Trends in the assessment of multidrug efficiency against identified bacterial strains isolated from wounds at El-Demerdash Hospital, Egypt

Multidrug-resistant (MDR) bacteria is a severe problem for universal public health which increases morbidity and mortality rate. These resistant bacteria lead to ineffective treatment of drugs resulting in the spreading and persistence of infections. So, the major target of this study is to estimate the competence of multidrug antibacterial agents against bacterial strains isolated from wound samples and then identify the most potent Multidrug-resistant (MDR) bacteria. Fifty wound swab specimens were gathered from various wounds and several patients from the Central Microbiology Laboratory of El-Demerdash Hospital, Cairo, Egypt. Eighty- nine bacterial isolates were isolated from fifty wound samples then cultured on different media and tested for their susceptibility to different thirty antibiotic discs using the agar disc diffusion method. After recording the results of the susceptibility test, the post potent resistant bacterial isolates recorded 3 bacterial isolates which resistant to 30 different antibiotic types. These resistant bacterial isolates were identified using morphological, biochemical, and molecular techniques. The results recorded that the post potent resistant bacterial isolates identified as Klebsiella oxytoca, Pseudomonas aeruginosa, and Escherichia coli. This study concluded that with the increase in the random use of antibiotic drugs resulted in the presence of multi-antibacterial resistant strains. There are bacterial strains that were isolated from wounds in patients at El-Demerdash Hospital, Egypt, and identified. They can resist about thirty different antibiotic discs. Abbreviation: Multiple antibiotic resistance (MAR)

Empirical Models for Power and Energy Requirements II : A Powered Implement Operation in Serdang Sandy Clay Loam, Malaysia

Power and energy requirements were measured with an instrumented tractor for rotary tilling in Serdang sandy clay loam soil.  The effects of travel speed and rotor speed upon the measured data were investigated.  Power model from orthogonal regression analysis was formulated based on linear and quadratic functions of travel speed and bite length.  Fuel consumption model from regression analysis was formulated based on linear tractor PTO power as well as linear equivalent tractor PTO power.  Fuel consumption rates predicted by ASAE D497.3 were found to be 25% to 28% overestimates of the values predicted by the model developed.  However, fuel consumption rates reported by OECD Tractor Test were found to be 1% to 9% lower than the fuel consumption rates predicted by the model developed.  A comparison of power and energy requirements for both powered and draught implements showed that the disk harrow was the most energy efficient implement in terms of fuel consumption and specific energy followed by the rotary tiller, disk plough and mouldboard.  Finally, average PTO power, fuel consumption, wheel slip, wheel power and specific energy for a powered implement are presented

Design and Development of A Three-Point Auto Hitch Dynamometer for An Agricultural Tractor

This paper describes the design, development and calibration of a three-point auto hitch dynamometer for measuring the horizontal and vertical forces that existed at the three-point hitch of an agricultural tractor.  The design concept of the dynamometer was based on an instrumented inverted U frame assembly that was mounted between tractor links and implement. The design incorporates for both lower point hitch spread and mast height adjustments, and quick hitch capability in accordance with category 1 and II three-point hitch system.  The force sensing elements were comprised of three steel extended octagonal ring transducers that were located between the inverted U frame and hook brackets.  Electrical resistance strain gauges were mounted on the extended octagonal ring transducer at strain angle nodes to independently monitor strains that were proportional to the horizontal and vertical forces at the ring center. Each transducer was designed for maximum horizontal and vertical forces of 25 kN and 10 kN at measurement mean sensitivities of 25.19 µStrain/kN and 25.60 µStrain/kN, respectively. However, the complete dynamometer has been designed to measure the maximum resultant horizontal and vertical forces of 50 kN and 20 kN, respectively.  Field demonstration tests on the dynamometer and data acquisition system showed that they were able to function effectively as intended.  The data acquisition system was able to successfully scan and record the dynamometer signals as programmed.  This dynamometer was part of the complete instrumentation system to be developed onboard a Massey Ferguson 3060 tractor for the generation of a comprehensive database on the power and energy requirements of the tractor and its working implement in the field

On-The-Go Assessment of Seed Metering Unit Performance Using an Opto-Electronic Sensor

The main objective of a seeding machine is to put seeds at a desired depth and spacing within the row. Seed spacing uniformity is one of the most important criteria in evaluating planter performance. Therefore, the objective of this research work was to develop an opt-electronic monitoring system for assessment of a mechanical planter seed metering unit performance. The developed system was used to monitor seed flow and to measure seed spacing from the metering system of the row crop planter. The developed system comprised of an optoelectronic sensor for seeds detection, a rotary encoder for forward speed and seed position measurement, amplifiers for adjusting sensors signals, a microcontroller for synchronizing sensors signals, and a PC for operating the program and displaying process. The developed system has been successfully tested on chickpeas seeds at two operating speeds (1.3 m/s and 1.9 m/s). Both numbers and locations of the dropped seeds were assessed. The results indicated that the developed system can be accurately used to detect seeds flow from the metering system with overall system errors of ±4% and ± 10% for speeds of 1.3m/s and 1.9m/s, respectively, compared to manual measurements. Further extensive testing on different crops under actual field conditions are highly recommended to ensure reliability of the developed system