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c438256690c649f3a85e6ad08255c709

MVIC knee extensor torque, Root Mean Square and neuromuscular efficiency of the quadriceps femoris constituents according to hip and knee angles during contraction. (A) MVIC knee extensor torque (N.m) (left y-axis) and different conditions (right x-axis). (B) Root Mean Square of quadriceps femoris (µV) (left y-axis) and different conditions (right x-axis). (C) Neuromuscular efficiency of the quadriceps femoris (%) (left y-axis) and different conditions (right x-axis). Data are presented as geometric means and confidence intervals (CI 95%). Legend: MVIC: Maximal Voluntary Isometric Contraction; RMS: Root Mean Square; QF: Quadriceps femoris; SUP60: supine with 60° of knee flexion; SIT60: seated with 60° of knee flexion; SUP20: supine with 20° of knee flexion; SIT20: seated with 20° of knee flexion. Significant differences: a different from SUP60 at (p ≤ 0.05). b different from SIT60 at (p ≤ 0.05).

PMC10002253

ijerph-20-03947-g004.jpg

2aa39567cf6b40a9b5b0ddde80829de7

The pennation angle and fascicle length of the quadriceps femoris constituents according to hip and knee angles during rest and contraction. Muscle (left y-axis) and different conditions (right x-axis). Rest (closed circle line), main effect (closed triangle line) and during MVIC (closed square line). The first column (pennation angle—θp (°) and second column (fascicle length—Lf (cm)). Data are presented as means and confidence intervals (CI 95%). (A,B) Rectus femoris; (C,D) Vastus lateralis; (E,F) Vastus medialis; (G,H) Vastus intermedius. Legend: SUP60: supine with 60° of knee flexion; SIT60: seated with 60° of knee flexion; SUP20: supine with 20° of knee flexion; SIT20: seated with 20° of knee flexion; θp: pennation angle; Lf: fascicle length. Significant differences: a different from SUP60 at (p ≤ 0.05); b different from SIT60 (p ≤ 0.05); * indicate significant differences in intensity (p ≤ 0.05) between rest and MVIC.

PMC10002253

ijerph-20-03947-g005.jpg

dd098e1e103e44ecbca7ad4215a8193b

The patellar tendon force-elongation (A) and stress-strain (B) relationships according to hip and knee angles during MVIC. SUP60 (closed square blue line); SIT60 (closed square green line); SUP20 (closed circle red line) and SIT20 (closed circle purple line). Data are presented as mean (SD). Legend: SUP60: supine with 60° of knee flexion; SIT60: seated with 60° of knee flexion; SUP20: supine with 20° of knee flexion; SIT20: seated with 20° of knee flexion.

PMC10002253

ijerph-20-03947-g006.jpg

bcc3158670a84a1d996463eacf4ed5df

The illustration of basic applications of innovative IT/ICT technologies, e.g., for the VR NEUROFORMA system, which is used in our laboratory: use in stationary settings such as research/medical centers or hospitals, remotely via mobile devices such as iPhones and tables, or using PCs at home (materials from our lab repository, with permission of the Titanis Ltd., Worcester, UK).

PMC10002333

ijerph-20-04150-g001.jpg

7873e17e28244c94ae8c4653d03fb11d

The view of the menu of the Syllables exercise parameters, regarding the selection of the number of rounds, level of difficulty, and range of movement in the VR NEUROFORMA system, and also the view of its version with the posturography platform and safety barriers (materials from our lab repository, with permission of Titanis Ltd.).

PMC10002333

ijerph-20-04150-g002.jpg

c3c68cd2410e487ea93cbc73332470e7

The presentation of examples of various exercises in the VR NEUROFORMA environment, such as (A) the arithmetic operations executive exercise, (B) the opposing boxing motor exercise, (C) the market products cognitive-motor exercise based on the dual task, (D) mirror paths exercise (materials from our lab repository, with the permission of Titanis Ltd.).

PMC10002333

ijerph-20-04150-g003.jpg

78edb55433684a558b9e20001cdc75ca

Chemical structure of Isocorydine.

