Hubungan Kepemimpinan Kepala Ruangan Menurut Persepsi Perawat Terhadap Motivasi Kerja Perawat Pelaksana Di Ruang Instalasi Rawat Inap F Blu Rsup Prof. Dr. R.d. Kandou Manado

: Leadership is the ability to provide a constructive influence others to do the business of the cooperative achieve the planned objectives. Motivation to work an employee is usually indicated by a continuous activity, and goal oriented. The purpose of this study is on the analysis of the relationship to the head of the room under the leadership of the nurse\u27s perception of the motivation of nurses in the inpatient department Prof.Dr.R.D. Kandou F BLU Manado. Analytic survey research design using a cross-sectional approach. Popolasi that all nurses in the inpatient space F BLU Prof. Dr. R.D. Kandou Manado. Total sampling using sampling. Data processed through univariate and bivariate analysis using Chi square with Fisher\u27s exact test alternatives. Results obtained by analysis of the probability (p) = 0.003 <α (0.05), which means that Ho is rejected. Conclusion, an association under the leadership of head room nurse perceptions of the work motivation of nurses in the inpatient department Prof.Dr.RDKandou F BLU Manado. Suggestions, for a head irina F would increase the motivation to work more room nurses, and for nurses would be to maintain and further enhance the motivation to work better

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration

Analysis of <i>Giardia lamblia</i> Interactions with Polymer Surfaces Using a Microarray Approach

The interaction of the waterborne protozoan parasite, <i>Giardia lamblia</i>, with polymeric materials was investigated by microarray screening of 652 polymers. Polymers were identified which either bound <i>G. lamblia</i> cysts or prevented their binding. Correlation of material properties such as wettability and surface roughness with cyst attachment revealed no influence of these factors upon <i>Giardia</i> adhesion. However, the study of polymer composition allowed the correlation of binding and generation of polymer structure function relationships; glycol and aromatic functionalities appeared to prevent adhesion, whereas secondary amine groups promoted adhesion, in agreement with previous literature. A significant reduction in attachment was observed following both cyst treatments with proteinase K and performing experiments at extremes of pH (2 and 12). It is suggested that proteinase K removes the proteins needed for specific surface interactions, whereas extremes of pH influence either protonation of the polymer or the surface charge of the cysts. The mechanism by which the protozoa attach to polymeric surfaces is proposed to be through ion–pair interactions. Improved understanding of <i>G. lamblia</i> surface interactions could assist in predicting transport and fate behavior in the environment and contribute to better design of water treatment processes, while the polymers identified in this work could find use in sensor applications and membrane filtration