Sampling bias explained

In statistics, sampling bias is a bias in which a sample is collected in such a way that some members of the intended population have a lower or higher sampling probability than others. It results in a biased sample[1] of a population (or non-human factors) in which all individuals, or instances, were not equally likely to have been selected.[2] If this is not accounted for, results can be erroneously attributed to the phenomenon under study rather than to the method of sampling.

Medical sources sometimes refer to sampling bias as ascertainment bias.[3] [4] Ascertainment bias has basically the same definition,[5] but is still sometimes classified as a separate type of bias.[6]

Distinction from selection bias

Sampling bias is usually classified as a subtype of selection bias,[7] sometimes specifically termed sample selection bias,[8] [9] [10] but some classify it as a separate type of bias.[11] A distinction, albeit not universally accepted, of sampling bias is that it undermines the external validity of a test (the ability of its results to be generalized to the entire population), while selection bias mainly addresses internal validity for differences or similarities found in the sample at hand. In this sense, errors occurring in the process of gathering the sample or cohort cause sampling bias, while errors in any process thereafter cause selection bias.

However, selection bias and sampling bias are often used synonymously.[12]

Types

Symptom-based sampling

The study of medical conditions begins with anecdotal reports. By their nature, such reports only include those referred for diagnosis and treatment. A child who can't function in school is more likely to be diagnosed with dyslexia than a child who struggles but passes. A child examined for one condition is more likely to be tested for and diagnosed with other conditions, skewing comorbidity statistics. As certain diagnoses become associated with behavior problems or intellectual disability, parents try to prevent their children from being stigmatized with those diagnoses, introducing further bias. Studies carefully selected from whole populations are showing that many conditions are much more common and usually much milder than formerly believed.

Truncate selection in pedigree studies

Geneticists are limited in how they can obtain data from human populations. As an example, consider a human characteristic. We are interested in deciding if the characteristic is inherited as a simple Mendelian trait. Following the laws of Mendelian inheritance, if the parents in a family do not have the characteristic, but carry the allele for it, they are carriers (e.g. a non-expressive heterozygote). In this case their children will each have a 25% chance of showing the characteristic. The problem arises because we can't tell which families have both parents as carriers (heterozygous) unless they have a child who exhibits the characteristic. The description follows the textbook by Sutton.[13]

The figure shows the pedigrees of all the possible families with two children when the parents are carriers (Aa).

The probabilities of each of the families being selected is given in the figure, with the sample frequency of affected children also given. In this simple case, the researcher will look for a frequency of or for the characteristic, depending on the type of truncate selection used.

The caveman effect

An example of selection bias is called the "caveman effect". Much of our understanding of prehistoric peoples comes from caves, such as cave paintings made nearly 40,000 years ago. If there had been contemporary paintings on trees, animal skins or hillsides, they would have been washed away long ago. Similarly, evidence of fire pits, middens, burial sites, etc. are most likely to remain intact to the modern era in caves. Prehistoric people are associated with caves because that is where the data still exists, not necessarily because most of them lived in caves for most of their lives.[14]

Problems due to sampling bias

Sampling bias is problematic because it is possible that a statistic computed of the sample is systematically erroneous. Sampling bias can lead to a systematic over- or under-estimation of the corresponding parameter in the population. Sampling bias occurs in practice as it is practically impossible to ensure perfect randomness in sampling. If the degree of misrepresentation is small, then the sample can be treated as a reasonable approximation to a random sample. Also, if the sample does not differ markedly in the quantity being measured, then a biased sample can still be a reasonable estimate.

The word bias has a strong negative connotation. Indeed, biases sometimes come from deliberate intent to mislead or other scientific fraud. In statistical usage, bias merely represents a mathematical property, no matter if it is deliberate or unconscious or due to imperfections in the instruments used for observation. While some individuals might deliberately use a biased sample to produce misleading results, more often, a biased sample is just a reflection of the difficulty in obtaining a truly representative sample, or ignorance of the bias in their process of measurement or analysis. An example of how ignorance of a bias can exist is in the widespread use of a ratio (a.k.a. fold change) as a measure of difference in biology. Because it is easier to achieve a large ratio with two small numbers with a given difference, and relatively more difficult to achieve a large ratio with two large numbers with a larger difference, large significant differences may be missed when comparing relatively large numeric measurements. Some have called this a 'demarcation bias' because the use of a ratio (division) instead of a difference (subtraction) removes the results of the analysis from science into pseudoscience (See Demarcation Problem).