PMC10003757

ijms-24-04629-g001.jpg

e588d9e39a884a039c0e9a3126a665cd

Protective effects of isocorydine on LPS-induced acute lung injury in mice. Body weight (A) and food intake (B) were monitored for 21 days in mice intraperitoneally injected with different doses of ICD and DEX (5 mg/kg). LPS-induced acute lung injury mouse model was established. (C) H&E staining of lung tissues. Scale bars, 200 μm. (D) Inflammation score of lungs. (E) Lung wet/dry weight ratios. (F) Statistics of survival time in ICD and control groups after LPS treatment. The mean and SD of at least three independent experiments are shown. * p < 0.05, ** p < 0.01 indicate significant differences between groups as determined by a two-tailed paired Student’s t-test.

PMC10003757

ijms-24-04629-g002.jpg

8ec93ead69f54246bd59a35965e43161

Inhibitory effects of isocorydine on IL-6 mRNA and protein expression in vitro and in vivo. Flow cytometry (A,B) and CCK-8 assay (C) were performed to evaluate BMDMs viability and apoptosis, after treated with different doses of ICD and DEX (5 μM) for 24 h. (D) The Il6 mRNA expression in BMDMs stimulated with LPS (100 ng/mL) for 0 and 6 h. Before stimulation with LPS, BMDMs were pretreated with different doses of ICD (0, 25, 50, 75 μM) and DEX (5 μM) for 1 h. (E,F) The Il6 mRNA expression in lung and spleen tissues of mice with LPS-induced acute lung injury. (G) The protein levels of IL-6 in supernatants of BMDMs stimulated with LPS (100 ng/mL) for 24 h. Before stimulation with LPS, BMDMs were pretreated with ICD (0, 25, 50, 75 μM) and DEX (5 μM) for 1 h. (H) The protein level of IL-6 of blood serum of mice with LPS-induced acute lung injury. In (E,F,H), the dose of LPS was 25 mg/kg, the doses of ICD were 0, 10, 20, 30 mg/kg and the dose of DEX was 5 mg/kg. The mean and SD of at least three independent experiments are shown. * p < 0.05, ** p < 0.01 indicate significant differences between groups, as determined by a two-tailed paired Student’s t-test.

PMC10003757

ijms-24-04629-g003.jpg

3aaf6145fbf2424cb115222b910b5a2b

ICD compromises expression of inflammation pathway-related genes in LPS-activated macrophages. (A) Scatter plot showing gene expression changes in LPS triggered BMDMs pretreated ICD, compared to BMDMs treated with LPS alone. Downregulated genes are indicated in blue, while upregulated genes are indicated in red. (B) Heatmap of differential expressed genes involved in Inflammatory Response. The expression level is shown in the form of Log2(FPKM). (C) GO (Biological Process) analysis of the downregulated genes in ICD pretreated BMDMs. (D) KEGG analysis of the downregulated genes in ICD pretreated BMDMs. (E–G) The mRNA level of Il1a, Ccl2 and Ptgs2 in LPS stimulated macrophages for 6 h, pretreated with ICD or not. (H) KEGG analysis of the upregulated genes in ICD pretreated BMDMs. (I) GO (Biological Process) analysis of the upregulated genes in ICD pretreated BMDMs. The mean and SD of at least three independent experiments are shown. * p < 0.05, ** p < 0.01 indicate significant differences between groups as determined by a two-tailed paired Student’s t-test.

PMC10003757

ijms-24-04629-g004.jpg

837f8e86790549f7add9d9db2fc4f6a4

ICD reduces the activation of LPS-induced inflammation-related signaling pathway in bone marrow-derived macrophages. (A,B) Western blot analysis activation of NF-kB and MAPK signaling pathway in macrophages stimulated with LPS at different time points as indicated, pretreated with ICD or not. The ratios of p-p65/p65 (C) and p-JNK/JNK (D) were quantified with ImageJ software (v1.53). The mean and SD of at least three independent experiments are shown. * p < 0.05, ** p < 0.01 indicate significant differences between groups, as determined by a two-tailed paired Student’s t-test.

PMC10003757

ijms-24-04629-g005.jpg

a0c303c185d84ec69e658696f29dae40

Schematic diagram of ICD effects in macrophages.

PMC10003757

ijms-24-04629-g006.jpg

1d2e401a30b24fdc86d9b28447ae600e

XRD patterns of the nanoparticles (JCPDS standard) calcined at different temperatures (200, 300, and 500 °C) and times (2, 4, and 5 h): (a) GS-NPs profile using aqueous extracts of PDL and (b) CS-NPs profile using NaOH.

