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Men versus Women in Sports Media Coverage and Popularity

Men versus Women in Sports Media Coverage and Popularity

Prepare and submit a term paper on Men versus Women in Sports Media Coverage and Popularity. Your paper should be a minimum of 1500 words in length

https://eazyweezyhomeworks.com/distinguish-between-evolutionary-psychology-and-sociobiology/

At the Vancouver Olympics for example men received almost whole day prime-time coverage. This was about 13 hours higher in comparison to women’s coverage (Brown 102). Men in most cases tend to perform extremely well in various games. This boosts the reporter’s morale towards covering most of the men’s games. In the summer Olympics in 2008 as well as the preceding years, there emerged improved airtime coverage with both men and women almost getting equal airtime coverage. About 46.3% of airtime coverage went to women this year, a decrease from the previous year 2004 when the coverage was 47.9% (Beck 46). Nevertheless, coverage of women’s sports events improved heavily towards socially acceptable sports for women. The socially accepted sports such as gymnastics are always attractive as these sports involve minimal clothing hence women can be easily displayed as physically attractive. These kinds of sports, even though are highly ranked in the media coverage among the women are not morally acceptable in the media fraternity. This case study explains the impact of media coverage in comparison to men’s and women’s sports coverage and popularity.

Women who normally take part in sports that involve either power or hard body contact are more often unlikely to receive media coverage. This is due to the stereotypical assumptions involved with these kinds of feminine events thus. there are reduced women sports coverage (Chua45). The women’s court volleyball competition received absolutely no coverage in the year 2004 despite the American team’s captivating performance and securing the silver medal. This was almost equally divided between both the men and women volleyball sports coverage this year. The emphasis of the women’s sports coverage exhibited a high emphasis on the women’s attractiveness and gendered qualities that may be provided for a much more efficient male-centric coverage. The 2010 Olympics aptly inclined towards men coverage thus rendering it biased (Lewis 78). Most of the winter sports by their nature generally provide women with fewer opportunities to capture various sports. The make-up of the spectators whom NBC normally targets to please provides a more complex narrative than mere pandering to male sports fans for the summer Olympics in 2008.

Assignment 2-Sample

create a thesis and an outline on The Sub-Cultures of the Star Trek Fans. Prepare this assignment according to the guidelines found in the APA Style Guide. An abstract is required.

The studies have equally examined the methods in which fans interact with the text. In anthropological studies, comparisons have been made between Star Trek fan body and religious Movements (Jindra, 1994). On another account, cultural studies have made comparisons of fan organizations and cults (Hills, 200). This article seeks to examine and give a comprehensive report on the ordinary Star Trek fans.

The original Star Trek was the creation of Gene Roddenberry (1921-1991), a United States Television producer and author. His idea was to develop a Television series involving the futuristic prospects of science fiction with the stage show and enthusiasm of TV westerns his original heading for the television series was the Wagon Train to the Stars. Star Trek was initially aired on American Television in 1966 and continued for three series. Each chapter was in itself an adventure, but then they were all connected together by the premise of a huge spacecraft that was crewed by a various range of individuals, traveling around the galaxy on a mission that took five years to explore different life and new evolutions, to confidently visit a place where no human being has gone in the past. Even though, not expressly successful it attracted a devoted fan-base that was partially made up of male fans that were interested in the scientific and exceptional effects essentials of the show. On the other hand, the show also enticed many female fans.

Over the past three decades, Star Trek has been using the term mega-text. Star Treks mega-text involves much more than the innumerable studio-based television series and films. it also consists of novels, Internet chat groups, treaties, and fanzines among others. That Star Treks idea of space examination is a lightly hidden metaphor for imperialism has extensively undergone analysis (Bernardi, 1998). Exploration, occupation, and incorporation are not far from the surface of the Star Trek New Generation text. Less ostensible, nonetheless, are features of the series that challenge the hegemonic understanding of this story and which current a post-colonial appraisal.

Nurse client relationships

Discussion Question: Nurse client relationships

Margaret Newman stated, the nurse and client become partners in living through the period of disharmony and emerging at a higher level of consciousness, the nurse client relationships often begin during periods of disruption, uncertainty, and unpredictability in patient’s lives.  Explore what she means by this statement. Then, reflect on a patient that you cared for that you could apply her theory to. Provide details of the interaction and outcomes.

https://eazyweezyhomeworks.com/create-a-5-pages-page-paper-that-discusses-transcript-of-therapy-session/

Your initial posting should be at least 400 words in length and utilize at least one scholarly source other than the textbook.

Assignment:

Leininger and Watson

Write a 1500-1750 word APA paper addressing each of the following points. Be sure to completely answer all the questions for each bullet point. Separate each section in your paper with a clear heading that allows your professor to know which bullet you are addressing in that section of your paper. Support your ideas with at least two (2) sources and the textbook using citations in your essay. Make sure to cite using the APA writing style for the essay. The cover page and reference page in correct APA do not count towards the minimum word amount. Review the rubric criteria for this assignment.

Case study #1

Mrs. Franklin-Jones was admitted from the Emergency Room to Cardiac Intensive Care one week ago with a diagnosis of acute myocardial infarction. She has recovered as expected and is moving to the cardiac step down unit today. She is talking with Nurse Julie Hernandez, as she gets settled in her new room, “I was really surprised when I got that bad pain in my chest! I knew I had high pressure but I just didn’t think it was that bad. I try to take my medicine like they told me to in the clinic but sometimes I forget. I guess that I need to study those papers they gave me about what foods I should eat and not eat. I better take care of myself! Momma had bad pressure and it killed her! Who knows—I may even have to learn to cook different than I was taught in Jamaica! I may have to let Tomas do the cooking. He’s got more time at home now than I do since he lost his job. There isn’t too much time between my shifts at the school cafeteria and my new housecleaning job. You know my sister is coming up from Jamaica to see me. I think she is bringing me some bush tea. That’ll set me right!”

  • Using Leininger’s Culture Care Model, what factors in the story shared by Mrs. Franklin-Jones should be considered by Nurse Hernandez when planning for the patient’s discharge?
  • Why is the theory of Culture Care Diversity important in the delivery of nursing care for all patients?
  • Using Leininger’s Theory of Culture Care Diversity and Universality, develop a plan of care for Mrs. Franklin-Jones.
  • Discuss the strengths and limits to Leininger’s Theory.

Case Study #2

Claude Jean-Baptiste is recovering from post-hip replacement surgery and has been transferred to the Rehabilitation Institute adjacent to the hospital. When he enters the unit, he sees welcoming signs written in several languages including his own, Creole. Since there are no nurses on that shift that speak Creole, they use a language line to ask for translation services. During this initial nursing assessment, the translator informs Mr. Jean-Baptiste that the nurses invite him to have a relative at his side so that they can be sure to understand and meet his needs. He is asked about Haitian customs and beliefs that they might honor. Mr. Jean-Baptiste is encouraged to bring food and spiritual care items, and to share the warmth of his culture with the nursing staff.

  • Discuss assumptions of the Transpersonal Caring relationship. What is the nurse’s role?
  • How is love, as defined by Watson, evident in this caring moment?
  • How can the nurse creatively use self to create a healing environment?
  • Discuss the strengths and limits to Watson’s Theory.

