Data_Sheet_1_Higher ultra processed foods intake is associated with low muscle mass in young to middle-aged adults: a cross-sectional NHANES study.docx

DesignUltra-processed foods (UPFs) have become a pressing global health concern, prompting investigations into their potential association with low muscle mass in adults.MethodsThis cross-sectional study analyzed data from 10,255 adults aged 20−59 years who participated in the National Health and Nutritional Examination Survey (NHANES) during cycles spanning from 2011 to 2018. The primary outcome, low muscle mass, was assessed using the Foundation for the National Institutes of Health (FNIH) definition, employing restricted cubic splines and weighted multivariate regression for analysis. Sensitivity analysis incorporated three other prevalent definitions to explore optimal cut points for muscle quality in the context of sarcopenia.ResultsThe weighted prevalence of low muscle mass was 7.65%. Comparing the percentage of UPFs calories intake between individuals with normal and low muscle mass, the values were found to be similar (55.70 vs. 54.62%). Significantly linear associations were observed between UPFs consumption and low muscle mass (P for non-linear = 0.7915, P for total = 0.0117). Upon full adjustment for potential confounding factors, participants with the highest UPFs intake exhibited a 60% increased risk of low muscle mass (OR = 1.60, 95% CI: 1.13 to 2.26, P for trend = 0.003) and a decrease in ALM/BMI (β = −0.0176, 95% CI: −0.0274 to −0.0077, P for trend = 0.003). Sensitivity analysis confirmed the consistency of these associations, except for the International Working Group on Sarcopenia (IWGS) definition, where the observed association between the highest quartiles of UPFs (%Kcal) and low muscle mass did not attain statistical significance (OR = 1.35, 95% CI: 0.97 to 1.87, P for trend = 0.082).ConclusionOur study underscores a significant linear association between higher UPFs consumption and an elevated risk of low muscle mass in adults. These findings emphasize the potential adverse impact of UPFs on muscle health and emphasize the need to address UPFs consumption as a modifiable risk factor in the context of sarcopenia.</p

Cell blebs and cytoskeleton under different DMSO concentrations.

<p><b>(A)</b> The bleb and cytoskeleton were observed by an inverted fluorescence microscope (membrane: red; cytoskeleton: green). <b>(B)</b> The bleb and cytoskeleton were observed by a confocal microscope (cytoskeleton: green; nucleus: blue). <b>(C)</b> The fluid flows in the formation of blebs under a hypoosmotic condition (0.1×PBS) and a hyperosmotic condition (25% DMSO in PBS). The experiments were repeated 3 times.</p

Cell blebs induced by the addition of CPAs.

<p>Various concentrations of <b>(A)</b> DMSO and <b>(B)</b> glycerol were applied to HeLa cells for 30 minutes. The development of cell blebs during the first 3 minutes was observed as the initial state and after 30 minutes as the stable state. Initiate: 3 minutes, and Stabilized: 30 minutes. The experiments were repeated 3 times.</p

Life cycle of a dynamic bleb.

<p><b>(A)</b> the inflation and retraction of one bleb (black arrows); <b>(B)</b> the actin microfilament reorganization during the bleb inflation and retraction; <b>(C)</b> the comparison of the inflation and retraction time between DMSO and glycerol. For <b>(A)</b> and <b>(B)</b>, the experiments were repeated 3 times. For <b>(C)</b>, the number of cells used was approximately 20.</p

Stepwise addition of DMSO.

<p><b>(A)</b> Comparison of the mortality rate of cells between stepwise and single-step addition. <b>(B)</b> Bleb index in the stepwise addition method. HeLa cells were treated with 20% DMSO for 30 minutes, and the solution was removed quickly and changed to 40% DMSO for 30 minutes. It was then changed to 60% DMSO for 30 minutes and, finally, to 80% DMSO. The inverted fluorescence microscope was used to observe dead cells labeled by PI and Hoechst. For <b>(A)</b>, the number of cells used was approximately 500 and the experiment was repeated 5 times. For <b>(B)</b>, the number of cells used was approximately 40. **p<0.01 was considered statistically significant.</p

The autophagy induced by the addition of CPAs.