PMC10003769

materials-16-01798-g001.jpg

a2de37cedccd47ac852ed4b10c3ee9ea

General FTIR spectra (4000–400 cm−1) of the nanoparticles calcined at different temperatures (200, 300, and 500 °C) and times (2, 4, and 5 h): (a) GS-NPs profile using aqueous extracts of PDL and (b) CS-NPs profile using NaOH.

PMC10003769

materials-16-01798-g002.jpg

579483fb3aae41df984f5028e0bc37b0

Fingerprint region of FTIR spectra in the (900–400 cm−1) of the nanoparticles calcinated at different temperatures (200, 300, and 500 °C) and times (2, 4, and 5 h): (a) GS-NPs profile using aqueous extracts of PDL and (b) CS-NPs profile using NaOH.

PMC10003769

materials-16-01798-g003.jpg

db5b2f6aec554fe3825877ff2b55d21a

Scanning electron microscopy (SEM) of the nanoparticles calcinated at different temperatures (200, 300, and 500 °C) and times (2, 4, and 5 h): (a) GS-NPs profile using aqueous extracts of PDL and (b) CS-NPs profile using NaOH.

PMC10003769

materials-16-01798-g004.jpg

12c0be5ce5de4170bc48791e9dc9a6eb

Transmission electron microscopy (TEM) of selected GS-NPs nanoparticles calcinated at temperatures (200 and 300 °C) and times (2 and 4 h).

PMC10003769

materials-16-01798-g005.jpg

64adffee56654329ab3febacb459f6cd

The inhibition zones (diameters) produced by selected GS-NPs Fe22. GS-NPs calcinated at 200 °C for 2 h, Fe24. GS-NPs calcinated at 200 °C for 4 h, Fe32. GS-NPs calcinated at 300 °C for 2 h and Fe34. GS-NPs calcinated at 300 °C for 4 h against Staphylococcus aureus (S. aureus) and Escherichia coli (E. coli) over 48 h.

PMC10003769

materials-16-01798-g006.jpg

0480267255ee47269a20f6c6eacadde9

The bibliometric analysis of cross-linked polybenzimidazole for high-temperature proton exchange membrane fuel cells.

PMC10003937

materials-16-01932-g001.jpg

55b9467aa2d242cd9b3a221c53c6d83e

Chemical structure of some PBIs.

PMC10003937

materials-16-01932-g002.jpg

ccdcb4d54f2547d8b05411cdd6069225

The effects of cross-linking on the mechanical strength and dimensional stability (taken from Ref. [65]).

PMC10003937

materials-16-01932-g003.jpg

7905ae5b367f4d51aaa1b5582a90a1ec

The cross-linked structure of NbPBI-TSPDO (taken from Ref. [67]).

PMC10003937

materials-16-01932-g004.jpg

00313f693fb24eefab24fbf0378db7ed

The cross-linked structure of CPBIm-X (taken from Ref. [69]).

PMC10003937

materials-16-01932-g005.jpg

8b90c706ec0a4fb68644cead8efdb2de

The voltage of different PBI-based membranes (taken from Ref. [70]).

PMC10003937

materials-16-01932-g006.jpg

c665c99faed545789803e79a5e96b48f

The cross-linked structure of 6FPBI-cPIL (taken from Ref. [71]).

PMC10003937

materials-16-01932-g007.jpg

d62a9dbbc19f433f92ac38438aff1820

The cross-linked structure of 2BIM-2Cl in Ph-PBI (taken from Ref. [65]).

PMC10003937

materials-16-01932-g008.jpg

4e28fd41a8914d1caccb94268e744a10

The voltage of CBOPBI@MOF40% (taken from Ref. [77]).

PMC10003937

materials-16-01932-g009.jpg

591d06a119534d059697c93afa2b823c

The cross-linked structure of cPBI-IL X (taken from Ref. [83]).

PMC10003937

materials-16-01932-g010.jpg

8bbe9beea89449fa8c675c95fbc2153d

The proton conductivity of the SiO2/c-PBI-20 composite membranes (taken from Ref. [85]).

