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Abstrak :
LATAR BELAKANG: Terbang dengan menggunakan pesawat yang memiliki kecepatan tinggi melebihi kecepatan suara (high performance air craft), yang mampu menghasilkan akselerasi +5Gz sampai +9Gz bahkan lebih terutama pada saat melakukan manuver, merupakan suatu tantangan tersendiri yang membutuhkan kepaiawaian dan sikap profesional. Banyak faktor yang mempengaruhi relaxed +Gz force tolerance seperti mean arterial pressure, hasil puncak ekspirasi dan posisi tubuh. METODE: Desain penelitian adalah studi korelasi, yang dilakukan di Lakespra Saryanto Jakarta. Dengan menggunakan populasi semua bakal calon penerbang TNI AU dan subyek dipilih secara random sederhana, semua yang memenuhi kriteria inklusi diambil. Sampel yang diambil sebanyak 31 orang, data yang dikumpulkan berasal dari kuesioner, pencatatan human centrifuge. Hasil penelitian kemudian dilakukan uji statistik berupa analisis regresi inner untnk melihat pengaruh arus puncak ekspirasi terhadap relaxed+Gz force tolerance serta faktor faal yang berpengaruh. HASIL: Rata-rata relaxed +G, -force tolerance 7,51 ± 0,71 G, selanjutnya beberapa faktor yang berpengaruh terhadap relaxed +Gr force tolerance antara lain arus puncak ekspirasi: koefisien regresi sebesar -0,358 dan kemaknaan p = 0,073; mean arterial pressure: koefisien regresi sebesar 0,047 dan kemaknaan p = 0,065, serta forced expiratory in 1 second: koefisien regresi sebesar 1,246 dan kemaknaan p = 0,012) dan yang paling dominan adalah-forced expiratory in l second. KESIMPULAN: Relaxed ±Gz force tolerance dipengaruhi oleh arus puncak ekspirasi. Di samping itu relaxed G tolerance berkaitan pula dengan mean arterial pressure dan FEV1.

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The Influence of Peak Expiratory Flow Rate to Relaxed +Gz Force Tolerance at Human Centrifuge Training in Pilot Candidates of Indonesian Air Force 2002BACK GROUND: Flying high performance fighter aircraft is a challenging and demanding profession which regularly imposes significant acceleration force on pilot, particularly during air combat maneuvering, in which +Gz level of +5 to ±9 G or more are frequently experienced. Relaxed +Gz force tolerance is influenced by mean arterial pressure, peak expiratory flow rate and body position. METHODS: Correlation study design was chosen for this research in Lakespra Saryanto. Simple random sampling is used to choose the subject from all pilot candidates in the population. Thirty one subjects were selected consecutively according to inclusion criteria. Data collected from questionnaire, human centrifuge records. The results were analyzed by linear regression analysis to evaluate the influence of peak expiratory flow rate and relaxed +Gz tolerance, and other physiological factors which might influence the relaxed +Gz tolerance. RESULTS: The mean value of relaxed +Crz tolerance was 7,51 ± 0,71G. Several factors that influence of relaxed +Gz tolerance was peak expiratory rate (regression coefficient - 0,358, p = 0,073); mean arterial pressure (regression coefficient =0,047, p = 0,065); forced expiratory volume in 1 second (regression coefficient 1,246, p = 0,012). The most dominant was forced expiratory volume in 1 second. CONCLUSIONS: Relaxed +Gz force tolerance was influenced by peak expiratory flow rate, forced expiratory volume in 1 second and mean arterial pressure.