<p><b>(A)</b> GFP-LC3/HeLa cells were treated with various concentrations of DMSO, and GFP green fluorescence dots appeared in cells. <b>(B)</b> LC3 conversion was determined by western blot in HeLa cells treated with different concentrations of DMSO. <b>(C)</b> Effect of DMSO on the autophagy rate. <b>(D)</b> GFP-LC3 /HeLa cells were inhibited by 3-MA, and then stimulated by 30% DMSO. Shrinkage of cell nuclei is a hallmark of apoptosis. <b>(E)</b> Autophagy reduced the apoptosis in the presence of 30% DMSO. **p<0.01 was considered statistically significant. The experiments were repeated 5 times. The number of cells used was approximately 500.</p

Effect of the concentration of CPAs: (A) number of cell blebs; (B) total area of cell blebs; (C) bleb index; (D) mortality rate of cells; (E) schematic of A_lip and A_cyto.

<p>HeLa cells were treated with a series of solutions containing different amounts of DMSO or glycerol, as well as the fluorochromes Hoechst and PI. After 30 minutes, when cells were stable, an inverted fluorescence microscope was used to observe cell death. For <b>(A)</b>, <b>(B)</b> and <b>(C)</b>, the cell number was approximately 40. For <b>(D)</b>, the cell number was approximately 500 and the experiment was repeated 5 times. For <b>(E)</b>, the red boundary denotes the lipid bilayer and the green boundary denotes the cortical cytoskeleton.</p

Hexadecylphosphate-Functionalized Iron Oxide Nanoparticles: Mild Oxidation of Benzyl C–H Bonds Exclusive to Carbonyls by Molecular Oxygen

We report here a specially designed catalytic system consisting of hexadecyl­phosphate-functionalized iron oxide nanoparticles in oil/water biphasic emulsion. The iron oxide nanoparticles act as catalytic centers and the surface-bonded hexadecyl­phosphates as peripheral units which tune the activity of iron oxide and the access of reactants to the catalytic centers. The catalytic system is highly effective to oxidize the benzyl C–H bonds in a series of compounds to carbonyls exclusively by molecular oxygen under mild conditions. The catalytic process, green and low cost, offers a novel concept to design highly effective catalysts with nanoparticles as active centers and surface-bonded organic phosphates as accelerants for oxidation reactions

Platinum Nanoparticles Encapsulated in MFI Zeolite Crystals by a Two-Step Dry Gel Conversion Method as a Highly Selective Hydrogenation Catalyst

A unique and well-controllable synthesis route to encapsulate metallic nanoparticles in the interior of MFI zeolite crystals has been developed. In the first step, hierarchical micro-mesoporous ZSM-5 zeolite was obtained by alkali treatment, and the platinum was deposited mainly in the pores. Then the precursor was covered with a gel similar in composition to silicalite-1 zeolite, which was structurally converted as whole to the Pt-encapsulated MFI zeolite employing the dry gel conversion method. With this method, the metal species, content, size, and encapsulation in the zeolite are easily controllable. The highly thermally stable Pt nanoparticles encapsulated in MFI zeolites kept their original size after a high-temperature catalytic test for CO oxidation. Because of the size selectivity of the MFI zeolite, the current Pt@MFI catalyst was highly active for hydrogenation of nitrobenzene but inert for hydrogenation of 2,3-dimethylnitrobenzene. Also, the Pt@MFI catalyst is highly selective for the hydrogenation of 4-nitrostyrene, whereas impregnated Pt/ZSM-5 is totally nonselective under the same conditions. The high performance of the Pt nanoparticles encapsulated within MFI crystals should bring about opportunities for new catalytic reactions

Acid-Resistant Catalysis without Use of Noble Metals: Carbon Nitride with Underlying Nickel

A nanocomposite able to function as a hydrogenation catalyst under strongly acidic conditions without the presence of noble metals is synthesized and thoroughly studied. This specially designed catalyst possesses a unique structure composed of carbon nitride (CN) with underlying nickel, in which the nickel endows the CN with new active sites for hydrogen adsorption and activation while it itself is physically isolated from the reactive environment and protected from poisoning or loss. The CN is inert for hydrogenation without the help of nickel. The catalyst shows good performance for hydrogenation of nitro compounds under strong acidic conditions, including the one-step hydrogenation of nitrobenzene in 1.5 M H₂SO₄ to produce <i>p</i>-amoniophenol, for which the acid in the reaction system has restricted the catalyst only to noble metals in previous studies. Further characterization has demonstrated that the nickel in the catalyst is in an electron-deficient state because some of its electron has been donated to CN (HRTEM, PES); thus, the hydrogen can be directly adsorbed and activated by the CN (HD exchange, in situ IR and NMR). With this structure, the active nickel is protected by inert CN from the corrosion of acid, and the inert CN is activated by the nickel for catalytic hydrogenation. The assembly of them gives a new catalyst that is effective and stable for hydrogenation even under a strongly acidic environment