PMC10003937

materials-16-01932-g011.jpg

ad1d5734ace4477eb5ee6384daf2e031

Structures of proteins and compounds. (A) Tetrameric structure of hemoglobin of adult (PDB 1GZX) with two α-chains shown in red, two β-chains shown in blue, and heme shown in green. (B) Molecular structure of resveratrol (RSV), CAS: 501-36-0.

PMC10004267

molecules-28-02050-g001.jpg

5dabbac5a5d44b98b848875f44e8a3fe

Ex vivo data on the interaction of RSV with HbA. (A) SPR assay results for RSV and HbA. The X-axis is time, and the Y-axis is resonance unit (RU). (B) Spectra of HbA with RSV over 4 h of deoxygenation. (C) Potential small-molecule binding pockets of the hemoglobin tetramer. In the protein structure, the hemoglobin α subunit homodimer is shown in red, the hemoglobin β subunit homodimer is shown in blue, and heme is shown in green. Small-molecule binding pockets were indicated by ellipses. (D) Hemoglobin/RSV complex. The tetramer is shown as a red and blue ribbon, and RSV is shown in green. (E) Resveratrol binding area and the contact amino acids (several amino acids are hidden for display convenience). (F) The molecular surface of the interaction region (red is the negatively charged region, blue is the positively charged region, and gray is the hydrophobic region). The amino acid V63 forms a Π-hydrogen bond with RSV. (G) Tm of HbA and HbA with RSV. Note: **, vs. HbA, p < 0.01; ##, vs. HbA: RSV = 1:1, p < 0.01.

PMC10004267

molecules-28-02050-g002a.jpg

c5b122fb62b24884b3363fb6260c08f6

The oxygen supply efficiency of HbA and rat RBCs with RSV ex vivo. Oxygen dissociation curves of (A) HbA and (F) rat RBCs with different concentrations of RSV: P50 values of (B) HbA and (G) rat RBCs with different concentrations of RSV; SI values of (C) HbA and (H) and rat RBCs with different concentrations of RSV; ∆SO2 values after the modification of (D) HbA and (I) rat RBCs with different concentrations of RSV; ∆SO2′ values after the modification of (E) HbA and (J) rat RBCs with different concentrations of RSV. Note: *, vs. control, p < 0.05; **, vs. control, p < 0.01; ##, vs. RSV-low, p < 0.01; @@, vs. RSV-mid, p < 0.01.

PMC10004267

molecules-28-02050-g003.jpg

3ee43d068531496e8b746b16e81c153d

The survival times of mice injected with RSV under acute hypoxic asphyxia: (A) probability of survival in acute hypoxic asphyxia; and (B) changes in survival times of mice injected with different concentrations of RSV under acute hypoxic asphyxia. Note: **, vs. control, p < 0.01; ##, vs. RSV-low, p < 0.01; @@, vs. RSV-mid, p < 0.01.

PMC10004267

molecules-28-02050-g004.jpg

ccb27249200e4f5fa0ab8be2caee86f9

Hypoxic adaption of mice treated with RSV: changes in body weight (A), arterial blood gas analysis results for the partial pressure of oxygen (PO2) (B), arterial oxygen saturation (SO2) results (C), lactate counts (D), blood cell analysis results for counts of red blood cells (RBCs) (E), hemoglobin volume (HGB) values (F), counts of hemoglobin (Hct) (G), oxygen dissociation curves (H), P50 values (I), SI (J), and ∆SO2′ values (K) after 7 days in the control group, normoxia with RSV group, hypoxia group, and hypoxia with RSV group. Note: *, vs. control group, p < 0.05; **, vs. control group, p < 0.01; #, vs. normoxia with RSV group, p < 0.05; ##, vs. normoxia with RSV group, p < 0.01; @, vs. hypoxia group, p < 0.05; @@, vs. hypoxia group, p < 0.01; aa, vs. control-7d group, p < 0.01; bb, vs. normoxia with RSV group, p < 0.01; cc, vs. hypoxia group, p < 0.01.

PMC10004267

molecules-28-02050-g005.jpg

f45baf717a69471b872affeaa30440fa

H&E analysis of liver, brain, and lung tissues of mice in the normal, normal with RSV, hypoxia, and hypoxia with RSV groups.

PMC10004267

molecules-28-02050-g006.jpg

7a7ad124f32b42fcaf6ec3eb796da97e

Normalized UV-Vis absorption spectra of curcumin (1) and its derivatives 2–5, recorded in THF.