Abstrak :
[ABSTRAK
Pembuatan bahan Cu-ZnFerrite dapat dilakukan dengan teknik Flow Injection Synthesis-FIS, dimana proses pembentukan bahan dilakukan secara reaksi kimia basah yang mengh asilkan pengendapan ?yield, dengan bahan baku FeCl2.4H2O, FeCl2.6H2O, CuCl2.2H2O, dan ZnCl2. Teknik FIS merupakan metode ko-presipitasi yang dilakukan secara terstruktur sehingga kecepatan reaksi, temperatur, dan pH bahan baku dapat diatur, direkam dengan skala produksi dapat dikembangkan dalam jumlah yang relatif besar. Fraksi yield merupakan fungsi dari pH larutan dan temperatur reagent yang berada dalam reaktor FIS. Parameter proses seperti; pH, temperatur (T), dan waktu proses(t) dapat direkam dengan memori elektronik SD-Card pH datalogger. Pengolahan data parameter proses pH dapat dilakukan relatif cepat sehingga diperoleh estimasi nilai entalpi dan kinetika pembentukan partikel bahan dengan teori dasar Avrami-Ozawa dan Kissinger. Salah satu macam produk yang diteliti adalah Bahan Cu-ZnFerrite. Karakteristik dasar bahan uji tersebut mampu menghsilkan nilai validitas dan reliabilitas tinggi yang direpresentasikan dalam bentuk nilai kesalahan pada rata rata atom. Dari 6 sampel berbeda tingkat krsalahan pembentuk senyawa Cu-ZnFerrite 0.85% dengan reliabilitas >0.9. Hal ini menunjukkan sistem FIS sebagai sistem alat ukur dan pemrosesan bahan Cu-Znferrite memiliki kemampuan ukur dan proses yang sahih-valid dan konsistensi-reliability, sehingga memungkinkan dapat digunakan untuk estimasi energi pembentukan pembentukan Cu-ZnFerrite dengan formulasi Cu(1-x) ZnxFe2O4 pada rentang x antara 0.35 sampai 0.45. Hasil estimasi nilai entalpi rata rata Cu-ZnFerrite 0.65[kcal/mol]. Secara kinetik bentuk partikel adalah batang berukuran paling besar 1,53 um dengan laju pembentukan 50 [nm/sec]. Uji Karakterisasi Difraksi SinarX, Ukuran partikel-Particle Size Analyser, dan Permagraf memperlihatkan partikel bahan Cu-ZnFerrite mudah dipengaruhi oleh atom yang berada baik pada sisi tetrahedral maupun sisi oktahedral Kristal spinel bahan.;

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ABSTRACT
The manufacture of Cu-ZnFerrite can be done by using the Technical of Flow Injection Synthesis-FIS, where the material forming process carried out by wet chemical reactions that produce the precipitation matter ?yield. The raw materials were; FeCl2.4H2O, FeCl3.6H2O, CuCl3.2H2O, and ZnCl2. The FIS technique developed by major reactor components such as; adiabatic reactor, peristaltic pumps and pH datalogger, where a co-precipitation synthesis method is done in a structured so that the reaction speed, temperature, and pH of the raw material can be arranged, recorded and scale of production can be developed in a relatively large amount. The process parameters such of pH, temperature (T), and the processing time (t) were recorded with an electronic memory SD-Card Datalogger and it can be performed in order to obtain both the enthalpy value and the kinetics of the material formation. The particle kinetic can be analyzed with the basic theory of Avrami-Ozawa and Kissinger. The baseline characteristics of the test material capable to result of both the instruments validity and reliability parameter values, which are represented in the form of a low error rate on the average atomic-forming compounds Cu-ZnFerrite a rounds 0.85% and reliability value more than 0.9 .The FIS system as a system of measuring and processing of Cu-Znferrite have ability to measure the parameter process as valid and consistency with high-reliability. In the estimation process of the formation energy of formation of Cu-ZnFerrite or as Cu (1-x) ZnxFe2O4 where x in the range of 0:35 to 0:45. the formation enthalpy of the Cu-ZnFerrite is 0.65 [kcal / mol], the particle shape is rod with a 1.53 um size and the growth formation rate is 50 [nm / sec]. The characterization of either X-ray Diffraction, Particle Size Analyser, or Permagraf show the Cu-ZnFerrite materials are easily become unstable particles by atomic both in the tetrahedral or octahedral spinel crystal sides; The manufacture of Cu-ZnFerrite can be done by using the Technical of Flow Injection Synthesis-FIS, where the material forming process carried out by wet chemical reactions that produce the precipitation matter ?yield. The raw materials were; FeCl2.4H2O, FeCl3.6H2O, CuCl3.2H2O, and ZnCl2. The FIS technique developed by major reactor components such as; adiabatic reactor, peristaltic pumps and pH datalogger, where a co-precipitation synthesis method