Some samples use a biased statistical design which nevertheless allows the estimation of parameters. The U.S. National Center for Health Statistics, for example, deliberately oversamples from minority populations in many of its nationwide surveys in order to gain sufficient precision for estimates within these groups.[15] These surveys require the use of sample weights (see later on) to produce proper estimates across all ethnic groups. Provided that certain conditions are met (chiefly that the weights are calculated and used correctly) these samples permit accurate estimation of population parameters.

Historical examples

A classic example of a biased sample and the misleading results it produced occurred in 1936. In the early days of opinion polling, the American Literary Digest magazine collected over two million postal surveys and predicted that the Republican candidate in the U.S. presidential election, Alf Landon, would beat the incumbent president, Franklin Roosevelt, by a large margin. The result was the exact opposite. The Literary Digest survey represented a sample collected from readers of the magazine, supplemented by records of registered automobile owners and telephone users. This sample included an over-representation of wealthy individuals, who, as a group, were more likely to vote for the Republican candidate. In contrast, a poll of only 50 thousand citizens selected by George Gallup's organization successfully predicted the result, leading to the popularity of the Gallup poll.

Another classic example occurred in the 1948 presidential election. On election night, the Chicago Tribune printed the headline DEWEY DEFEATS TRUMAN, which turned out to be mistaken. In the morning the grinning president-elect, Harry S. Truman, was photographed holding a newspaper bearing this headline. The reason the Tribune was mistaken is that their editor trusted the results of a phone survey. Survey research was then in its infancy, and few academics realized that a sample of telephone users was not representative of the general population. Telephones were not yet widespread, and those who had them tended to be prosperous and have stable addresses. (In many cities, the Bell System telephone directory contained the same names as the Social Register). In addition, the Gallup poll that the Tribune based its headline on was over two weeks old at the time of the printing.[16]

In air quality data, pollutants (such as carbon monoxide, nitrogen monoxide, nitrogen dioxide, or ozone) frequently show high correlations, as they stem from the same chemical process(es). These correlations depend on space (i.e., location) and time (i.e., period). Therefore, a pollutant distribution is not necessarily representative for every location and every period. If a low-cost measurement instrument is calibrated with field data in a multivariate manner, more precisely by collocation next to a reference instrument, the relationships between the different compounds are incorporated into the calibration model. By relocation of the measurement instrument, erroneous results can be produced.[17]

A twenty-first century example is the COVID-19 pandemic, where variations in sampling bias in COVID-19 testing have been shown to account for wide variations in both case fatality rates and the age distribution of cases across countries.[18] [19]

Statistical corrections for a biased sample

If entire segments of the population are excluded from a sample, then there are no adjustments that can produce estimates that are representative of the entire population. But if some groups are underrepresented and the degree of underrepresentation can be quantified, then sample weights can correct the bias. However, the success of the correction is limited to the selection model chosen. If certain variables are missing the methods used to correct the bias could be inaccurate.[20]

For example, a hypothetical population might include 10 million men and 10 million women. Suppose that a biased sample of 100 patients included 20 men and 80 women. A researcher could correct for this imbalance by attaching a weight of 2.5 for each male and 0.625 for each female. This would adjust any estimates to achieve the same expected value as a sample that included exactly 50 men and 50 women, unless men and women differed in their likelihood of taking part in the survey.