Assignment Expectations:

Length: 1500 – 1750 words

Structure: Include a title page and reference page in APA format.  These do not count towards the minimum word count for this assignment. Your essay must include an introduction and a conclusion.

References: Use appropriate APA style in-text citations and references for all resources utilized to answer the questions. A minimum of two (2) outside scholarly sources and the textbook are required for this assignment.

Rubric: This assignment uses a rubric for scoring. Please review it as part of your assignment preparation and again prior to submission to ensure you have addressed its criteria at the highest level.

Assignment sample 2

Write 5 pages thesis on the topic oklahoma city bombing

The magnitude of the blast can be estimated by the number of explosives in the van which was approximately 4800 pounds of destructive chemicals and a number of 168 people lost their lives, while thousands of other people were injured or moaning over their losses (Sherrow 6). Out of the 168 souls lost, 19 of them were children (The Federal Bureau of Investigation). Oklahoma City bombing was the most intense and serious case of domestic terrorism and demanded a thorough investigation and reporting regarding the reasons and factors which led to the upsetting incident.

According to reports, the bombing was planned by an ex-Army soldier and security guard, Timothy McVeigh. On the morning of the bombing, he loaded his truck with explosives made from a combination of hazardous and destructive chemicals. He then drove his car to the federal building where he parked the car in front of the building with a clear intention to commit mass murder. He then left the spot in another car. At 9.02 am the bomb exploded, according to the planned time set by McVeigh. Within moments of the bomb explosion, most of the federal building was brought down into the gravel and the shock wave from the blast was so intense that more than 300 buildings nearby were also damaged or destroyed (The Federal Bureau of Investigation). According to scientists, as the bomb exploded, super hot gas went upward through the building at a gigantic speed of 8,000 feet per second. The force was so intense that people were slammed against the walls with a force of 37 tons. And when the gas evaporated, a vacuum was created which shook the ground as if there was a “full-scale earthquake” (Sherrow 6-7). Thus, the explosion was of massive intensity which not only affected the federal building but also the buildings located in its close vicinity.

In view of the World Trade Centre bombing two years back, the instant suspicion of the federal government was on the Middle Eastern terrorists

Understanding Simple Linear Regression

Exercise 14
Understanding Simple Linear Regression
Statistical Technique in Review
In nursing practice, the ability to predict future events or outcomes is crucial, and researchers calculate and report linear regression results as a basis for making these predictions. Linear regression provides a means to estimate or predict the value of a dependent variable based on the value of one or more independent variables. The regression equation is a mathematical expression of a causal proposition emerging from a theoretical framework. The linkage between the theoretical statement and the equation is made prior to data collection and analysis. Linear regression is a statistical method of estimating the expected value of one variable, y, given the value of another variable, x. The focus of this exercise is simple linear regression, which involves the use of one independent variable, x, to predict one dependent variable, y.

The regression line developed from simple linear regression is usually plotted on a graph, with the horizontal axis representing x (the independent or predictor variable) and the vertical axis representing the y (the dependent or predicted variable; see Figure 14-1). The value represented by the letter a is referred to as the y intercept, or the point where the regression line crosses or intercepts the y-axis. At this point on the regression line, x = 0. The value represented by the letter b is referred to as the slope, or the coefficient of x. The slope determines the direction and angle of the regression line within the graph. The slope expresses the extent to which y changes for every one-unit change in x. The score on variable y (dependent variable) is predicted from the subject’s known score on variable x (independent variable). The predicted score or estimate is referred to as Ŷ (expressed as y-hat) (Cohen, 1988; Grove, Burns, & Gray, 2013; Zar, 2010).

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FIGURE 14-1 GRAPH OF A SIMPLE LINEAR REGRESSION LINE
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Simple linear regression is an effort to explain the dynamics within a scatterplot (see Exercise 11) by drawing a straight line through the plotted scores. No single regression line can be used to predict, with complete accuracy, every y value from every x value. However, the purpose of the regression equation is to develop the line to allow the highest degree of prediction possible, the line of best fit. The procedure for developing the line of best fit is the method of least squares. If the data were perfectly correlated, all data points would fall along the straight line or line of best fit. However, not all data points fall on the line of best fit in studies, but the line of best fit provides the best equation for the values of y to be predicted by locating the intersection of points on the line for any given value of x.

The algebraic equation for the regression line of best fit is y = bx + a, where:

y=dependentvariable(outcome)

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x=independentvariable(predictor)

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b=slopeoftheline(beta,orwhattheincreaseinvalueisalongthex-axisforeveryunitofincreaseintheyvalue),alsocalledtheregressioncoefficient.

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a=y−intercept(thepointwheretheregressionlineintersectsthe y-axis),alsocalledtheregressionconstant(Zar,2010).

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In Figure 14-2, the x-axis represents Gestational Age in weeks and the y-axis represents Birth Weight in grams. As gestational age increases from 20 weeks to 34 weeks, birth weight also increases. In other words, the slope of the line is positive. This line of best fit can be used to predict the birth weight (dependent variable) for an infant based on his or her gestational age in weeks (independent variable). Figure 14-2 is an example of a line of best fit that was not developed from research data. In addition, the x-axis was started at 22 weeks rather than 0, which is the usual start in a regression figure. Using the formula y = bx + a, the birth weight of a baby born at 28 weeks of gestation is calculated below.

Formula:y=bx+a

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Inthisexample,a=500,b=20,andx=28weeks

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y=20(28)+500=560+500=1,060grams

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FIGURE 14-2 EXAMPLE LINE OF BEST FIT FOR GESTATIONAL AGE AND BIRTH WEIGHT
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The regression line represents y for any given value of x. As you can see, some data points fall above the line, and some fall below the line. If we substitute any x value in the regression equation and solve for y, we will obtain a ŷ that will be somewhat different from the actual values. The distance between the ŷ and the actual value of y is called residual, and this represents the degree of error in the regression line. The regression line or the line of best fit for the data points is the unique line that will minimize error and yield the smallest residual (Zar, 2010). The step-by-step process for calculating simple linear regression in a study is presented in Exercise 29.

Research Article
Source
Flannigan, C., Bourke, T. W., Sproule, A., Stevenson, M., & Terris, M. (2014). Are APLS formulae for estimating weight appropriate for use in children admitted to PICU? Resuscitation, 85(7), 927–931.

Introduction
Medications and other therapies often necessitate knowing a patient’s weight. However, a child may be admitted to a pediatric intensive care unit (PICU) without a known weight, and instability and on-going resuscitation may prevent obtaining this needed weight. Clinicians would benefit from a tool that could accurately estimate a patient’s weight when such information is unavailable. Thus Flannigan et al. (2014) conducted a retrospective observational study for the purpose of determining “if the revised APLS UK [Advanced Paediatric Life Support United Kingdom] formulae for estimating weight are appropriate for use in the paediatric care population in the United Kingdom” (Flannigan et al., 2014, p. 927). The sample included 10,081 children (5,622 males and 4,459 females), who ranged from term-corrected age to 15 years of age, admitted to the PICU during a 5-year period. Because this was a retrospective study, no geographic location, race, and ethnicity data were collected for the sample. A paired samples t-test was used to compare mean sample weights with the APLS UK formula weight. The “APLS UK formula ‘weight = (0.05 × age in months) + 4’ significantly overestimates the mean weight of children under 1 year admitted to PICU by between 10% [and] 25.4%” (Flannigan et al., 2014, p. 928). Therefore, the researchers concluded that the APLS UK formulas were not appropriate for estimating the weight of children admitted to the PICU.

