The essential role of basic science in medical education: the perspective from psychology
Two lines of inquiry have examined how clinicians use basic science by asking them to think aloud as they read a clinical case.(f.2,3) Both studies concluded that clinicians rarely used basic science in developing an explanation. It should be noted that these conclusions were based on a very limited...
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| description | Two lines of inquiry have examined how clinicians use basic science by asking them to think aloud as they read a clinical case.(f.2,3) Both studies concluded that clinicians rarely used basic science in developing an explanation. It should be noted that these conclusions were based on a very limited number of cases, and the clinician's goal was always diagnosis, not management. Still, it is likely that most practitioners most of the time need not invoke basic science explanations to understand a patient's problem. However, in relatively rare circumstances when things do not fit together, the clinician might go back to basic principles to reason it out. There is some evidence to support this hypothesis. [Patel VL] and associates(f.4) found that specialists operating outside their specialty (where presumably the solution was less likely to be forth-coming) were more likely to invoke basic science. Another study(f.5) suggested that specialists may use basic science concepts when working within their own specialty. In this study, nephrologists, second-year medicine residents and first-year family medicine residents were confronted with a series of 8 very difficult nephrology problems on paper and asked to "think aloud" as they reasoned their way through the problem. Diagnostic accuracy of the first-year residents was about 20%, of the second-year residents, it was about 50% and of the nephrologists, about 90%. More striking was that the process was very different in the 3 cohorts. The first-year residents seemed to have real difficulty generating hypotheses -- they had few diagnoses and ordered few tests. Second-year residents had the most hypotheses and ordered the most tests but were unable to reach a conclusion. Nephrologists knew what they were dealing with and ordered relatively few, targetted additional tests. More striking was that, whereas the first-year residents rarely thought about basic mechanisms, this was the modus operandi of the specialists. Returning to the main theme, I wish to review evidence from psychology that understanding contributes to learning. In brief, the perspective of psychology is that "people construct new knowledge and understanding based on what they already know and believe."(f.7) In a number of studies, [Brophy S Bransford JD] and colleagues(f.8) examined the effect of learning for understanding versus learning to remember. In one classic study, they showed 2 groups of students some text about learning to fly a kite. The te |
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It should be noted that these conclusions were based on a very limited number of cases, and the clinician's goal was always diagnosis, not management. Still, it is likely that most practitioners most of the time need not invoke basic science explanations to understand a patient's problem. However, in relatively rare circumstances when things do not fit together, the clinician might go back to basic principles to reason it out. There is some evidence to support this hypothesis. [Patel VL] and associates(f.4) found that specialists operating outside their specialty (where presumably the solution was less likely to be forth-coming) were more likely to invoke basic science. Another study(f.5) suggested that specialists may use basic science concepts when working within their own specialty. In this study, nephrologists, second-year medicine residents and first-year family medicine residents were confronted with a series of 8 very difficult nephrology problems on paper and asked to "think aloud" as they reasoned their way through the problem. Diagnostic accuracy of the first-year residents was about 20%, of the second-year residents, it was about 50% and of the nephrologists, about 90%. More striking was that the process was very different in the 3 cohorts. The first-year residents seemed to have real difficulty generating hypotheses -- they had few diagnoses and ordered few tests. Second-year residents had the most hypotheses and ordered the most tests but were unable to reach a conclusion. Nephrologists knew what they were dealing with and ordered relatively few, targetted additional tests. More striking was that, whereas the first-year residents rarely thought about basic mechanisms, this was the modus operandi of the specialists. Returning to the main theme, I wish to review evidence from psychology that understanding contributes to learning. In brief, the perspective of psychology is that "people construct new knowledge and understanding based on what they already know and believe."