is done in a structured so that the reaction speed, temperature, and pH of the raw material can be arranged, recorded and scale of production can be developed in a relatively large amount. The process parameters such of pH, temperature (T), and the processing time (t) were recorded with an electronic memory SD-Card Datalogger and it can be performed in order to obtain both the enthalpy value and the kinetics of the material formation. The particle kinetic can be analyzed with the basic theory of Avrami-Ozawa and Kissinger. The baseline characteristics of the test material capable to result of both the instruments validity and reliability parameter values, which are represented in the form of a low error rate on the average atomic-forming compounds Cu-ZnFerrite a rounds 0.85% and reliability value more than 0.9 .The FIS system as a system of measuring and processing of Cu-Znferrite have ability to measure the parameter process as valid and consistency with high-reliability. In the estimation process of the formation energy of formation of Cu-ZnFerrite or as Cu (1-x) ZnxFe2O4 where x in the range of 0:35 to 0:45. the formation enthalpy of the Cu-ZnFerrite is 0.65 [kcal / mol], the particle shape is rod with a 1.53 um size and the growth formation rate is 50 [nm / sec]. The characterization of either X-ray Diffraction, Particle Size Analyser, or Permagraf show the Cu-ZnFerrite materials are easily become unstable particles by atomic both in the tetrahedral or octahedral spinel crystal sides, The manufacture of Cu-ZnFerrite can be done by using the Technical of Flow Injection Synthesis-FIS, where the material forming process carried out by wet chemical reactions that produce the precipitation matter –yield. The raw materials were; FeCl2.4H2O, FeCl3.6H2O, CuCl3.2H2O, and ZnCl2. The FIS technique developed by major reactor components such as; adiabatic reactor, peristaltic pumps and pH datalogger, where a co-precipitation synthesis method is done in a structured so that the reaction speed, temperature, and pH of the raw material can be arranged, recorded and scale of production can be developed in a relatively large amount. The process parameters such of pH, temperature (T), and the processing time (t) were recorded with an electronic memory SD-Card Datalogger and it can be performed in order to obtain both the enthalpy value and the kinetics of the material formation. The particle kinetic can be analyzed with the basic theory of Avrami-Ozawa and Kissinger. The baseline characteristics of the test material capable to result of both the instruments validity and reliability parameter values, which are represented in the form of a low error rate on the average atomic-forming compounds Cu-ZnFerrite a rounds 0.85% and reliability value more than 0.9 .The FIS system as a system of measuring and processing of Cu-Znferrite have ability to measure the parameter process as valid and consistency with high-reliability. In the estimation process of the formation energy of formation of Cu-ZnFerrite or as Cu (1-x) ZnxFe2O4 where x in the range of 0:35 to 0:45. the formation enthalpy of the Cu-ZnFerrite is 0.65 [kcal / mol], the particle shape is rod with a 1.53 um size and the growth formation rate is 50 [nm / sec]. The characterization of either X-ray Diffraction, Particle Size Analyser, or Permagraf show the Cu-ZnFerrite materials are easily become unstable particles by atomic both in the tetrahedral or octahedral spinel crystal sides]

Abstrak :
Using enzymatic sensor to determine the level of captopril is an alternative method that is being widely developed. In research , made in captopril sensor using Screen Printed Electrode (SPE), because of its advantage of being practical and simple. Cu electrodeposition on SPE is being done by potential -0,480 V vs Ag½AgCl with variation of time deposition of 5, 30 and 60 second. This research finds that the optimum deposition time is 60 second by taking into loading amount of 6,92 x 10-6 gr.cm-2. Cu/SPE is then applied to the Flow Injection Analysis (FIA) system. The optimum result of sensor appears in the FIA system with at the flow rate of 0,5 mL/minute and KOH Concentration of 1 M. Cu/SPE Sensor in FIA system has LOD of 6,530 x 10-6 M and sensitivity of 308,80 μA.mM-1.cm-2. Cu/SPE sensor has good repeatability with value linearity of 0,9113 and %RSD of 1,75%. Selectivity test on the captopril to the glucose and lactose may produce better sensor. The application of Cu/SPE sensor has value %recovery of 96,29%.