Relevant Study Results
“Simple linear regression was used to produce novel formulae for the prediction of the mean weight specifically for the PICU population” (Flannigan et al., 2014, p. 927). The three novel formulas are presented in Figures 1, 2, and 3, respectively. The new formulas calculations are more complex than the APLS UK formulas. “Although a good estimate of mean weight can be obtained by our newly derived formula, reliance on mean weight alone will still result in significant error as the weights of children admitted to PICU in each age and sex [gender] group have a large standard deviation . . . Therefore as soon as possible after admission a weight should be obtained, e.g., using a weight bed” (Flannigan et al., 2014, p. 929).

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FIGURE 1 Comparison of actual weight with weight calculated using APLS formula “Weight in kg = (0.5 × age in months) + 4” and novel formula “Weight in kg = (0.502 × age in months) + 3.161” Flannigan, C., Bourke, T. W., Sproule, A., Stevenson, M., & Terris, M. (2014). Are APLS formulae for estimating weight appropriate for use in children admitted to PICU? Resuscitation, 85(7), p. 928.
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FIGURE 2 Comparison of actual weight with weight calculated using APLS formula “Weight in kg = (2 × age in years) + 8” and novel formula “Weight in kg = (0.176 × age in months) + 7.241” Flannigan, C., Bourke, T. W., Sproule, A., Stevenson, M., & Terris, M. (2014). Are APLS formulae for estimating weight appropriate for use in children admitted to PICU? Resuscitation, 85(7), p. 928.
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FIGURE 3 Comparison of actual weight with weight calculated using APLS formula “Weight in kg = (3 × age in years) + 7” and novel formula “Weight in kg = (0.331 × age in months) − 6.868” Flannigan, C., Bourke, T. W., Sproule, A., Stevenson, M., & Terris, M. (2014). Are APLS formulae for estimating weight appropriate for use in children admitted to PICU? Resuscitation, 85(7), p. 929.

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Study Questions
1. What are the variables on the x- and y-axes in Figure 1 from the Flannigan et al. (2014) study?

2. What is the name of the type of variable represented by x and y in Figure 1? Is x or y the score to be predicted?

3. What is the purpose of simple linear regression analysis and the regression equation?

4. What is the point where the regression line meets the y-axis called? Is there more than one term for this point and what is the value of x at that point?

5. In the formula y = bx + a, is a or b the slope? What does the slope represent in regression analysis?

6. Using the values a = 3.161 and b = 0.502 with the novel formula in Figure 1, what is the predicted weight in kilograms for a child at 5 months of age? Show your calculations.

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7. What are the variables on the x-axis and the y-axis in Figures 2 and 3? Describe these variables and how they might be entered into the regression novel formulas identified in Figures 2 and 3.

8. Using the values a = 7.241 and b = 0.176 with the novel formula in Figure 2, what is the predicted weight in kilograms for a child at 4 years of age? Show your calculations.

9. Does Figure 1 have a positive or negative slope? Provide a rationale for your answer. Discuss the meaning of the slope of Figure 1.

10. According to the study narrative, why are estimated child weights important in a pediatric intensive care (PICU) setting? What are the implications of these findings for practice?

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Answers to Study Questions
1. The x variable is age in months, and the y variable is weight in kilograms in Figure 1.

2. x is the independent or predictor variable. y is the dependent variable or the variable that is to be predicted by the independent variable, x.

3. Simple linear regression is conducted to estimate or predict the values of one dependent variable based on the values of one independent variable. Regression analysis is used to calculate a line of best fit based on the relationship between the independent variable x and the dependent variable y. The formula developed with regression analysis can be used to predict the dependent variable (y) values based on values of the independent variable x.

4. The point where the regression line meets the y-axis is called the y intercept and is also represented by a (see Figure 14-1). a is also called the regression constant. At the y intercept, x = 0.

5. b is the slope of the line of best fit (see Figure 14-1). The slope of the line indicates the amount of change in y for each one unit of change in x. b is also called the regression coefficient.

6. Use the following formula to calculate your answer: y = bx + a
y = 0.502 (5) + 3.161 = 2.51 + 3.161 = 5.671 kilograms
Note: Flannigan et al. (2014) expressed the novel formula of weight in kilograms = (0.502 × age in months) + 3.161 in the title of Figure 1.

7. Age in years is displayed on the x-axis and is used for the APLS UK formulas in Figures 2 and 3. Figure 2 includes children 1 to 5 years of age, and Figure 3 includes children 6 to 12 years of age. However, the novel formulas developed by simple linear regression are calculated with age in months. Therefore, the age in years must be converted to age in months before calculating the y values with the novel formulas provided for Figures 2 and 3. For example, a child who is 2 years old would be converted to 24 months (2 × 12 mos./year = 24 mos.). Then the formulas in Figures 2 and 3 could be used to predict y (weight in kilograms) for the different aged children. The y-axis on both Figures 2 and 3 is weight in kilograms (kg).

8. First calculate the child’s age in months, which is 4 × 12 months/year = 48 months.
y = bx + a = 0.176 (48) + 7.241 = 8.448 + 7.241 = 15.689 kilograms
Note the x value needs to be in age in months and Flannigan et al. (2014) expressed the novel formula of weight in kilograms = (0.176 × age in months) + 7.241.

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9. Figure 1 has a positive slope since the line extends from the lower left corner to the upper right corner and shows a positive relationship. This line shows that the increase in x (independent variable) is associated with an increase in y (dependent variable). In the Flannigan et al. (2014) study, the independent variable age in months is used to predict the dependent variable of weight in kilograms. As the age in months increases, the weight in kilograms also increases, which is the positive relationship illustrated in Figure 1.

10. According to Flannigan et al. (2014, p. 927), “The gold standard for prescribing therapies to children admitted to Paediatric Intensive Care Units (PICU) requires accurate measurement of the patient’s weight. . . . An accurate weight may not be obtainable immediately because of instability and on-going resuscitation. An accurate tool to aid the critical care team estimate the weight of these children would be a valuable clinical tool.” Accurate patient weights are an important factor in preventing medication errors particularly in pediatric populations. The American Academy of Pediatrics (AAP)’s policy on Prevention of Medication Errors in the Pediatric Inpatient Setting can be obtained from the following website: https://www.aap.org/en-us/advocacy-and-policy/federal-advocacy/Pages/Federal-Advocacy.aspx#SafeandEffectiveDrugsandDevicesforChildren. The Centers for Medicare & Medicaid Services, Partnership for Patients provides multiple links to Adverse Drug Event (ADE) information including some resources specific to pediatrics at http://partnershipforpatients.cms.gov/p4p_resources/tsp-adversedrugevents/tooladversedrugeventsade.html.

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EXERCISE 14 Questions to Be Graded
Follow your instructor’s directions to submit your answers to the following questions for grading. Your instructor may ask you to write your answers below and submit them as a hard copy for grading. Alternatively, your instructor may ask you to use the space below for notes and submit your answers online at http://evolve.elsevier.com/Grove/Statistics/ under “Questions to Be Graded.”