(f.7) In a number of studies, [Brophy S Bransford JD] and colleagues(f.8) examined the effect of learning for understanding versus learning to remember. In one classic study, they showed 2 groups of students some text about learning to fly a kite. The text had sentences like "It works well on beaches..." One group had as the title of the paragraph, "flying a kite," the other group did not. Not surprisingly, the first group was much better at recalling the specific information in the text. Thus, learning was enhanced by the meaning and understanding derived from the title. A more recent study more closely mimics the typical instructional situation.(f.9) In this study, there were 3 groups who were all directed to learn a concept in psychology called "schema theory." The first group read and summarized a text, then heard a lecture on the subject. (Read the text in advance? What ideal students!) The second group explored the concept using simplified data sets then heard the same lecture, The last group spent twice as much time as the second with the data sets, but never heard the lecture. Performance on a test was about 20% for groups 1 and 3, but 45 % for group 2. Thus, active manipulation, combined with an organizing concept (from the lecture) was essential for optimal learning. Another factor that may influence transfer is the goal of initial learning. Problems are often used to illustrate a concept, for example, by presenting the problem and solution sequentially as part of instruction and instructing students to remember and review the problem so they can understand how the concept explains the problem. Needham and Begg(f.12) contrasted this approach with a second, in which students were shown the problem and encouraged to arrive at their own solution (usually unsuccessfully), then provided with the solution. The first group, who were shown the problem and solution together, achieved about 60% transfer to a second problem. The group who actively attempted to solve the problem achieved about 90% transfer. Paradoxically, on a memory test, the first group remembered more of the initial problem. Although this study can appropriately be viewed as evidence for the advantage of active learning in facilitating transfer, the question really becomes what activities were being engaged. Presumably in the course of trying to solve the problem, subjects are led to discover the deep structure of the problem and then to create a more abstract representation. This strategy has also been shown to facilitate transfer.(F.13)</description><identifier>ISSN: 0147-958X</identifier><identifier>PMID: 10782317</identifier><identifier>CODEN: CNVMDL</identifier><language>eng</language><publisher>Canada: Canadian Society for Clinical Investigation</publisher><subject>Awareness ; Canada ; Conferences ; Education ; Education, Medical - trends ; Learning ; Medical education ; Psychology ; Science - education ; University level</subject><ispartof>Clinical and investigative medicine, 2000-02, Vol.23 (1), p.47-51; discussion 52-4</ispartof><rights>Copyright Canadian Medical Association Feb 2000</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,776,780</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/10782317$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Norman, G</creatorcontrib><title>The essential role of basic science in medical education: the perspective from psychology</title><title>Clinical and investigative medicine</title><addtitle>Clin Invest Med</addtitle><description>Two lines of inquiry have examined how clinicians use basic science by asking them to think aloud as they read a clinical case.(f.2,3) Both studies concluded that clinicians rarely used basic science in developing an explanation. It should be noted that these conclusions were based on a very limited number of cases, and the clinician's goal was always diagnosis, not management. Still, it is likely that most practitioners most of the time need not invoke basic science explanations to understand a patient's problem. However, in relatively rare circumstances when things do not fit together, the clinician might go back to basic principles to reason it out. There is some evidence to support this hypothesis. [Patel VL] and associates(f.4) found that specialists operating outside their specialty (where presumably the solution was less likely to be forth-coming) were more likely to invoke basic science. Another study(f.5) suggested that specialists may use basic science concepts when working within their own specialty. In this study, nephrologists, second-year medicine residents and first-year family medicine residents were confronted with a series of 8 very difficult nephrology problems on paper and asked to "think aloud" as they reasoned their way through the problem. Diagnostic accuracy of the first-year residents was about 20%, of the second-year residents, it was about 50% and of the nephrologists, about 90%. More striking was that the process was very different in the 3 cohorts. The first-year residents seemed to have real difficulty generating hypotheses -- they had few diagnoses and ordered few tests. Second-year residents had the most hypotheses and ordered the most tests but were unable to reach a conclusion. Nephrologists knew what they were dealing with and ordered relatively few, targetted additional tests. More striking was that, whereas the first-year residents rarely thought about basic mechanisms, this was the modus operandi of the specialists. Returning to the main theme, I wish to review evidence from psychology that understanding contributes to learning. In brief, the perspective of psychology is that "people construct new knowledge and understanding based on what they already know and believe."