference and muscle O2 diffusing capacity ( DmO2$D{{\rm{m}}}_{{{\rm{O}}}_2}$ ). Non-invasive methods to determine DmO2$D{{\rm{m}}}_{{{\rm{O}}}_2}$ in humans are currently unavailable. Muscle oxygen uptake (m V̇O2${\dot{V}}_{{{\rm{O}}}_{\rm{2}}}$ ) recovery rate constant (k), measured by near-infrared spectroscopy (NIRS) using intermittent arterial occlusions, is associated with muscle oxidative capacity in vivo. We reasoned that k would be limited by DmO2$D{{\rm{m}}}_{{{\rm{O}}}_2}$ when muscle oxygenation is low (kLOW ), and hypothesized that: (i) k in well oxygenated muscle (kHIGH ) is associated with maximal O2 flux in fibre bundles; and (ii) ∆k (kHIGH  - kLOW ) is associated with capillary density (CD). Vastus lateralis k was measured in 12 participants using NIRS after moderate exercise. The timing and duration of arterial occlusions were manipulated to maintain tissue saturation index within a 10% range either below (LOW) or above (HIGH) half-maximal desaturation, assessed during sustained arterial occlusion. Maximal O2 flux in phosphorylating state was 37.7 ± 10.6 pmol s-1  mg-1 (∼5.8 ml min-1  100 g-1 ). CD ranged 348 to 586 mm-2 . kHIGH was greater than kLOW (3.15 ± 0.45 vs. 1.56 ± 0.79 min-1 , P < 0.001). Maximal O2 flux was correlated with kHIGH (r = 0.80, P = 0.002) but not kLOW (r = -0.10, P = 0.755). Δk ranged -0.26 to -2.55 min-1 , and correlated with CD (r = -0.68, P = 0.015). m V̇O2${\dot{V}}_{{{\rm{O}}}_{\rm{2}}}$ k reflects muscle oxidative capacity only in well oxygenated muscle. ∆k, the difference in k between well and poorly oxygenated muscle, was associated with CD, a mediator of DmO2$D{{\rm{m}}}_{{{\rm{O}}}_2}$ . Assessment of muscle k and ∆k using NIRS provides a non-invasive window on muscle oxidative and O2 diffusing capacity. KEY POINTS: We determined post-exercise recovery kinetics of quadriceps muscle oxygen uptake (m V̇O2${\dot{V}}_{{{\rm{O}}}_{\rm{2}}}$ ) measured by near-infrared spectroscopy (NIRS) in humans under conditions of both non-limiting (HIGH) and limiting (LOW) O2 availability, for comparison with biopsy variables. The m V̇O2${\dot{V}}_{{{\rm{O}}}_{\rm{2}}}$ recovery rate constant in HIGH O2 availability was hypothesized to reflect muscle oxidative capacity (kHIGH ) and the difference in k between HIGH and LOW O2 availability (∆k) was hypothesized to reflect muscle O2 diffusing capacity. kHIGH was correlated with phosphorylating oxidative capacity of permeabilized muscle fibre bundles (r = 0.80). ∆k was negatively correlated with capillary density (r = -0.68) of biopsy samples. NIRS provides non-invasive means of assessing both muscle oxidative and oxygen diffusing capacity in vivo.

Published

2022

3. Human skeletal muscle possesses an epigenetic memory of high-intensity interval training.

Author

Pilotto, Andrea M., Turner, Daniel C., Mazzolari, Raffaele, Crea, Emanuela, Brocca, Lorenza, Pellegrino, Maria Antonietta, Miotti, Danilo, Bottinelli, Roberto, Sharples, Adam P., and Porcelli, Simone

Subjects

HIGH-intensity interval training, AEROBIC capacity, VASTUS lateralis, GENE expression profiling, RESISTANCE training, OXYGEN consumption

Abstract

Human skeletal muscle displays an epigenetic memory of resistance exercise induced-hypertrophy. It is unknown, however, whether high-intensity interval training (HIIT) also evokes an epigenetic muscle memory. This study used repeated training intervention interspersed with a detraining period to assess epigenetic memory of HIIT. Twenty healthy subjects (25 ± 5 yr) completed two HIIT interventions (training and retraining) lasting 2 mo, separated by 3 mo of detraining. Measurements at baseline, after training, detraining, and retraining included maximal oxygen consumption (V̇ o 2max). Vastus lateralis biopsies were taken for genome-wide DNA methylation and targeted gene expression analyses. V̇ o 2max improved during training and retraining (P < 0.001) without differences between interventions (P > 0.58). Thousands of differentially methylated positions (DMPs) predominantly demonstrated a hypomethylated state after training, retained even after 3-mo of exercise cessation and into retraining. Five genes, ADAM19, INPP5a, MTHFD1L, CAPN2, and SLC16A3, possessed differentially methylated regions (DMRs) with retained hypomethylated memory profiles and increased gene expression. The retained hypomethylation during detraining was associated with an enhancement in expression of the same genes even after 3 mo of detraining. SLC16A3, INPP5a, and CAPN2 are involved in lactate transport and calcium signaling. Despite similar physiological adaptations between training and retraining, memory profiles were found at epigenetic and gene expression level, characterized by retained hypomethylation and increased gene expression after training into long-term detraining and retraining. These genes were associated with calcium signaling and lactate transport. Although significant memory was not observed in physiological parameters, our novel findings indicate that human skeletal muscle possesses an epigenetic memory of HIIT. NEW & NOTEWORTHY: Cells possess a "memory" such that adaptations can be more quickly regained when a previously encountered challenge is reintroduced. Exercise provides an excellent experimental model to explore the concept of cellular memory to physiologically relevant stressors in humans. This study highlights molecular mechanisms that contribute to muscle memory in response to high-intensity interval training in humans, showing retention of DNA methylation and gene expression profiles from earlier training into detraining and retraining. [ABSTRACT FROM AUTHOR]

Published

2025

4. Near-infrared Spectroscopy Estimation Of Combined Muscle Oxidative Capacity And Oxygen Diffusion Capacity In Humans: 736.

Author

Pilotto, Andrea M., Adami, Alessandra, Mazzolari, Raffaele, Brocca, Lorenza, Crea, Emanuela, Pellegrino, Maria A., Bottinelli, Roberto, Zuccarelli, Lucrezia, Grassi, Bruno, Rossiter, Harry B., and Porcelli, Simone

Subjects

*SKELETAL muscle physiology, *MITOCHONDRIAL physiology, *NEAR infrared spectroscopy, *OXYGEN consumption, *CONFERENCES & conventions

Published

2022