Gambaran Pengetahuan Tentang Anemia Gizi Besi pada Remaja Putri di SMA Negeri 3 Manado

Remaja putri rentan terhadap anemia gizi besi, dalam usia remaja terjadi perubahan fisik san hormonal. Perkembangan ini mempengaruhi kebutuhan zat gizi dimasa remaja. Kebutuhan akan zat besi pada remaja sering tidak terpenuhi karena remaja putri memiliki kebiasaan makan yang buruk. Dampak anemia gizi besi akan lebih serius efeknya karena remaja putri nantinya akan hamil dan melahirkan anak, sehingga dapat meningkatkan bahaya kematian ibu dan kelahiran prematur. Data World Health Organization (WHO) pada tahun 2019 di Indonesia angka kejadian anemia pada perempuan 15-49 tahun yaitu sebesar 31,2%. Penelitian dilakukan bulan Mei-Agustus 2021 dengan tujuan mendeskripsikan pengetahuan tentang anemia gizi besi pada remaja putri di SMA Negeri 3 Manado. Menggunakan jenis penelitian kuantitatif dengan desain penelitian deskriptif dengan jumlah sampel 241 responden. Hasil penelitian berdasarkan pengumpulan data menggunakan kuesioner pengetahuan tentang anemia gizi besi diperoleh bahwa responden dengan kategori pengetahuan baik yaitu sebanyak 59 remaja putri (24,5%) kategori pengetahuan cukup sebanyak 144 remaja putri (59,8%), dan kategori pengetahuan kurang sebanyak 38 remaja putri (15,8%). Kesimpulan dari penelitian ini adalah sebagian besar remaja putri di SMA Negeri 3 Manado berada pada kategori pengetahuan cukup yaitu sebanyak 144 orang (59,8%). Kata Kunci: Anemia Gizi Besi, Remaja Putri ABSTRACTAdolescent girls are susceptible to iron deficiency anemia, in adolescence there are physical changes in hormonal san. This development affects the nutritional needs in adolescence. The need for iron in adolescents often goes unmet because young women have poor eating habits. The impact of iron deficiency anemia will be more serious because young women will later become pregnant and give birth to children, so it can increase the danger of maternal death and premature birth. World Health Organization (WHO) data in 2019 in Indonesia the incidence of anemia in women 15-49 years is 31.2%. The study was conducted in May-August 2021 with the aim of describing knowledge about iron deficiency anemia in young women in State High School 3 Manado. Using quantitative research types with descriptive research designs with a sample number of 241 respondents. The results of the study based on data collection using knowledge questionnaires about iron deficiency anemia were obtained that respondents with good knowledge categories were as many as 59 young women (24.5%) enough knowledge categories as many as 144 young women (59.8%), and less knowledge categories as many as 38 young women (15.8%). The conclusion of this study is that most of the young women in State High School 3 Manado are in the category of sufficient knowledge, which is as many as 144 people (59.8%). Keywords: Iron Deficiency Anemia, Adolescent Girl Â

Gambaran Kadar Kalium Serum Pada Pasien Penyakit Ginjal Kronik Stadium 5 Non Dialisis Di Manado

: Potassium is the main intracellular ion in the body and plays a key role in maintaining cell function. Total body potassium distributed 98% in intracellular and 2% in extracellular fluid. A slight change in the distribution of these can cause hypokalemia or hyperkalemia. A healthy kidney has great capacity to maintain potassium homeostasis in the cace of excess potassium. The kidney is primarily responsible for maintaining total body potassium content by matching potassium intake with potassium excretion. This study aimed to obtain the profile of potassium serum in non dialysis CKD stage 5 patients in Manado. This was an obsevartional descriptive study. There were 35 blood samples obtained from patients in Nephrology-Hypertension Polyclinic and IRINA of Prof. Dr. R.D Kandou Hospital and Teling Adventist Hospital. There were 11 samples (31,4%) with hypokalemia consisted of 6 home-care patients (35.3%) and 5 hospital-care patients (27.8%), 15 samples (42.9%) were in normal range consisted of 8 home-care patients (47.1%) and 7 hospital-care patients (38.9%), and 9 samples (25.7%) with hyperkalemia consisted of 3 home-care patients (17.6%) and 6 hospital-care patients (33,3%) from total non-dialysis CKD stage 5 samples resulted from laboratory examination. Conclusion: In non dialysis CKD stage 5 patients in Manado, normokalemia was the most common found than hypokalemia and hyperkalemia