PMC10004679

molecules-28-02209-g001.jpg

3b7ecdc586b54c53bad59268a5d9cf25

Photodegradation profile of curcumin 1 (black), curcumin derivative 3 (red) and curcumin derivative 4 (blue) under different light doses (0, 9.4 and 23.5 J/cm2 using a 450 nm Biotable® light source device) using DMSO/H2O as solvent. Three experiments were carried out (n = 3), and the results are shown as means (± SD deviation).

PMC10004679

molecules-28-02209-g002.jpg

30841ae4e43f430488c53189e2fadc35

Examples of prepared films with 15% w/w curcumin derivative loads on PVC: (A) pure PVC, (B) PVC (1)-curc, (C) PVC(4)-etherC10, (D) PVC(3)-esterC10.

PMC10004679

molecules-28-02209-g003.jpg

171dd0e81bf74bf39daffcb391e3d8e3

Normalized solid-state UV-Vis absorption spectra of the PVC–curcumin-based films (0.1% w/w curcumin derivative/PVC).

PMC10004679

molecules-28-02209-g004.jpg

8415dc244c64495fa7a3529a2db5d5fc

TGA curves of PVC and PVC–curcumin-based materials (30% w/w curcumin derivative/PVC); β = 10 °C/min.

PMC10004679

molecules-28-02209-g005.jpg

cd3e63f7111846f6a8a3f0a67e069823

Examples of stress–strain curves for: (a) PVC; (b) PVC(4)-etherC10.

PMC10004679

molecules-28-02209-g006.jpg

29d6d88f8ff943518c2c75f4a29e1d49

(a) Comparative study of different PVC loads with 1 on the photodynamic inactivation of S. aureus planktonic cultures. (b) Comparative study of PVC(1)–(4) (30% w/w curcumin derivative/PVC) on the photodynamic inactivation of S. aureus planktonic cultures. The label *** (p < 0.001) represents statistical difference.

PMC10004679

molecules-28-02209-g007.jpg

b9bda7b1b1a14425a20bf477be362ead

Cytotoxicity of curcumin-based plasticizer 4 against human fibroblast cell line (HDFn). Each condition was carried out at all times and three independent experiments were conducted (n = 3). p < 0.05 was considered to be statistically significant. Ctrl (black bar): control without exposure to formulation; Ctrl 2.5, Ctrl 5 and Ctrl 10 (gray bars): formulation control (2.5 µg/mL, 5 µg/mL and 10 µg/mL); Curcumin derivative 4 (blue bar): incubation with 4 at 2.5 µg/mL, 5 µg/mL and 10 µg/mL.

PMC10004679

molecules-28-02209-g008.jpg

bf5af3e1248149679d04d954e12cd538

(a) Synthesis of curcumin ester and ether derivatives. (b) Synthesis of saturated fatty acids from waste cooking oil.

PMC10004679

molecules-28-02209-sch001.jpg

8aa7d182b1ee43999d81e17dc34d9842

The 25(OH)D serum concentration distribution according to age intervals.

PMC10005256

nutrients-15-01227-g001.jpg

de6f5e08a1cd4fd9800590429387659f

The 25(OH)D serum concentration according to COVID-19 severity and death outcome. The patients who died, with different severity forms, are presented in the grey boxplot. The box shows the median value (horizontal rule), along with the 1st and 3rd quartiles of the observed data (top and bottom of box). Each whisker’s length corresponds to values that are up to 1.5 times the range between the quartiles.

PMC10005256

nutrients-15-01227-g002.jpg

db3d26a4927f46c6b45789a2b46d1cfe

Illustration of in vitro measurement. Two flow phantoms (*) were compared in this study.

PMC10007061

sensors-23-02639-g001.jpg

6783f51d654e4790965e5e1abaee5772

Illustration of the power curve of singular values (a,(b) porcine blood and in vivo jugular vein experiments.

PMC10007061

sensors-23-02639-g002.jpg

27c31c11f8f246c0944c4bfc5658a789

B-mode images in the porcine blood experiment in case of low shear rate. (a) Clutter-less case. (b,c) Clutter-rich cases without and with filters. (1) and (2) PBS and plasma samples.