Name: _______________________________________________________ Class: _____________________

Date: ___________________________________________________________________________________

1. According to the study narrative and Figure 1 in the Flannigan et al. (2014) study, does the APLS UK formula under- or overestimate the weight of children younger than 1 year of age? Provide a rationale for your answer.

2. Using the values a = 3.161 and b = 0.502 with the novel formula in Figure 1, what is the predicted weight in kilograms (kg) for a child at 9 months of age? Show your calculations.

3. Using the values a = 3.161 and b = 0.502 with the novel formula in Figure 1, what is the predicted weight in kilograms for a child at 2 months of age? Show your calculations.

4. In Figure 2, the formula for calculating y (weight in kg) is Weight in kg = (0.176 × Age in months) + 7.241. Identify the y intercept and the slope in this formula.

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5. Using the values a = 7.241 and b = 0.176 with the novel formula in Figure 2, what is the predicted weight in kilograms for a child 3 years of age? Show your calculations.

6. Using the values a = 7.241 and b = 0.176 with the novel formula in Figure 2, what is the predicted weight in kilograms for a child 5 years of age? Show your calculations.

7. In Figure 3, some of the actual mean weights represented by blue line with squares are above the dotted straight line for the novel formula, but others are below the straight line. Is this an expected finding? Provide a rationale for your answer.

8. In Figure 3, the novel formula is (weight in kilograms = (0.331 × Age in months) − 6.868. What is the predicted weight in kilograms for a child 10 years old? Show your calculations.

9. Was the sample size of this study adequate for conducting simple linear regression? Provide a rationale for your answer.

10. Describe one potential clinical advantage and one potential clinical problem with using the three novel formulas presented in Figures 1, 2, and 3 in a PICU setting.

(Grove 139-150)

Grove, Susan K., Daisha Cipher. Statistics for Nursing Research: A Workbook for Evidence-Based Practice, 2nd Edition. Saunders, 022016. VitalBook file.

The citation provided is a guideline. Please check each citation for accuracy before use.

 

Exercise 19
Understanding Pearson Chi-Square
Statistical Technique in Review
The Pearson Chi-square (χ2 ) is an inferential statistical test calculated to examine differences among groups with variables measured at the nominal level. There are different types of χ2 tests and the Pearson chi-square is commonly reported in nursing studies. The Pearson χ2 test compares the frequencies that are observed with the frequencies that were expected. The assumptions for the χ2 test are as follows:

1. The data are nominal-level or frequency data.

2. The sample size is adequate.

3. The measures are independent of each other or that a subject’s data only fit into one category (Plichta & Kelvin, 2013).

The χ2 values calculated are compared with the critical values in the χ2 table (see Appendix D Critical Values of the χ2 Distribution at the back of this text). If the result is greater than or equal to the value in the table, significant differences exist. If the values are statistically significant, the null hypothesis is rejected (Grove, Burns, & Gray, 2013). These results indicate that the differences are probably an actual reflection of reality and not just due to random sampling error or chance.

In addition to the χ2 value, researchers often report the degrees of freedom (df). This mathematically complex statistical concept is important for calculating and determining levels of significance. The standard formula for df is sample size (N) minus 1, or df = N − 1; however, this formula is adjusted based on the analysis technique performed (Plichta & Kelvin, 2013). The df formula for the χ2 test varies based on the number of categories examined in the analysis. The formula for df for the two-way χ2 test is df = (R − 1) (C − 1), where R is number of rows and C is the number of columns in a χ2 table. For example, in a 2 × 2 χ2 table, df = (2 − 1) (2 − 1) = 1. Therefore, the df is equal to 1. Table 19-1 includes a 2 × 2 chi-square contingency table based on the findings of An et al. (2014) study. In Table 19-1, the rows represent the two nominal categories of alcohol 192use and alcohol nonuse and the two columns represent the two nominal categories of smokers and nonsmokers. The df = (2 − 1) (2 − 1) = (1) (1) = 1, and the study results were as follows: χ2 (1, N = 799) = 63.1; p < 0.0001. It is important to note that the df can also be reported without the sample size, as in χ2(1) = 63.1, p < 0.0001.

TABLE 19-1

CONTINGENCY TABLE BASED ON THE RESULTS OF AN ET AL. (2014) STUDY

Nonsmokers n = 742 Smokers n = 57*
No alcohol use 551 14
Alcohol use† 191 43
*Smokers defined as “smoking at least 1 cigarette daily during the past month.”

†Alcohol use “defined as at least 1 alcoholic beverage per month during the past year.”

An, F. R., Xiang, Y. T., Yu., L., Ding, Y. M., Ungvari, G. S., Chan, S. W. C., et al. (2014). Prevalence of nurses’ smoking habits in psychiatric and general hospitals in China. Archives of Psychiatric Nursing, 28(2), 120.

If more than two groups are being examined, χ2 does not determine where the differences lie; it only determines that a statistically significant difference exists. A post hoc analysis will determine the location of the difference. χ2 is one of the weaker statistical tests used, and results are usually only reported if statistically significant values are found. The step-by-step process for calculating the Pearson chi-square test is presented in Exercise 35.

Research Article
Source
Darling-Fisher, C. S., Salerno, J., Dahlem, C. H. Y., & Martyn, K. K. (2014). The Rapid Assessment for Adolescent Preventive Services (RAAPS): Providers’ assessment of its usefulness in their clinical practice settings. Journal of Pediatric Health Care, 28(3), 217–226.

Introduction
Darling-Fisher and colleagues (2014, p. 219) conducted a mixed-methods descriptive study to evaluate the clinical usefulness of the Rapid Assessment for Adolescent Preventative Services (RAAPS) screening tool “by surveying healthcare providers from a wide variety of clinical settings and geographic locations.” The study participants were recruited from the RAAPS website to complete an online survey. The RAAPS risk-screening tool “was developed to identify the risk behaviors contributing most to adolescent morbidity, mortality, and social problems, and to provide a more streamlined assessment to help providers address key adolescent risk behaviors in a time-efficient and user-friendly format” (Darling-Fisher et al., 2014, p. 218). The RAAPS is an established 21-item questionnaire with evidence of reliability and validity that can be completed by adolescents in 5–7 minutes.

“Quantitative and qualitative analyses indicated the RAAPS facilitated identification of risk behaviors and risk discussions and provided efficient and consistent assessments; 86% of providers believed that the RAAPS positively influenced their practice” (Darling-Fisher et al., 2014, p. 217). The researchers concluded the use of RAAPS by healthcare providers could improve the assessment and identification of adolescents at risk and lead to the delivery of more effective adolescent preventive services.

Relevant Study Results
In the Darling-Fisher et al. (2014, p. 220) mixed-methods study, the participants (N = 201) were “providers from 26 U.S. states and three foreign countries (Canada, Korea, and Ireland).” More than half of the participants (n = 111; 55%) reported they were using the RAAPS in their clinical practices. “When asked if they would recommend the RAAPS to other providers, 86 responded, and 98% (n = 84) stated they would recommend RAAPS. The two most common reasons cited for their recommendation were for screening (n = 76, 92%) and identification of risk behaviors (n = 75, 90%). Improved communication (n = 52, 63%) and improved documentation (n = 46, 55%) and increased patient understanding of their risk behaviors (n = 48, 58%) were also cited by respondents as reasons to recommend the RAAPS” (Darling-Fisher et al., 2014, p. 222).