Impact of Hydrogen Bonding on the Susceptibility of Peptides to Oxidation

The tendency of peptides to be oxidized is intimately connected with their function and even their ability to exist in an oxidative environment. Here we report high-level theoretical studies that show that hydrogen bonding can alter the susceptibility of peptides to oxidation, with complexation to a hydrogen-bond acceptor facilitating oxidation, and vice versa, impacting the feasibility of a diverse range of biological processes. It can even provide an energetically viable mechanistic alternative to direct hydrogen-atom abstraction. We find that hydrogen bonding to representative reactive groups leads to a broad (?400?kJ?mol?1) spectrum of ionization energies in the case of model amide, thiol and phenol systems. While some of the oxidative processes at the extreme ends of the spectrum are energetically prohibitive, subtle environmental and solvent effects could potentially mitigate the situation, leading to a balance between hydrogen bonding and oxidative susceptibility

AgCl-induced hot salt stress corrosion cracking in a titanium alloy

The mechanism of AgCl-induced stress corrosion cracking of Ti-6246 was examined at 500 MPa and 380 °C for 24 h exposures. SEM and STEM-EDX examination of a FIB-sectioned blister and crack showed that metallic Ag was formed and migrated along the crack. TEM analysis also revealed the presence of SnO2 and Al2O3 corrosion products mixed into TiO2. The fracture surface has a transgranular nature with a brittle appearance in the primary α phase. Long, straight and non-interacting dislocations were observed in a brittle appearance fractured primary α grain, with basal and pyramidal traces. This is consistent with a dislocation emission view of the cracking mechanism

Quantum mechanics/molecular mechanics studies on the mechanism of action of cofactor pyridoxal 5'-phosphate in ornithine 4,5-aminomutase

A computational study was performed on the experimentally elusive cyclisation step in the cofactor pyridoxal 5′-phosphate (PLP)-dependent D-ornithine 4,5-aminomutase (OAM)-catalysed reaction. Calculations using both model systems and a combined quantum mechanics/molecular mechanics approach suggest that regulation of the cyclic radical intermediate is achieved through the synergy of the intrinsic catalytic power of cofactor PLP and the active site of the enzyme. The captodative effect of PLP is balanced by an enzyme active site that controls the deprotonation of both the pyridine nitrogen atom (N1) and the Schiff-base nitrogen atom (N2). Furthermore, electrostatic interactions between the terminal carboxylate and amino groups of the substrate and Arg297 and Glu81 impose substantial “strain” energy on the orientation of the cyclic intermediate to control its trajectory. In addition the “strain” energy, which appears to be sensitive to both the number of carbon atoms in the substrate/analogue and the position of the radical intermediates, may play a key role in controlling the transition of the enzyme from the closed to the open state. Our results provide new insights into several aspects of the radical mechanism in aminomutase catalysis and broaden our understanding of cofactor PLP-dependent reactions

Identification of a Small Molecule Anti-biofilm Agent Against Salmonella enterica

Biofilm formation is a common strategy utilized by bacterial pathogens to establish persistence in a host niche. Salmonella enterica serovar Typhi, the etiological agent of Typhoid fever, relies on biofilm formation in the gallbladder to chronically colonize asymptomatic carriers, allowing for transmission to uninfected individuals. S. enterica serovar Typhimurium utilizes biofilms to achieve persistence in human and animal hosts, an issue of both clinical and agricultural importance. Here, we identify a compound that selectively inhibits biofilm formation in both S. Typhi and S. Typhimurium serovars at early stages of biofilm development with an EC50 of 21.0 and 7.4 μM, respectively. We find that this compound, T315, also reduces biofilm formation in Acinetobacter baumannii, a nosocomial and opportunistic pathogen with rising antibiotic resistance. T315 treatment in conjunction with sub-MIC dosing of ciprofloxacin further reduces S. enterica biofilm formation, demonstrating the potential of such combination therapies for therapeutic development. Through synthesis of two biotin-labeled T315 probes and subsequent pull-down and proteomics analysis, we identified a T315 binding target: WrbA, a flavin mononucleotide-dependent NADH:quinone oxidoreductase. Using a S. Typhimurium strain lacking WrbA we demonstrate that this factor contributes to endogenous S. enterica biofilm formation processes and is required for full T315 anti-biofilm activity. We suggest WrbA as a promising target for further development of anti-biofilm agents in Salmonella, with potential for use against additional bacterial pathogens. The development of anti-biofilm therapeutics will be essential to combat chronic carriage of Typhoid fever and thus accomplish a meaningful reduction of global disease burden

