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Have you ever heard of people saying correlation does not imply causation? If not, have you ever done experiments in class and been asked for data? If so, for what purpose did you do it? Why did teachers tell you to observe, collect, and analyze data? The answer is that observation, collection, and analysis are the basis of the scientific method. We can use statistical data to quantify biological data. Consistent data collection has made big data a critical field, particularly in biology. In the following, we will define statistical analysis, and describe the different types and methods to use statistics to analyze data in biology. We will also see some examples and introduce the emerging field of biostatistics and its importance.
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Jetzt kostenlos anmeldenHave you ever heard of people saying correlation does not imply causation? If not, have you ever done experiments in class and been asked for data? If so, for what purpose did you do it? Why did teachers tell you to observe, collect, and analyze data? The answer is that observation, collection, and analysis are the basis of the scientific method. We can use statistical data to quantify biological data. Consistent data collection has made big data a critical field, particularly in biology. In the following, we will define statistical analysis, and describe the different types and methods to use statistics to analyze data in biology. We will also see some examples and introduce the emerging field of biostatistics and its importance.
Statistical analysis involves collecting, exploring, and interpreting data sets to discover trends and patterns to make conclusions.
Within biology, we have the field of biostatistics.
Biostatistics is the field of study where researchers apply statistical analysis to biological topics.
For example, we can design biological experiments, with the purpose of extracting and analyzing data and finally interpreting the results to reach conclusions.
Essential parts of biological experiments that involve statistical analysis in order are:
1. Determining sample sizes
2. Testing hypotheses
3. Interpretation of data
After going over what statistical analysis is, we can now focus on the common types of statistical analysis used in biological experiments.
Descriptive statistical analysis
Inferential statistical analysis
While there are more statistical analyses than the two mentioned above, descriptive and inferential are the most common ones used in biological research.
Now that we've looked at the types of statistical analysis in biology. We can go over the common examples mentioned under descriptive and inferential statistics in more detail. The amount of information in this article will be limited to only the statistics we need to know in biology.
Correlational
Correlational studies or tests measure how closely related two or more variables are. By closely related, we mean linearly or how they change together at a constant rate. Scientists usually use this method to describe relationships between two or more variables without linking a cause and effect. Since correlational studies fall under descriptive statistics, they help describe simple relationships. For example, think about how the time spent studying, and grades correlate. Usually, we'd say they are positively correlated if students are studying actively.
We measure correlations using the correlation coefficient or r, ranging from -1 to +1.
The larger the slope, whether negative or positive, the steeper the line gets. The difference is that positive slopes lean or slants to the right compared to negative slopes, which tilt or incline to the left. The no-correlation graph is just a straight line or slope of 0.
For more information regarding correlation, please visit our article "Correlation."
Regression
Regressions define the strength between an independent variable (usually denoted as X) and a dependent variable (usually marked as Y). If more than two independent variables are involved, we are dealing with a multiple linear regression model. We measure regression using the coefficient of determination or \( R^2\). The higher the coefficient of determination, the better the model fits our data.
Mean
The mean or the average of a data set is a commonly known mathematical term. We use it to look at a data set's big picture or overall trend. Keep in mind that the mean can be an inaccurate statistical method if the data has a lot of outliers. We calculate it by adding up all the numbers in the data set and then dividing by however many numbers there are in the data set.
Standard deviation
Standard deviation is a statistical method that measures how far our data is spread from the mean. A low standard deviation means that our data is close to the mean and spread out from the mean or norm if our standard deviation is high. Normal distributions have symmetrical data with no skew. Researchers usually use standard deviation when they need to determine if their data points are clustered or not.
Now that we understand the definition of statistical analysis and the types and methods of statistical analysis, it's time to move on to examples or applications of the methods of statistical analysis mentioned above.
Examples of how scientists use the mean in statistical analysis include hypothesis testing or comparison of means
The comparison of means method involves comparing the means of two or more different sets or groups.
If we compare two groups or sets, we can use t-tests, but if you need to compare more than two groups, researchers usually use an ANOVA test. We will only go over the more commonly used t-test.
To use a t-test, we must first assume that our data is:
What type of t-test do scientists use?
After selecting the type of t-test that's needed based on their experiments, researchers usually use statistical software to calculate the t-value. The bigger the absolute t-value, the more likely the sample mean differs from the population mean.
Important values that relate to a t-test are:
The standard deviation and the mean can be used together to tell you where the values in your data set fall or lie if they follow a normal distribution
We call this rule the empirical rule or the 68-95-99.7 rule, which states:
About 68% of scores are within 1 standard deviation (SD) from the mean.
About 95% of scores are within 2 standard deviations (SD) from the mean.
About 99.7% of scores are within 3 standard deviations (SD) from the mean.
Scientists use the empirical rule to make sure that their data set or predicted values are close to the average or mean. If it's not then the likelihood of the prediction, experiment, or theory being right is low.
Researchers use statistical analysis with the purpose of answering essential and often experimental questions in biology. Usually, scientists collect data to answer questions such as "What's the degree of correlation?", "How much?", "How many?" etc. Statistical analysis can provide a method for quantifying collected data and observations.
For example, a pharmaceutical company tells us that most of their patients showed no adverse effects from the drug during all three trials. We'd want to determine what their sample size was. In other words, we want to know what "most" means. Do most mean 120/200 or only 60% of people survive, or 199/200 people survive? We'd also want to know if they were randomly sampled, the mean of the data set, and what they mean by adverse side effects.
Descriptive and inferential are the most common types of statistical analysis used in biological research.
Common methods of statistical analysis in biology include correlation, regression, standard deviation, and the mean.
Researchers use statistical analysis with the purpose of answering essential and often experimental questions in Biology.
Statistical analysis in biology involves collecting, exploring, and interpreting data sets to discover trends and patterns to make conclusions.
We use statistics in biology to test hypotheses, perform experiments, choose sample sizes, and even interpret results.
The five basic methods of statistical analysis are standard deviation, the mean, regression, hypothesis testing, and sample size determining.
An example or application of statistical analysis that researchers use is the t-test to compare the means between two groups either against a standard value, the same population, or different populations.
Researchers use statistical analysis to answer essential and often experimental questions in Biology. Usually, scientists collect data to answer questions such as "What's the degree of correlation?", "How much?", "How many?" etc. Statistical analysis can provide a method for quantifying collected data and observations.
What is statistical analysis?
Statistical analysis involves collecting, exploring, and interpreting data sets to discover trends and patterns to make conclusions.
How are biology and statistics related?
Biostatistics is the field of study where researchers apply statistical analysis to biological topics. For example, we can design biological experiments, from which we can extract and analyze data and finally interpret the results to reach conclusions.
What is descriptive statistical analysis?
Descriptive statistics are statistics that simply describe data.
What are examples of descriptive analysis?
mean
What are examples of inferential analysis?
p-values
What are correlational studies?
Correlational studies or tests measure how closely related two or more variables are. By closely related, we mean linearly or how they change together at a constant rate.
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