See also

Notes and References

  1. Web site: Sampling Bias . Medical Dictionary . 23 September 2009 . https://web.archive.org/web/20160310100307/http://www.medilexicon.com/medicaldictionary.php?t=10087 . 10 March 2016 .
  2. Web site: Biased sample . TheFreeDictionary . 23 September 2009 . Mosby's Medical Dictionary, 8th edition .
  3. Book: Weising K . DNA fingerprinting in plants: principles, methods, and applications . Taylor & Francis Group . London . 2005 . 180 . 978-0-8493-1488-9 .
  4. Ramírez i Soriano A . Ph.D. . Selection and linkage desequilibrium tests under complex demographies and ascertainment bias. . Universitat Pompeu Fabra . 29 November 2008 . 34 .
  5. Web site: Ascertainment Bias . Medilexicon Medical Dictionary . https://web.archive.org/web/20160806100330/http://www.medilexicon.com/medicaldictionary.php?t=10080 . 6 August 2016 . 14 November 2009 .
  6. Web site: Panacek EA . May 2009 . Error and Bias in Clinical Research . https://web.archive.org/web/20160817191133/http://elearning.saem.org/sites/default/files/issuu/libraries/Panacek_Error_And_Bias_In_Clinical_Research_syllabus_1.pdf . 17 August 2016 . SAEM Annual Meeting . New Orleans, LA . . 14 November 2009 .
  7. Web site: Selection Bias . Dictionary of Cancer Terms . https://web.archive.org/web/20090609002707/http://medical.webends.com/kw/Selection%20Bias . 9 June 2009 . 23 September 2009 .
  8. Ards S, Chung C, Myers SL . The effects of sample selection bias on racial differences in child abuse reporting . Child Abuse & Neglect . 22 . 2 . 103–15 . February 1998 . 9504213 . 10.1016/S0145-2134(97)00131-2 . free .
  9. Cortes C, Mohri M, Riley M, Rostamizadeh A . Sample Selection Bias Correction Theory. Algorithmic Learning Theory. 5254. 2008. 38–53. 10.1007/978-3-540-87987-9_8. 0805.2775. Lecture Notes in Computer Science. 978-3-540-87986-2. 10.1.1.144.4478. 842488.
  10. Cortes C, Mohri M . Domain adaptation and sample bias correction theory and algorithm for regression. Theoretical Computer Science. 519. 2014. 103–126 . 10.1016/j.tcs.2013.09.027. 10.1.1.367.6899.
  11. Book: Fadem B . Behavioral Science. 2009. Lippincott Williams & Wilkins. 978-0-7817-8257-9. 262.
  12. Book: Wallace R . Maxcy-Rosenau-Last Public Health and Preventive Medicine. 15th. 2007. McGraw Hill Professional. 978-0-07-159318-2. 21.
  13. Book: Sutton HE . An Introduction to Human Genetics. 4th. 1988. Harcourt Brace Jovanovich. 978-0-15-540099-3.
  14. Berk RA . An Introduction to Sample Selection Bias in Sociological Data . American Sociological Review . June 1983 . 48 . 3 . 386–398 . 10.2307/2095230. 2095230 .
  15. Web site: Minority Health . National Center for Health Statistics . 2007 .
  16. Web site: Lienhard JH . Gallup Poll . 29 September 2007 . The Engines of Our Ingenuity .
  17. Tancev G, Pascale C . The Relocation Problem of Field Calibrated Low-Cost Sensor Systems in Air Quality Monitoring: A Sampling Bias . Sensors . 20 . 21 . 6198 . October 2020 . 33143233 . 7662848 . 10.3390/s20216198 . 2020Senso..20.6198T . free .
  18. Ward D . Sampling Bias: Explaining Wide Variations in COVID-19 Case Fatality Rates. . 20 April 2020. Preprint . Bern, Switzerland . 10.13140/RG.2.2.24953.62564/1 .
  19. Böttcher L, D'Orsogna MR, Chou T . Using excess deaths and testing statistics to determine COVID-19 mortalities. . European Journal of Epidemiology . 36 . 545–558 . May 2021 . 5 . 10.1007/s10654-021-00748-2 . free . 8127858 .
  20. Cuddeback G, Wilson E, Orme JG, Combs-Orme T . 2004. Detecting and Statistically Correcting Sample Selection Bias. Journal of Social Service Research. 30. 3. 19–33. 10.1300/J079v30n03_02. 11685550.