PMC10007061

sensors-23-02639-g003.jpg

99dd41b25b81438ca15b661a68a22929

B-mode images in the porcine blood experiment in case of high shear rate, as well as Figure 3.

PMC10007061

sensors-23-02639-g004.jpg

5a8f6684fe134029994a7bb685c74972

Frequency dependence of the BSC at selected flow rates. (a,b) PBS and plasma samples in the clutter-less phantom. (c,d) Those in the clutter-rich phantom.

PMC10007061

sensors-23-02639-g005.jpg

a1ff81535004470d9ab8932655a73bf4

Shear rate dependence of the spectral slope (a) and MBF (b).

PMC10007061

sensors-23-02639-g006.jpg

e4417cd3d2fe4686ba655e753dfb265d

In vivo B-mode images in the human jugular vein in subjects #1 (a) to #3 (c) compared between low shear (1) and high shear rates (2) within the intra-subject.

PMC10007061

sensors-23-02639-g007.jpg

b16c4cfd2d3a4023a00c5c9f9ef5d6eb

Temporal variation in the spectral slope (a), MBF (b), shear rate (c), and mean velocity (d) in each subject.

PMC10007061

sensors-23-02639-g008.jpg

9859708200744644b3d7e2bbf582c28c

B-mode image (a) and spatial distribution of the spectral slope (b) and MBF (c) with velocity vector and shear rate in subject #4.

PMC10007061

sensors-23-02639-g009.jpg

47da77141fc8407480502f998339b58a

Mean temporal frequency in each cut-off power of singular value. (a,b) PBS and plasma samples.

PMC10007061

sensors-23-02639-g010.jpg

787ce7d213a64ee5a1b3f828551a55c2

Power spectra in the axial direction. (a,b) PBS and plasma samples in the different low rank singular values at a selected flow rate of 10 mL/min. The spectra were computed in the typical frame at the center of the lumen.

PMC10007061

sensors-23-02639-g011.jpg

1c8817659c04433da9abac6e11642aa3

Typical B-mode images of PBS (a) and plasma (b) samples in the different clutter filter conditions at the flow rate of 10 mL/min.

PMC10007061

sensors-23-02639-g012.jpg

3a5d30f4fa2342e59e82f5f33f813776

The same as in Figure 12, except at the flow rate of 350 mL/min.

PMC10007061

sensors-23-02639-g013.jpg

8da3f4896c6444deb5c099bb35968ccc

Effect of clutter filter conditions for the spectral slope in the porcine blood experiment at the flow rates of 10 mL/min (a) and 350 mL/min (b).

PMC10007061

sensors-23-02639-g014.jpg

9419841aa1d64b1195fb8f67aae3dc0a

Motivations and ecological impacts of STEH: (a) Problems of Battery Replacement. (b) Motivation for STEH.

PMC10007205

sensors-23-02858-g001.jpg

fad1cc2d58594ead8b660ba2b0a9b83c

(a) Vertical Axis Wind Turbine (VAWT). (b) Multiple-blade VAWT [38,40].

PMC10007205

sensors-23-02858-g002.jpg

e68e06951aed451dbd9cf30162da41b0

Home chimney pinwheels (HCP).

PMC10007205

sensors-23-02858-g003.jpg

90265c4c33bf4f0683220aa5e8384282

(a) Aerodynamic lift and drag acting on a blade. (b) Mid-horizontal cross-sectional view of the turbine and wind flow.

PMC10007205

sensors-23-02858-g004.jpg

11dec6db95774cb4ba73449000c81ac5

Block Diagram of energy harvesting mechanism and remote monitoring of Wind STEH.

PMC10007205

sensors-23-02858-g005.jpg

018ef6e0f6554b02bcec48b6847caa06

STEH fabrication from Home Chimney Pinwheels (HCP): (a) Physical outlook, (b) the magnetic cap of the converter, (c) the harness showing the converter winding coils with the magnetic cap uncovered.

PMC10007205

sensors-23-02858-g006.jpg

257cb2be99da41e0ab1b5379f510d375

STEH-HCP Top-view rotation.

PMC10007205

sensors-23-02858-g007.jpg

6636b253003044f49f75aa2c5cd5ab96

PMU Circuit diagram.

PMC10007205

sensors-23-02858-g008.jpg

d2280f9fb0804bcbbf2d7ebe4f219eba

STEH Smart Sensing and Communication Process: (a) Sensing and communication (b) Flowchart.