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“Respondents who were not using the RAAPS (n = 90; 45%), had a variety of reasons for not using it. Most reasons were related to constraints of their health system or practice site; other reasons were satisfaction with their current method of assessment . . . and that they were interested in the RAAPS for academic or research purposes rather than clinical use” (Darling-Fisher et al., 2014, p. 220).

Chi-square analysis was calculated to determine if any statistically significant differences existed between the characteristics of the RAAPS users and nonusers. Darling-Fisher et al. (2014) did not provide a level of significance or α for their study, but the standard for nursing studies is α = 0.05. “Statistically significant differences were noted between RAAPS users and nonusers with respect to provider types, practice setting, percent of adolescent patients, years in practice, and practice region. No statistically significant demographic differences were found between RAAPS users and nonusers with respect to race, age” (Darling-Fisher et al., 2014, p. 221). The χ2 results are presented in Table 2.

TABLE 2

DEMOGRAPHIC COMPARISONS BETWEEN RAPID ASSESSMENT FOR ADOLESCENT PREVENTIVE SERVICE USERS AND NONUSERS

Current user Yes (%) No (%) χ2 p
Provider type (n = 161) 12.7652, df = 2 < .00
Health care provider 64 (75.3) 55 (72.4)
Mental health provider 13 (15.3) 2 (2.6)
Other 8 (9.4) 19 (25.0)
Practice setting (n = 152) 12.7652, df = 1 < .00
Outpatient health clinic 20 (24.1) 36 (52.2)
School-based health clinic 63 (75.9) 33 (47.8)
% Adolescent patients (n = 154) 7.3780, df = 1 .01
≤50% 26 (30.6) 36 (52.2)
>50% 59 (69.4) 33 (47.8)
Years in practice (n = 157) 6.2597, df = 1 .01
≤5 years 44 (51.8) 23 (31.9)
>5 years 41 (48.2) 49 (68.1)
U.S. practice region (n = 151) 29.68, df = 3 < .00
Northeastern United States 13 (15.3) 15 (22.7)
Southern United States 11 (12.9) 22 (33.3)
Midwestern United States 57 (67.1) 16 (24.2)
Western United States 4 (4.7) 13 (19.7)
Race (n = 201) 1.2865, df = 2 .53
Black/African American 11 (9.9) 5 (5.6)
White/Caucasian 66 (59.5) 56 (62.2)
Other 34 (30.6) 29 (32.2)
Provider age in years (n = 145) 4.00, df = 2 .14
20–39 years 21 (25.6) 8 (12.7)
40–49 years 24 (29.3) 19 (30.2)
50+ years 37 (45.1) 36 (57.1)
image

χ2, Chi-square statistic.

df, degrees of freedom.

Darling-Fisher, C. S., Salerno, J., Dahlem, C. H. Y., & Martyn, K. K. (2014). The Rapid Assessment for Adolescent Preventive Services (RAAPS): Providers’ assessment of its usefulness in their clinical practice settings. Journal of Pediatric Health Care, 28(3), p. 221.

194
Study Questions
1. What is the sample size for the Darling-Fisher et al. (2014) study? How many study participants (percentage) are RAAPS users and how many are RAAPS nonusers?

2. What is the chi-square (χ2) value and degrees of freedom (df) for provider type?

3. What is the p value for provider type? Is the χ2 value for provider type statistically significant? Provide a rationale for your answer.

4. Does a statistically significant χ2 value provide evidence of causation between the variables? Provide a rationale for your answer.

5. What is the χ2 value for race? Is the χ2 value statistically significant? Provide a rationale for your answer.

6. Is there a statistically significant difference between RAAPS users and RAAPS nonusers with regard to percentage adolescent patients? In your own opinion is this an expected finding? Document your answer.

195
7. What is the df for U.S. practice region? Complete the df formula for U.S. practice region to visualize how Darling-Fisher et al. (2014) determined the appropriate df for that region.

8. State the null hypothesis for the years in practice variable for RAAPS users and RAAPS nonusers.

9. Should the null hypothesis for years in practice developed for Question 8 be accepted or rejected? Provide a rationale for your answer.

10. How many null hypotheses were accepted by Darling-Fisher et al. (2014) in Table 2? Provide a rationale for your answer.

196
Answers to Study Questions
1. The sample size is N = 201 with n = 111 (55%) RAAPS users and n = 90 (45%) RAAPS nonusers as indicated in the narrative results.

2. The χ2 = 12.7652 and df = 2 for provider type as presented in Table 2.

3. The p = < .00 for the provider type. Yes, the χ2 = 12.7652 for provider type is statistically significant as indicated by the p value presented in Table 2. The specific χ2 value obtained could be compared against the critical value in a χ2 table (see Appendix D Critical Values of the χ2 Distribution at the back of this text) to determine the significance for the specific degrees of freedom (df), but readers of research reports usually rely on the p value provided by the researcher(s) to determine significance. Most nurse researchers set the level of significance or alpha (α) = 0.05. Since the p value is less than alpha, the result is statistically significant. You need to note that p values never equal zero as they appear in this study. The p values would not be zero if carried out more decimal places.

4. No, a statistically significant χ2 value does not provide evidence of causation. A statistically significant χ2 value indicates a significant difference between groups exists but does not provide a causal link (Grove et al., 2013; Plichta & Kelvin, 2013).

5. The χ2 = 1.2865 for race. Since p = .53 for race, the χ2 value is not statistically significant. The level of significance is set at α = 0.05 and the p value is larger than alpha, so the result is nonsignificant.

6. Yes, there is a statistically significant difference between RAAPS users and RAAPS nonusers with regard to percent of adolescent patients. The chi-square value = 7.3780 with a p = .01.You might expect that nurses caring for more adolescents might have higher RAAPS use as indicated in Table 2. However, nurses need to be knowledgeable of assessment and care needs of populations and subpopulations in their practice even if not frequently encountered. Two valuable sources for adolescent care include the Centers for Disease Control and Prevention (CDC) Adolescent and School Health at http://www.cdc.gov/HealthyYouth/idex.htm and the World Health Organization (WHO) adolescent health at http://www.who.int/topics/adolescent_health/en/.

7. The df = 3 for U.S. practice region is provided in Table 2. The df formula, df = (R − 1) (C − 1) is used. There are four “R” rows, Northeastern United States, Southern United States, Midwestern United States, and Western United States. There are two “C” columns, RAAPS users and RAAPS nonusers. df = (4 − 1)(2 − 1) = (3)(1) = 3.

8. The null hypothesis: There is no difference between RAAPS users and RAAPS nonusers for providers with ≤5 years of practice and those with >5 years of practice.

197
9. The null hypothesis for years in practice stated in Questions 8 should be rejected. The χ2 = 6.2597 for years in practice is statistically significant, p = .01. A statistically significant χ2 indicates a significant difference exists between the users and nonusers of RAAPS for years in practice; therefore, the null hypothesis should be rejected.

10. Two null hypotheses were accepted since two χ2 values (race and provider age) were not statistically significant (p > 0.05), as indicated in Table 2. Nonsignificant results indicate that the null hypotheses are supported or accepted as an accurate reflection of the results of the study.

