Difference between revisions of "Team:Uppsala/Model"

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<p> L'<sub>t</sub> &#61; &#8722; (&rho; &#43; &beta; &#215; H) &#215; L<sub>t</sub> &#43; q &#215; &lambda; &#215; H &#215; A<sub>t</sub>  (Equation 1)</p>
 
<p> L'<sub>t</sub> &#61; &#8722; (&rho; &#43; &beta; &#215; H) &#215; L<sub>t</sub> &#43; q &#215; &lambda; &#215; H &#215; A<sub>t</sub>  (Equation 1)</p>
 
<p> A'<sub>t</sub> &#61; d&#215; &beta; &#215; L &#8722; &mu; &#215; A<sub>t</sub> &#8722; A&#215; u  (Equation 2)</p>
 
<p> A'<sub>t</sub> &#61; d&#215; &beta; &#215; L &#8722; &mu; &#215; A<sub>t</sub> &#8722; A&#215; u  (Equation 2)</p>
 
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Revision as of 20:22, 15 October 2018



Results



With the same starting conditions, and only varying when anthelmintics are used, four datasets were obtained. The four different data sets show how the density of parasites per hectare pasture and how the amount of parasites per horse varies for both the regular and the optimized use of anthelmintics. As mentioned in the method, two extreme points of starting values were used, which was when L0, the density of worms per ha pasture, is 1000, and A0 is either 10000 and 0. The results of the calculations are shown in the graphs (figure 1, 2, 3 and 4).



Parasites in horses, startvalue = 0

Figure 1. The amount of parasites per horse where regular and optimized use of anthelmintics is compared. The starting value is 0 parasites in the horse. Every time anthelmintics are used there is a sharp decline in the graph. Over a five year period, the regular use of anthelmintics, would be 10 times. For the optimized use, anthelmintics wouldn't be used at all, because the amount of parasites never exceeds the threshold. The amount of parasites in the horse are lower for the regular use of anthelmintics, but that is understandable, because anthelmintics is used more often. However, in the optimized use, the amount of parasites never exceed a theoretical amount which would affect the horse negatively.



Parasites on pasture, startvalue =0

Figure 2. How the density of parasites per hectare changes where regular and optimized use of anthelmintics is compared. The starting value of parasites in the horse are set to 0. The data fluctuates because the temperature changes day to day, which affects the development of an egg turning into a larvae. This can also be seen during the summer months, where the parasite density increases due to higher temperatures.



Parasites in horses, starvalue = 100000

Figure 3. The amount of parasites per horse where regular and optimized use of anthelmintics is compared. The starting value is 100 000 parasites in the horse. Every time anthelmintics are used there is a sharp decline in the graph. Over a five year period, the regular use of anthelmintics, would be 10 times. For the optimized use, anthelmintics would be used 7 times. The amount of parasites in the horse are lower for the regular use of anthelmintics, but that is understandable, because anthelmintics is used more often. However, in the optimized use, the amount of parasites never exceed an amount which will affect the horse negatively.



Parasites on pasture, startvalue = 100000

Figure 4. How the density of parasites per hectare changes where regular and optimized use of anthelmintics is compared. The starting value of parasites in the horse are set to 100 000. The data fluctuates because the temperature changes day to day, which affects the development of an egg turning into a larvae. This can also be seen during the summer months, where the parasite density increases due to higher temperatures.



The model shows that with an optimized use of anthelmintics, no anthelmintics cures would have to be used. In comparision to when the anthelmintics are used regulary, which means that anthelmintics would be used 10 times during a 5 year period. In the calculations where the starting value of parasites in the horse is at 100 000, there would be 3 cures less in the optimized method compared to the regular method. The anthelmintics resistance in parasites increases with the use of anthelmintics, which can be unnecessary in some cases. Which also can be seen in these model.

However, this model doesn’t take into account the encysted larva in the mucosa, this is due to lack of information about when the larva choses to encyst, and when it decides to burst to from the cyst. The communication between the adult parasites and the encysted larva is still a mystery that has to be solved to be able to form a even more accurate model.

Although there’s some shortcomings, the model clearly shows that using anthelmintics only when it’s needed, would decrease the usage of the anthelmintics, and in the long run restrain the growing resistance against different anthelmintics in the parasites.