Abstrak :
Usaha untuk membuat alat yang dapat mempermudah pekerjaan manusia dalam pengawasan, penelitian, dan perkembangan laboratorium analisa merupakan kecenderungan pada akhir abad 20 Otomatisasi instrumentasi di laboratorium menghasilkan banyak kemajuan dalam analisis kimia seperti sensitivitass, elektivitas. Presisi, kecepatan, biaya, dan jangkauan aplikasi yang luas. Salah satu contoh otomatisasi dalam analisis kimia adalah flow lryectiott Analysis atau FIA. FIA adalah metode analisis berdasarkan injeksi cairan sampel ke dalam aliran kontinyu tidak beruas dari suatu cairan yang sesuai. Injeksi sampel membentuk zona hasil reaksi kimia. Zona ini ditransportasikan menuju detector dan langsung diukur absorbansi, potensial elektroda atau parameter fisika lainnya. Modifikasi yang bisa dilakukan dalam FIA membuat metoda ini dapat menjadi metoda Analisis alternatif dan mempunyai jangkauan luas dalam komunitas analisis kimia. Pada penelitian yang dilakukan, dipelajari metoda penentuan klorida dengan teknik FIA. Prinsip penentuannya adalah pengukuran. besarnya absorbansi senyawa kompleks {Fe(SCN)}2. yang dihasilkan dari reaksi antara Fe3* dengan scN-. Ion SCN- ini dihasilkan dari reaksi antara ion cl- dengan Hg(SCN)2. Kelayakan teknik FIA ditentukan dengan parameter operasional FIA yaitu dispersi. Dispersi adalah perbandingan absorbansi yang tidak terdispersi dengan absorbansi FIA. Dispersi dipengaruhi volume injeksi sampel kecepatan alir pereaksi dan panjangk olom. Hargad ispersid ari percobaana dalah2 -6, hargai ni beradad alam range dipsersi untuk pengukuran Spektrofotomteri yaitu disperse sedang ( 3-10). Hasil percobaan membuktikan bahwa kenaikan volume injeksi sampel dan kecepatan alir pereaksj umumnya menyebabkan dispersi menurun. Sedangkan kenaikan panjang kolom menyebabkan dispersi meningkat. Dengan menggunakan kondisi optimum, dilakukan percobaan untuk Mengetahui pengaruhi on pengganggu terhadap hasil pengukuran. Ion pengganggu yang digunakan adalah sulfat dan karbonat pada konsentrasi sepersepuluh, setengah, satu' l0' dan 50 kali konsentrasi klorida. Sampai konsentrasi ion sulfat dan karbonat 50 kali konsentrasi klorida ternyata tidak memberikan perbedaan berarti dibandingkan dengan tanpa ion pengganggu tersebut. Batas deteksi pengukuran dengan F IA adalah 6'13 ppm sedangkan dengan konduktometri 3l 29 ppm.P erbandingan dengan titrasi Konduktometri tdak.memberikan perbedaan hasil yang berarti.