199
EXERCISE 19 Questions to Be Graded
Follow your instructor’s directions to submit your answers to the following questions for grading. Your instructor may ask you to write your answers below and submit them as a hard copy for grading. Alternatively, your instructor may ask you to use the space below for notes and submit your answers online at http://evolve.elsevier.com/Grove/Statistics/ under “Questions to Be Graded.”

Name: _______________________________________________________ Class: _____________________

Date: ___________________________________________________________________________________

1. According to the relevant study results section of the Darling-Fisher et al. (2014) study, what categories are reported to be statistically significant?

2. What level of measurement is appropriate for calculating the χ2 statistic? Give two examples from Table 2 of demographic variables measured at the level appropriate for χ2.

3. What is the χ2 for U.S. practice region? Is the χ2 value statistically significant? Provide a rationale for your answer.

4. What is the df for provider type? Provide a rationale for why the df for provider type presented in Table 2 is correct.

200
5. Is there a statistically significant difference for practice setting between the Rapid Assessment for Adolescent Preventive Services (RAAPS) users and nonusers? Provide a rationale for your answer.

6. State the null hypothesis for provider age in years for RAAPS users and RAAPS nonusers.

7. Should the null hypothesis for provider age in years developed for Question 6 be accepted or rejected? Provide a rationale for your answer.

8. Describe at least one clinical advantage and one clinical challenge of using RAAPS as described by Darling-Fisher et al. (2014).

9. How many null hypotheses are rejected in the Darling-Fisher et al. (2014) study for the results presented in Table 2? Provide a rationale for your answer.

10. A statistically significant difference is present between RAAPS users and RAAPS nonusers for U.S. practice region, χ2 = 29.68. Does the χ2 result provide the location of the difference? Provide a rationale for your answer

(Grove 191-200)

Grove, Susan K., Daisha Cipher. Statistics for Nursing Research: A Workbook for Evidence-Based Practice, 2nd Edition. Saunders, 022016. VitalBook file.

The citation provided is a guideline. Please check each citation for accuracy before use.

 

 

Exercise 29
Calculating Simple Linear Regression
Simple linear regression is a procedure that provides an estimate of the value of a dependent variable (outcome) based on the value of an independent variable (predictor). Knowing that estimate with some degree of accuracy, we can use regression analysis to predict the value of one variable if we know the value of the other variable (Cohen & Cohen, 1983). The regression equation is a mathematical expression of the influence that a predictor has on a dependent variable, based on some theoretical framework. For example, in Exercise 14, Figure 14-1 illustrates the linear relationship between gestational age and birth weight. As shown in the scatterplot, there is a strong positive relationship between the two variables. Advanced gestational ages predict higher birth weights.

A regression equation can be generated with a data set containing subjects’ x and y values. Once this equation is generated, it can be used to predict future subjects’ y values, given only their x values. In simple or bivariate regression, predictions are made in cases with two variables. The score on variable y (dependent variable, or outcome) is predicted from the same subject’s known score on variable x (independent variable, or predictor).

Research Designs Appropriate for Simple Linear Regression
Research designs that may utilize simple linear regression include any associational design (Gliner et al., 2009). The variables involved in the design are attributional, meaning the variables are characteristics of the participant, such as health status, blood pressure, gender, diagnosis, or ethnicity. Regardless of the nature of variables, the dependent variable submitted to simple linear regression must be measured as continuous, at the interval or ratio level.

Statistical Formula and Assumptions
Use of simple linear regression involves the following assumptions (Zar, 2010):

1. Normal distribution of the dependent (y) variable

2. Linear relationship between x and y

3. Independent observations

4. No (or little) multicollinearity

5. Homoscedasticity

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Data that are homoscedastic are evenly dispersed both above and below the regression line, which indicates a linear relationship on a scatterplot. Homoscedasticity reflects equal variance of both variables. In other words, for every value of x, the distribution of y values should have equal variability. If the data for the predictor and dependent variable are not homoscedastic, inferences made during significance testing could be invalid (Cohen & Cohen, 1983; Zar, 2010). Visual examples of homoscedasticity and heteroscedasticity are presented in Exercise 30.

In simple linear regression, the dependent variable is continuous, and the predictor can be any scale of measurement; however, if the predictor is nominal, it must be correctly coded. Once the data are ready, the parameters a and b are computed to obtain a regression equation. To understand the mathematical process, recall the algebraic equation for a straight line:

y=bx+a

image
where

y=the dependent variable(outcome)

image
x=the independent variable(predictor)

image
b=the slope of the line

image
a=y-intercept(the point where the regression line intersects the y-axis)

image
No single regression line can be used to predict with complete accuracy every y value from every x value. In fact, you could draw an infinite number of lines through the scattered paired values (Zar, 2010). However, the purpose of the regression equa­tion is to develop the line to allow the highest degree of prediction possible—the line of best fit. The procedure for developing the line of best fit is the method of least squares. The formulas for the beta (β) and slope (α) of the regression equation are computed as follows. Note that once the β is calculated, that value is inserted into the formula for α.

β=n∑xy−∑x∑yn∑x 2 −(∑x) 2

image
α=∑y−b∑xn

image
Hand Calculations
This example uses data collected from a study of students enrolled in a registered nurse to bachelor of science in nursing (RN to BSN) program (Mancini, Ashwill, & Cipher, 2014). The predictor in this example is number of academic degrees obtained by the student prior to enrollment, and the dependent variable was number of months it took for the student to complete the RN to BSN program. The null hypothesis is “Number of degrees does not predict the number of months until completion of an RN to BSN program.”

The data are presented in Table 29-1. A simulated subset of 20 students was selected for this example so that the computations would be small and manageable. In actuality, studies involving linear regression need to be adequately powered (Aberson, 2010; Cohen, 1988). Observe that the data in Table 29-1 are arranged in columns that correspond to 321the elements of the formula. The summed values in the last row of Table 29-1 are inserted into the appropriate place in the formula for b.

TABLE 29-1

ENROLLMENT GPA AND MONTHS TO COMPLETION IN AN RN TO BSN PROGRAM

Student ID x y x2 xy
(Number of Degrees) (Months to Completion)
1 1 17 1 17
2 2 9 4 18
3 0 17 0 0
4 1 9 1 9
5 0 16 0 0
6 1 11 1 11
7 0 15 0 0
8 0 12 0 0
9 1 15 1 15
10 1 12 1 12
11 1 14 1 14
12 1 10 1 10
13 1 17 1 17
14 0 20 0 0
15 2 9 4 18
16 2 12 4 24
17 1 14 1 14
18 2 10 4 20
19 1 17 1 17
20 2 11 4 22
sum Σ 20 267 30 238
image

The computations for the b and α are as follows:

Step 1: Calculate b.
From the values in Table 29-1, we know that n = 20, Σx = 20, Σy = 267, Σx2 = 30, and Σxy = 238. These values are inserted into the formula for b, as follows:

b=20(238)−(20)(267)20(30)−20 2

image

b=−2.9

image

Step 2: Calculate α.
From Step 1, we now know that b = −2.9, and we plug this value into the formula for α.