(f.7) In a number of studies, [Brophy S Bransford JD] and colleagues(f.8) examined the effect of learning for understanding versus learning to remember. In one classic study, they showed 2 groups of students some text about learning to fly a kite. The text had sentences like "It works well on beaches..." One group had as the title of the paragraph, "flying a kite," the other group did not. Not surprisingly, the first group was much better at recalling the specific information in the text. Thus, learning was enhanced by the meaning and understanding derived from the title. A more recent study more closely mimics the typical instructional situation.(f.9) In this study, there were 3 groups who were all directed to learn a concept in psychology called "schema theory." The first group read and summarized a text, then heard a lecture on the subject. (Read the text in advance? What ideal students!) The second group explored the concept using simplified data sets then heard the same lecture, The last group spent twice as much time as the second with the data sets, but never heard the lecture. Performance on a test was about 20% for groups 1 and 3, but 45 % for group 2. Thus, active manipulation, combined with an organizing concept (from the lecture) was essential for optimal learning. Another factor that may influence transfer is the goal of initial learning. Problems are often used to illustrate a concept, for example, by presenting the problem and solution sequentially as part of instruction and instructing students to remember and review the problem so they can understand how the concept explains the problem. Needham and Begg(f.12) contrasted this approach with a second, in which students were shown the problem and encouraged to arrive at their own solution (usually unsuccessfully), then provided with the solution. The first group, who were shown the problem and solution together, achieved about 60% transfer to a second problem. The group who actively attempted to solve the problem achieved about 90% transfer. Paradoxically, on a memory test, the first group remembered more of the initial problem. Although this study can appropriately be viewed as evidence for the advantage of active learning in facilitating transfer, the question really becomes what activities were being engaged. Presumably in the course of trying to solve the problem, subjects are led to discover the deep structure of the problem and then to create a more abstract representation. This strategy has also been shown to facilitate transfer.(F.13)</description><subject>Awareness</subject><subject>Canada</subject><subject>Conferences</subject><subject>Education</subject><subject>Education, Medical - trends</subject><subject>Learning</subject><subject>Medical education</subject><subject>Psychology</subject><subject>Science - education</subject><subject>University level</subject><issn>0147-958X</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2000</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><sourceid>BENPR</sourceid><recordid>eNpd0D1PwzAQBmAPIFoKfwFZDGyR_BXHZkMVX1IlliLBFDn2hbpK4mA7SP33BFEWpluee_XenaAloaIqdKneFug8pT0hhJVSn6EFJZVinFZL9L7dAYaUYMjedDiGDnBocWOStzhZD4MF7Afcg_N2BuAma7IPwy3O8-YIMY1gs_8C3MbQ4zEd7C504eNwgU5b0yW4PM4Ven24366fis3L4_P6blOMjItcuJYYQSqrpDAlEZqWWjHWyLYB5UBoRRjYxhnQbK7PBNfUNaQkznDpjJN8hW5-c8cYPidIue59stB1ZoAwpbqiREpFyxle_4P7MMVh7lZTLQWjQv-gqyOamvnmeoy-N_FQ_32MfwOuD2Z6</recordid><startdate>20000201</startdate><enddate>20000201</enddate><creator>Norman, G</creator><general>Canadian Society for Clinical Investigation</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>3V.</scope><scope>7RV</scope><scope>7X7</scope><scope>7XB</scope><scope>88E</scope><scope>88I</scope><scope>8AF</scope><scope>8AO</scope><scope>8FI</scope><scope>8FJ</scope><scope>8FK</scope><scope>8FQ</scope><scope>8FV</scope><scope>ABUWG</scope><scope>AFKRA</scope><scope>AZQEC</scope><scope>BENPR</scope><scope>CCPQU</scope><scope>DWQXO</scope><scope>FYUFA</scope><scope>GHDGH</scope><scope>GNUQQ</scope><scope>HCIFZ</scope><scope>K9-</scope><scope>K9.</scope><scope>M0R</scope><scope>M0S</scope><scope>M1P</scope><scope>M2P</scope><scope>M3G</scope><scope>NAPCQ</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>PRINS</scope><scope>Q9U</scope><scope>7X8</scope></search><sort><creationdate>20000201</creationdate><title>The essential role of basic science in medical education: the perspective from psychology</title><author>Norman, G</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-p234t-df0a407c864a5049159822b6fbe8de49802ecbdae9200224391db050da36dad63</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2000</creationdate><topic>Awareness</topic><topic>Canada</topic><topic>Conferences</topic><topic>Education</topic><topic>Education, Medical - 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Academic</collection><jtitle>Clinical and investigative medicine</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Norman, G</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>The essential role of basic science in medical education: the perspective from psychology</atitle><jtitle>Clinical and investigative medicine</jtitle><addtitle>Clin Invest Med</addtitle><date>2000-02-01</date><risdate>2000</risdate><volume>23</volume><issue>1</issue><spage>47</spage><epage>51; discussion 52-4</epage><pages>47-51; discussion 52-4</pages><issn>0147-958X</issn><coden>CNVMDL</coden><abstract>Two lines of inquiry have examined how clinicians use basic science by asking them to think aloud as they read a clinical case.