Abstrak :
Penentuan kadar kolesterol menggunakan sensor non-enzimatik pada saat ini banyak dikembangkan sebagai alternatif, sensor kolesterol non-enzimatik berupa perangkat yang praktis dan sederhana, digunakan Screen Printed Electrode SPE sebagai sensor, kemudian dimodifikasi dengan carbon nanotube CNT dan nafion Nf . Pada penelitian ini, digunakan oksida tembaga sebagai sensor non-enzimatik yang terdeposit dipermukaan SPE yang telah diteteskan CNT terfungsionalisasi-Nf, dengan metode elektrodeposisi menggunakan larutan CuSO4 0.01M dalam 0,1M H2SO4. Variasi, potensial dan waktu deposisi dilakukan untuk mendapatkan deposit Cu/CNT-Nf-SPE yang optimum, karakterisasi dengan SEM-EDX. Uji deteksi kolesterol dilakukan pada potensial 0.482V vs Ag/AgCl. Deposit Cu/CNT-Nf-SPE dengan tetesan CNT terfungsionalisasi-Nf pada potensial - 0.386V selama 300 detik merupakan yang paling optimum, karena mempunyai sensitifitas paling tertinggi sebesar 6220,6 ?A mM-1 cm-2, batas deteksi terendah sebesar 9,559 x 10-3 M dan linieritas paling baik sebesar R2 = 0.8856. Sensor deposit Cu/CNT-Nf-SPE optimum digunakan pada sistem FIA, didapatkan laju alir optimum 1,0 mL/menit, konsentrasi KOH 1 M sebagai carier dilihat dari RSD sebesar 1.0371 rata-rata respon arus 0.05046 mA. Pada variasi konsentrasi kolesterol dihasilkan linieritas sebesar R2 = 0.9916 dengan sensitifitas sebesar 3051,470 ?A mM-1 cm-2, batas deteksi terndah sebesar 9.5116 x 10-4 M sensor memiliki repeatabilitas yang baik dengan RSD sebesar 1.2944 n=10 . Uji stabilitas selama 4 hari pengamatan dengan RSD rata-rata sebesar 0.904574 . Deteksi kolesterol pada darah dengan KR 43.72. Uji selektivitas pada kolesterol terhadap sukrosa, fruktosa, dan asam askorbat. ......Determination of Cholesterol sensor using non enzymatic sensor has been developed as an alternative to non enzymatic cholesterol sensor with practical and simple device, using Screen Printed Electrode SPE as sensor, which then modified with carbon nanotube CNT dan Nafion membrane Nf . In this study, copper oxide are used as non enzymatic sensor deposited on the surface of SPE dripped with functionalized CNT Nf, using electodeposition method with solution of 0.01 M CuSO4 in 0.1 M H2SO4. Droplets of functionalized CNT Nf, deposition potential and time are varied to find the optimal Cu CNT Nf SPE deposit, characterize with SEM EDX. Cholesterol detection were tested at the potential of 0.482V vs Ag AgCl. The test found that the optimal deposit was Cu CNT Nf SPE functionalized CNT Nf at potential 0.386V for 300 seconds, with highest sensitivity of 6220.6 A mM 1 cm 2, lowest detection limit of 9.569 x 10 3 M, and best linearity of R2 0.8856. The optimal sensor depositition Cu CNT Nf SPE electrode were used on flow system FIA, with result of optimal flow rate of 1.0 mL min, concentration of 1 M KOH as a carrier seen from RSD of 1.0371 with average current response 0.05046 mA. The result of variation of cholesterol concentration was linearity of R2 0.9916 with sensitivity 3051.470 A mM 1 cm 2, lowest detection limit of 9.5116 x 10 4 M, sensor have good repeatability at RSD of 1.2944 n 10 . Stability test for 4 days resulted in RSD average of 0.904574 . cholesterol detection in a blood yield KR of 43.72 , and interference test on Cholesterol to glucose, sucrose, fructose, ascorbic acid.