PMC10007205

sensors-23-02858-g009.jpg

5ce1c344933e42ea985362c6fe50da0b

The ESP32 LoRa 1-CH Gateway Receiving Module (a) with a duck antenna, (b) mounted within a building.

PMC10007205

sensors-23-02858-g010.jpg

e0ffa5e7656e47fc82d240c568f246ed

Laboratory Set-Up for the HCP Smart Turbine Energy Harvester. (a) Experimental set-up, (b) Set-up for wind measurement with output voltage.

PMC10007205

sensors-23-02858-g011.jpg

2268235ebae64b8989ca4437664d5ecc

STEH Rooftop Set-up: (a) HCP-STEH on flat rooftop (b) output reading.

PMC10007205

sensors-23-02858-g012.jpg

92a67b5b2fb94fe08d315d37fcb73e89

Output voltage waveforms for different wind speeds.

PMC10007205

sensors-23-02858-g013.jpg

1a79e712d93943d5a5b75dfdbbb3bd01

No-load peak output voltage with wind speeds.

PMC10007205

sensors-23-02858-g014.jpg

2b417918948b4724a381024dbd0ced9a

Fitted output voltage curve with wind speed.

PMC10007205

sensors-23-02858-g015.jpg

007196c271cc4745b6427e59f662e09d

Recorded output data for Day 1.

PMC10007205

sensors-23-02858-g016.jpg

89c33af8cee24bc0baccb1e4bea2d993

Recorded output data for Day 2.

PMC10007205

sensors-23-02858-g017.jpg

bcd7bc285cb4467b98eeadee060b055b

Recorded output data for Day 3.

PMC10007205

sensors-23-02858-g018.jpg

39261a4a995d4ea09ce6b47b595c8575

Recorded output data for Day 4.

PMC10007205

sensors-23-02858-g019.jpg

b9df10ca32df4b80805f6f862bd1737c

Recorded output data for Day 5.

PMC10007205

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b1aec08f67144863b96e77d1a92eee74

Measured output voltage of the harvester for the five days with an 8-point moving average trend line.

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Wind speed in Aveiro for the month of September 2022. [Source: www.meteoblue.com, accessed on 12 December 2022]. The five days of monitoring of the harvester is indicated by the red rectangle.

PMC10007205

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A snapshot of the HCP-STEH Cloud-based output data for Day 3 on the “ThingSpeak” Cloud platform.

PMC10007205

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A snapshot of the HCP-STEH Cloud-based output data for Day 4 on the “ThingSpeak” Cloud platform.

PMC10007205

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(a) Scheme of the reactor setup for glycerol phosphorylation. (b) Oven-cured phosphate-containing polyester.

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(a) Hot pressing of particleboard. (b) Pressed board still in the iron mold.

PMC10007242

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ATR-FTIR spectra of phosphorylated glycerol products PG1 and PG2 and pure glycerol as reference.

PMC10007242

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ATR-FTIR spectra of phosphate-containing bio-based polyesters PE1 and PE2 and polyester without phosphate as reference PE0.

PMC10007242

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1H-NMR spectra of phosphorylated glycerol products PG1, PG2 and pure glycerol as reference.

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(a) SEM analysis and (b) EDX analysis of sample PE0.

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(a) SEM analysis and (b) EDX analysis of sample PE1.

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(a) SEM analysis and (b) EDX analysis of sample PE2.

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(a) TGA and (b) DTG data for the different monomers and polymers in nitrogen.

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(a) TGA and (b) DTG data for the different monomers and polymers in air.

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(a) Gram–Schmidt over time and temperature and (b) FTIR spectra recorded at different intervals for PE0 sample.

PMC10007242

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(a) Gram–Schmidt over time and temperature and (b) FTIR spectra recorded at different intervals for PE1 sample.

PMC10007242

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(a) Gram–Schmidt over time and temperature and (b) FTIR spectra recorded at different intervals for PE2 sample.

PMC10007242

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(a) Middle and (b) far ATR-FTIR spectra of the TGA-FTIR residues.

PMC10007242

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Percentages of thickness swelling (blue) and water absorption (white) of particleboard samples with and without additives.

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Heat Release Rate (HRR) versus time curves for all the samples.

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