Solar panels are a very effective source of renewable energy in Indonesia. To increase the output power of solar panels, especially on the static solar panels, a reflector is required as an additional device. This paper describes development of a static solar panel equipped with an active reflector. Five LDR sensors are mounted on the top of the reflector, to detect the highest solar intensity. Meanwhile, a DC motor as a reflector drive system is mounted on the bottom of the reflector. The tilt angle of the solar panel is 450 to the negative x-axis and the reflector is 750 to the positive x-axis. The reflector will move in a semi-circular path, following the direction of the highest solar intensity detected by the LDR sensor. Three different reflectors used to optimize the output power, there are stainless steel, aluminium foil, and mirror. Solar panel with mirror reflector produces the largest output power compared to other reflectors. The output power of this device increases 1.6 times to the solar panels without reflector.
Pulsed Electromagnetic Fields (PEMF) is reported to encourage the healing of nonunion fractures. However, the mechanism by which this occurs is still not known. Wnt signaling pathways are believed to be important signaling pathways in bone formation. This study will evaluate the healing of delayed union femur fracture, given PEMF exposure. 48 Spraque Dawley rats were fracturized at the left femoral shaft. These rats were randomized into two groups: A control group (24 rats) and the PEMF group (24 rats). The PEMF group was given PEMF exposure of 1.6 mT, with a frequency of 50 Hz for 4 h every day for 5, 10, 18 and 28 days, while the control group was not given PEMF exposure. Consequently, on days 5, 10, 18 and 28 days after fracture, 6 rats from each group were sacrificed. Callus bone was used for histological and RT-PCR examination on the expression of Wnt10b, Wnt5a and β-catenin. Blood samples were taken to examine Alkaline Phosphatase (ALP) activity using the ELISA method. Hematoxylin Eosin (HE) staining results showed that in the initial phase of healing, fibrous tissue in the fracture gap of the PEMF group was less compared to the control group. In the PEMF group, ALP activity increased significantly on day 10. This is thought to be related to an increase in osteoblast activity in a bone matrix formation. Furthermore, RT-PCR examination results showed that Wnt10b, Wnt5a and β-catenin gene expression was higher in the PEMF group compared to the control group. It can be concluded that PEMF exposure is thought to accelerate delayed union fracture healing through the Wnt signal pathway.
Delayed union and nonunion fractures are clinical challenges for orthopedic surgeons. The development of fracture complications, such as delayed union and nonunion fractures, is still difficult to predict. Various methods are being investigated to improve fracture healing and prevent complications in patients. There are various methods to promote fracture healing, broadly divided into biological, chemical, and physical methods. One of the most widely used physical methods to promote fracture healing is the pulsed electromagnetic field (PEMF). This study aimed to evaluate the healing process of delayed union fracture after being stimulated by PEMF. Twenty-four rats were randomly divided into two groups: the control group (n = 12) and the PEMF group (n = 12). Delayed union fracture was performed on the left femur of all rats. Subsequently, the PEMF group was given PEMF stimulus with a magnetic field intensity of 1.6 mT and a frequency of 50 Hz for 4 hours/day and 7 days/week. The fracture healing process was evaluated on days 5, 10, 18, and 28 based on the bone callus histology using safranin O fast green (SOFG) staining. The results of the histological analysis showed that bone cartilage was higher in the PEMF group than in the control group throughout the observation period. In addition, the PEMF group had less fibrous tissue at the beginning of the healing. This finding indicates PEMF stimulation has an effect on inducing osteogenesis on fracture healing and reducing the risk of delayed union.
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