α=267−(−2.9)(20)20

image

α=16.25

image

Step 3: Write the new regression equation:

y=−2.9x+16.25

image

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Step 4: Calculate R.
The multiple R is defined as the correlation between the actual y values and the predicted y values using the new regression equation. The predicted y value using the new equation is represented by the symbol ŷ to differentiate from y, which represents the actual y values in the data set. We can use our new regression equation from Step 3 to compute predicted program completion time in months for each student, using their number of academic degrees prior to enrollment in the RN to BSN Program. For example, Student #1 had earned 1 academic degree prior to enrollment, and the predicted months to completion for Student 1 is calculated as:

y ̂ =−2.9(1)+16.25

image

y ̂ =13.35

image

Thus, the predicted ŷ is 13.35 months. This procedure would be continued for the rest of the students, and the Pearson correlation between the actual months to completion (y) and the predicted months to completion (ŷ) would yield the multiple R value. In this example, the R = 0.638. The higher the R, the more likely that the new regression equation accurately predicts y, because the higher the correlation, the closer the actual y values are to the predicted ŷ values. Figure 29-1 displays the regression line where the x axis represents possible numbers of degrees, and the y axis represents the predicted months to program completion (ŷ values).

image
FIGURE 29-1 REGRESSION LINE REPRESENTED BY NEW REGRESSION EQUATION.
Step 5: Determine whether the predictor significantly predicts y.

t=Rn−21−R 2 ‾ ‾ ‾ ‾ √

image

To know whether the predictor significantly predicts y, the beta must be tested against zero. In simple regression, this is most easily accomplished by using the R value from Step 4:

t=.638200−21−.407 ‾ ‾ ‾ ‾ ‾ √

image

t=3.52

image

323

The t value is then compared to the t probability distribution table (see Appendix A). The df for this t statistic is n − 2. The critical t value at alpha (α) = 0.05, df = 18 is 2.10 for a two-tailed test. Our obtained t was 3.52, which exceeds the critical value in the table, thereby indicating a significant association between the predictor (x) and outcome (y).

Step 6: Calculate R2.
After establishing the statistical significance of the R value, it must subsequently be examined for clinical importance. This is accomplished by obtaining the coefficient of determination for regression—which simply involves squaring the R value. The R2 represents the percentage of variance explained in y by the predictor. Cohen describes R2 values of 0.02 as small, 0.15 as moderate, and 0.26 or higher as large effect sizes (Cohen, 1988). In our example, the R was 0.638, and, therefore, the R2 was 0.407. Multiplying 0.407 × 100% indicates that 40.7% of the variance in months to program completion can be explained by knowing the student’s number of earned academic degrees at admission (Cohen & Cohen, 1983).
The R2 can be very helpful in testing more than one predictor in a regression model. Unlike R, the R2 for one regression model can be compared with another regression model that contains additional predictors (Cohen & Cohen, 1983). The R2 is discussed further in Exercise 30.
The standardized beta (β) is another statistic that represents the magnitude of the association between x and y. β has limits just like a Pearson r, meaning that the standardized β cannot be lower than −1.00 or higher than 1.00. This value can be calculated by hand but is best computed with statistical software. The standardized beta (β) is calculated by converting the x and y values to z scores and then correlating the x and y value using the Pearson r formula. The standardized beta (β) is often reported in literature instead of the unstandardized b, because b does not have lower or upper limits and therefore the magnitude of b cannot be judged. β, on the other hand, is interpreted as a Pearson r and the descriptions of the magnitude of β can be applied, as recommended by Cohen (1988). In this example, the standardized beta (β) is −0.638. Thus, the magnitude of the association between x and y in this example is considered a large predictive association (Cohen, 1988).

324
SPSS Computations
This is how our data set looks in SPSS.

image

Step 1: From the “Analyze” menu, choose “Regression” and “Linear.”

Step 2: Move the predictor, Number of Degrees, to the space labeled “Independent(s).” Move the dependent variable, Number of Months to Completion, to the space labeled “Dependent.” Click “OK.”

image

325
Interpretation of SPSS Output
The following tables are generated from SPSS. The first table contains the multiple R and the R2 values. The multiple R is 0.638, indicating that the correlation between the actual y values and the predicted y values using the new regression equation is 0.638. The R2 is 0.407, indicating that 40.7% of the variance in months to program completion can be explained by knowing the student’s number of earned academic degrees at enrollment.

Regression
image
The second table contains the ANOVA table. As presented in Exercises 18 and 33, the ANOVA is usually performed to test for differences between group means. However, ANOVA can also be performed for regression, where the null hypothesis is that “knowing the value of x explains no information about y”. This table indicates that knowing the value of x explains a significant amount of variance in y. The contents of the ANOVA table are rarely reported in published manuscripts, because the significance of each predictor is presented in the last SPSS table titled “Coefficients” (see below).

image
The third table contains the b and a values, standardized beta (β), t, and exact p value. The a is listed in the first row, next to the label “Constant.” The β is listed in the second row, next to the name of the predictor. The remaining information that is important to extract when interpreting regression results can be found in the second row. The standardized beta (β) is −0.638. This value has limits just like a Pearson r, meaning that the standardized β cannot be lower than −1.00 or higher than 1.00. The t value is −3.516, and the exact p value is 0.002.

image
326
Final Interpretation in American Psychological Association (APA) Format
The following interpretation is written as it might appear in a research article, formatted according to APA guidelines (APA, 2010). Simple linear regression was performed with number of earned academic degrees as the predictor and months to program completion as the dependent variable. The student’s number of degrees significantly predicted months to completion among students in an RN to BSN program, β = −0.638, p = 0.002, and R2 = 40.7%. Higher numbers of earned academic degrees significantly predicted shorter program completion time.

327
Study Questions
1. If you have access to SPSS, compute the Shapiro-Wilk test of normality for months to completion (as demonstrated in Exercise 26). If you do not have access to SPSS, plot the frequency distributions by hand. What do the results indicate?

2. State the null hypothesis for the example where number of degrees was used to predict time to BSN program completion.

3. In the formula y = bx + a, what does “b” represent?

4. In the formula y = bx + a, what does “a” represent?

5. Using the new regression equation, ŷ = −2.9x + 16.25, compute the predicted months to program completion if a student’s number of earned degrees is 0. Show your calculations.

6. Using the new regression equation, ŷ = −2.9x + 16.25, compute the predicted months to program completion if a student’s number of earned degrees is 2. Show your calculations.

328
7. What was the correlation between the actual y values and the predicted y values using the new regression equation in the example?

8. What was the exact likelihood of obtaining a t value at least as extreme as or as close to the one that was actually observed, assuming that the null hypothesis is true?

9. How much variance in months to completion is explained by knowing the student’s number of earned degrees?

10. How would you characterize the magnitude of the R2 in the example? Provide a rationale for your answer.

329
Answers to Study Questions
1. The Shapiro-Wilk p value for months to RN to BSN program completion was 0.16, indicating that the frequency distribution did not significantly deviate from normality. Moreover, visual inspection of the frequency distribution indicates that months to completion is approximately normally distributed. See SPSS output below for the histograms of the distribution:

image

2. The null hypothesis is: “The number of earned academic degrees does not predict the number of months until completion of an RN to BSN program.”

3. In the formula y = bx + a, “b” represents the slope of the regression line.

4. In the formula y = bx + a, “a” represents the y-intercept, or the point at which the regression line intersects the y-axis.

5. The predicted months to program completion if a student’s number of academic degrees is 0 is calculated as: ŷ = −2.9(0) + 16.25 = 16.25 months.