(f.2,3) Both studies concluded that clinicians rarely used basic science in developing an explanation. It should be noted that these conclusions were based on a very limited number of cases, and the clinician's goal was always diagnosis, not management. Still, it is likely that most practitioners most of the time need not invoke basic science explanations to understand a patient's problem. However, in relatively rare circumstances when things do not fit together, the clinician might go back to basic principles to reason it out. There is some evidence to support this hypothesis. [Patel VL] and associates(f.4) found that specialists operating outside their specialty (where presumably the solution was less likely to be forth-coming) were more likely to invoke basic science. Another study(f.5) suggested that specialists may use basic science concepts when working within their own specialty. In this study, nephrologists, second-year medicine residents and first-year family medicine residents were confronted with a series of 8 very difficult nephrology problems on paper and asked to "think aloud" as they reasoned their way through the problem. Diagnostic accuracy of the first-year residents was about 20%, of the second-year residents, it was about 50% and of the nephrologists, about 90%. More striking was that the process was very different in the 3 cohorts. The first-year residents seemed to have real difficulty generating hypotheses -- they had few diagnoses and ordered few tests. Second-year residents had the most hypotheses and ordered the most tests but were unable to reach a conclusion. Nephrologists knew what they were dealing with and ordered relatively few, targetted additional tests. More striking was that, whereas the first-year residents rarely thought about basic mechanisms, this was the modus operandi of the specialists. Returning to the main theme, I wish to review evidence from psychology that understanding contributes to learning. In brief, the perspective of psychology is that "people construct new knowledge and understanding based on what they already know and believe."(f.7) In a number of studies, [Brophy S Bransford JD] and colleagues(f.8) examined the effect of learning for understanding versus learning to remember. In one classic study, they showed 2 groups of students some text about learning to fly a kite. The text had sentences like "It works well on beaches..." One group had as the title of the paragraph, "flying a kite," the other group did not. Not surprisingly, the first group was much better at recalling the specific information in the text. Thus, learning was enhanced by the meaning and understanding derived from the title. A more recent study more closely mimics the typical instructional situation.(f.9) In this study, there were 3 groups who were all directed to learn a concept in psychology called "schema theory." The first group read and summarized a text, then heard a lecture on the subject. (Read the text in advance? What ideal students!) The second group explored the concept using simplified data sets then heard the same lecture, The last group spent twice as much time as the second with the data sets, but never heard the lecture. Performance on a test was about 20% for groups 1 and 3, but 45 % for group 2. Thus, active manipulation, combined with an organizing concept (from the lecture) was essential for optimal learning. Another factor that may influence transfer is the goal of initial learning. Problems are often used to illustrate a concept, for example, by presenting the problem and solution sequentially as part of instruction and instructing students to remember and review the problem so they can understand how the concept explains the problem. Needham and Begg(f.12) contrasted this approach with a second, in which students were shown the problem and encouraged to arrive at their own solution (usually unsuccessfully), then provided with the solution. The first group, who were shown the problem and solution together, achieved about 60% transfer to a second problem. The group who actively attempted to solve the problem achieved about 90% transfer. Paradoxically, on a memory test, the first group remembered more of the initial problem. Although this study can appropriately be viewed as evidence for the advantage of active learning in facilitating transfer, the question really becomes what activities were being engaged. Presumably in the course of trying to solve the problem, subjects are led to discover the deep structure of the problem and then to create a more abstract representation. This strategy has also been shown to facilitate transfer.(F.13)</abstract><cop>Canada</cop><pub>Canadian Society for Clinical Investigation</pub><pmid>10782317</pmid></addata></record> |
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| title | The essential role of basic science in medical education: the perspective from psychology |
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