Survey modeling



When we had chosen this years iGEM project, we wanted to investigate how a potential bacteria based product could be integrated in the community. Therefore a survey was conducted and sent out to horseowners all over Europe. Based on the answers we would get more insight into people's awareness of the large and small strongyle, and everything related to them. The marketing analysis was done in collaboration with the human practice part of the project, where human practises worked with which questions would be added into the survey, and the modeling group worked with creating a program that would be used to analyze the results.

In the modeling part of the project, we have created a analyzing program to interpret the answers we received from the survey. The purpose of the analyze was to look for correlations between different variables, for example; is there any correlation between how concerned people are about resistance to strongyle and if they are using any preventive treatments against strongyles?

The information acquired from the model could be used to, for example, investigate how knowledge about anthelmintic resistance could be disseminated in a efficacious manner. Additionally, we wanted to find a potential target market and get an idea of how a potential product could be marketed.



Design

In order to turn the results from the survey into usable data, we first needed to transform all the answers that were in text form to numerical form, and filter out incomplete values, as well. This was done to be able to analyse it further. The survey consisted of several questions that gave answers as discrete data. If we instead, had worked with continuous data, a regression analysis could have been performed. [10] Now, when using discrete data, we needed to find a suitable way to handle this. We chose to use a type of discrete scatter plot with valued points and with histograms. [11] In the discrete scatter plots, the size of the points increases every time a coupling occurs, see an example of a plot in figure 5. In this case, a coupling refers to when a x and a y value exist together. In this way the importance of a couple can easily be visualized. To suspect a correlation, the largest sized points should appear in some kind of linear, exponential or other interesting pattern.

Result

Results that we found interesting is further described on human practices page. To download the model written in R, click here. Figure 1 shows a descriptive discrete scatter plot with valued points and figure 2 shows an application of the latter plot based on real survey data.



An example of a descriptive discrete scatter plot with valued points

Figure 5. Descriptive discrete scatter plot with valued points. The numbers in the points describes the number of couplings.



An example discrete scatter plot with valued points based on data from the survey.

Figure 6. An example of an discrete scatter plot with valued points based on data from the survey.



Survey modeling

[1] Traversa D, Klei TR, Iorio R, Paoletti B, Lia RP, Otranto D, et al. Occurrence of anthelmintic resistant equine cyathostome populations in central and southern Italy. Prev Vet Med. 2007;82: 314–320.

[2] Lind EO, Kuzmina T, Uggla A, Waller PJ, Höglund J. A field study on the effect of some anthelmintics on cyathostomins of horses in sweden. Vet Res Commun. 2007;31: 53–65.

[3] Lind EO, Rautalinko E, Uggla A, Waller PJ, Morrison DA, Höglund J. Parasite control practices on Swedish horse farms. Acta Vet Scand. 2007;49: 25.

[4] Pech CL, Doole GJ, Pluske JM. Economic management of anthelmintic resistance: model and application. Aust J Agric Resour Econ. 2009;53: 585–602.

[5] Karlsson J. Parasite detection in extensively hold Gotland ponies. Uppsala: SLU, Institutionen för biomedicin och veterinär folkhälsovetenskap; 2015; 42.

[6] Rupasinghe D, Ogbourne CP. Laboratory studies on the effect of temperature on the development of the free-living stages of some strongylid nematodes of the horse. Zeitschrift f�r Parasitenkunde. 1978;55: 249–253.

[7] SMHI Meteorologiska observationer [Internet]. Lufttemperatur, dygnsvärde, Historiskt granskande. Available: http://opendata-download-metobs.smhi.se/explore/?parameter=1

[8] Council NZS. A guide to feed planning for sheep farmers. Beef+ Lamb New Zealand. 2012; 1–55.

[9] The Rules of Feeding Your Horse. In: The humane society of United States [Internet]. [cited 12 Oct 2018]. Available: http://www.humanesociety.org/animals/horses/tips/rules_horse_feeding.html

[10] Schneider, Astrid, Gerhard Hommel, och Maria Blettner. ”Linear Regression Analysis”. Deutsches Ärzteblatt International107, nr 44 (november 2010): 776–82. https://doi.org/10.3238/arztebl.2010.0776.

[11] The R graphs gallery (n.d.). #5 CORRELATION OF DISCRETE VARIABLES, http://www.r-graph-gallery.com/5-correlation-of-discrete-variables/ [2018-10-14]