New hydroxylated metabolites of 4-monochlorobiphenyl in whole poplar plants

Two new monohydroxy metabolites of 4-monochlorobiphenyl (CB3) were positively identified using three newly synthesized monohydroxy compounds of CB3: 2-hydroxy-4-chlorobiphenyl (2OH-CB3), 3-hydroxy-4-chlorobiphenyl (3OH-CB3) and 4-hydroxy-3-chlorobiphenyl (4OH-CB2). New metabolites of CB3, including 2OH-CB3 and 3OH-CB3, were confirmed in whole poplars (Populus deltoides × nigra, DN34), a model plant in the application of phytoremediation. Furthermore, the concentrations and masses of 2OH-CB3 and 3OH-CB3 formed in various tissues of whole poplar plants and controls were measured. Results showed that 2OH-CB3 was the major product in these two OH-CB3s with chlorine and hydroxyl moieties in the same phenyl ring of CB3. Masses of 2OH-CB3 and 3OH-CB3 in tissues of whole poplar plants were much higher than those in the hydroponic solution, strongly indicating that the poplar plant itself metabolizes CB3 to both 2OH-CB3 and 3OH-CB3. The total yield of 2OH-CB3 and 3OH-CB3, with chlorine and hydroxyl in the same phenyl ring of CB3, was less than that of three previously found OH-CB3s with chlorine and hydroxyl in the opposite phenyl rings of CB3 (2'OH-CB3, 3'OH-CB3, and 4'OH-CB3). Finally, these two newly detected OH-CB3s from CB3 in this work also suggests that the metabolic pathway was via epoxide intermediates. These five OH-CB3s clearly showed the complete metabolism profile from CB3 to monohydroxylated CB3. More importantly, it's the first report and confirmation of 2OH-CB3 and 3OH-CB3 (new metabolites of CB3) in a living organism

Adenosyl Radical: Reagent and Catalyst in Enzyme Reactions

Adenosine is undoubtedly an ancient biological molecule that is a component of many enzyme cofactors: ATP, FADH, NAD(P)H, and coenzyme A, to name but a few, and, of course, of RNA. Here we present an overview of the role of adenosine in its most reactive form: as an organic radical formed either by homolytic cleavage of adenosylcobalamin (coenzyme B 12 , AdoCbl) or by single-electron reduction of S -adenosylmethionine (AdoMet) complexed to an iron–sulfur cluster. Although many of the enzymes we discuss are newly discovered, adenosine's role as a radical cofactor most likely arose very early in evolution, before the advent of photosynthesis and the production of molecular oxygen, which rapidly inactivates many radical enzymes. AdoCbl-dependent enzymes appear to be confined to a rather narrow repertoire of rearrangement reactions involving 1,2-hydrogen atom migrations; nevertheless, mechanistic insights gained from studying these enzymes have proved extremely valuable in understanding how enzymes generate and control highly reactive free radical intermediates. In contrast, there has been a recent explosion in the number of radical-AdoMet enzymes discovered that catalyze a remarkably wide range of chemically challenging reactions; here there is much still to learn about their mechanisms. Although all the radical-AdoMet enzymes so far characterized come from anaerobically growing microbes and are very oxygen sensitive, there is tantalizing evidence that some of these enzymes might be active in aerobic organisms including humans.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/69165/1/604_ftp.pd