6. The predicted months to program completion if a student’s number of academic degrees is 2 is calculated as: ŷ = −2.9(2) + 16.25 = 10.45 months.

7. The correlation between the actual y values and the predicted y values using the new regression equation in the example, also known as the multiple R, is 0.638.

8. The exact likelihood of obtaining a t value at least as extreme as or as close to the one that was actually observed, assuming that the null hypothesis is true, was 0.2%. This value was obtained by looking at the SPSS output table titled “Coefficients” in the last value of the column labeled “Sig.”

9. 40.7% of the variance in months to completion is explained by knowing the student’s number of earned academic degrees at enrollment.

10. The magnitude of the R2 in this example, 0.407, would be considered a large effect according to the effect size tables in Exercises 24 and 25.

330
Data for Additional Computational Practice for the Questions to be Graded
Using the example from Mancini and colleagues (2014), students enrolled in an RN to BSN program were assessed for demographics at enrollment. The predictor in this example is age at program enrollment, and the dependent variable was number of months it took for the student to complete the RN to BSN program. The null hypothesis is: “Student age at enrollment does not predict the number of months until completion of an RN to BSN program.” The data are presented in Table 29-2. A simulated subset of 20 students was randomly selected for this example so that the computations would be small and manageable.

TABLE 29-2

AGE AT ENROLLMENT AND MONTHS TO COMPLETION IN AN RN TO BSN PROGRAM

Student ID x y x2 xy
(Student Age) (Months to Completion)
1 23 17 529 391
2 24 9 576 216
3 24 17 576 408
4 26 9 676 234
5 31 16 961 496
6 31 11 961 341
7 32 15 1,024 480
8 33 12 1,089 396
9 33 15 1,089 495
10 34 12 1,156 408
11 34 14 1,156 476
12 35 10 1,225 350
13 35 17 1,225 595
14 39 20 1,521 780
15 40 9 1,600 360
16 42 12 1,764 504
17 42 14 1,764 588
18 44 10 1,936 440
19 51 17 2,601 867
20 24 11 576 264
sum Σ 677 267 24,005 9,089
image

331
EXERCISE 29 Questions to Be Graded
Name: _______________________________________________________ Class: _____________________

Date: ___________________________________________________________________________________

Follow your instructor’s directions to submit your answers to the following questions for grading. Your instructor may ask you to write your answers below and submit them as a hard copy for grading. Alternatively, your instructor may ask you to use the space below for notes and submit your answers online at http://evolve.elsevier.com/Grove/Statistics/ under “Questions to Be Graded.”

1. If you have access to SPSS, compute the Shapiro-Wilk test of normality for the variable age (as demonstrated in Exercise 26). If you do not have access to SPSS, plot the frequency distributions by hand. What do the results indicate?

2. State the null hypothesis where age at enrollment is used to predict the time for completion of an RN to BSN program.

3. What is b as computed by hand (or using SPSS)?

4. What is a as computed by hand (or using SPSS)?

332
5. Write the new regression equation.

6. How would you characterize the magnitude of the obtained R2 value? Provide a rationale for your answer.

7. How much variance in months to RN to BSN program completion is explained by knowing the student’s enrollment age?

8. What was the correlation between the actual y values and the predicted y values using the new regression equation in the example?

9. Write your interpretation of the results as you would in an APA-formatted journal.

10. Given the results of your analyses, would you use the calculated regression equation to predict future students’ program completion time by using enrollment age as x? Provide

(Grove 319-332)

Grove, Susan K., Daisha Cipher. Statistics for Nursing Research: A Workbook for Evidence-Based Practice, 2nd Edition. Saunders, 022016. VitalBook file.

The citation provided is a guideline. Please check each citation for accuracy before use.

https://eazyweezyhomeworks.com/benefits-of-using-tablets-in-schools/

 

Exercise 35
Calculating Pearson Chi-Square
The Pearson chi-square test (χ2) compares differences between groups on variables measured at the nominal level. The χ2 compares the frequencies that are observed with the frequencies that are expected. When a study requires that researchers compare proportions (percentages) in one category versus another category, the χ2 is a statistic that will reveal if the difference in proportion is statistically improbable.

A one-way χ2 is a statistic that compares different levels of one variable only. For example, a researcher may collect information on gender and compare the proportions of males to females. If the one-way χ2 is statistically significant, it would indicate that proportions of one gender are significantly higher than proportions of the other gender than what would be expected by chance (Daniel, 2000). If more than two groups are being examined, the χ2 does not determine where the differences lie; it only determines that a significant difference exists. Further testing on pairs of groups with the χ2 would then be warranted to identify the significant differences.

A two-way χ2 is a statistic that tests whether proportions in levels of one nominal variable are significantly different from proportions of the second nominal variable. For example, the presence of advanced colon polyps was studied in three groups of patients: those having a normal body mass index (BMI), those who were overweight, and those who were obese (Siddiqui, Mahgoub, Pandove, Cipher, & Spechler, 2009). The research question tested was: “Is there a difference between the three groups (normal weight, overweight, and obese) on the presence of advanced colon polyps?” The results of the χ2 test indicated that a larger proportion of obese patients fell into the category of having advanced colon polyps compared to normal weight and overweight patients, suggesting that obesity may be a risk factor for developing advanced colon polyps. Further examples of two-way χ2 tests are reviewed in Exercise 19.

Research Designs Appropriate for the Pearson χ2
Research designs that may utilize the Pearson χ2 include the randomized experimental, quasi-experimental, and comparative designs (Gliner, Morgan, & Leech, 2009). The variables may be active, attributional, or a combination of both. An active variable refers to an intervention, treatment, or program. An attributional variable refers to a characteristic of the participant, such as gender, diagnosis, or ethnicity. Regardless of the whether the variables are active or attributional, all variables submitted to χ2 calculations must be measured at the nominal level.

410
Statistical Formula and Assumptions
Use of the Pearson χ2 involves the following assumptions (Daniel, 2000):

1. Only one datum entry is made for each subject in the sample. Therefore, if repeated measures from the same subject are being used for analysis, such as pretests and posttests, χ2 is not an appropriate test.

2. The variables must be categorical (nominal), either inherently or transformed to categorical from quantitative values.

3. For each variable, the categories are mutually exclusive and exhaustive. No cells may have an expected frequency of zero. In the actual data, the observed cell frequency may be zero. However, the Pearson χ2 test is sensitive to small sample sizes, and other tests, such as the Fisher’s exact test, are more appropriate when testing very small samples (Daniel, 2000; Yates, 1934).

The test is distribution-free, or nonparametric, which means that no assumption has been made for a normal distribution of values in the population from which the sample was taken (Daniel, 2000).

The formula for a two-way χ2 is:

χ 2 =n[(A)(D)−(B)(C)] 2 (A+B)(C+D)(A+C)(B+D)

image
The contingency table is labeled as follows. A contingency table is a table that displays the relationship between two or more categorical variables (Daniel, 2000):

A B
C D
With any χ2 analysis, the degrees of freedom (df) must be calculated to determine the significance of the value of the statistic. The following formula is used for this calculation:

df=(R−1)(C−1)

image
where

R=Number of rows

image
C=Number of columns

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Hand Calculations
A retrospective comparative study examined whether longer antibiotic treatment courses were associated with increased antimicrobial resistance in patients with spinal cord injury (Lee et al., 2014). Using urine cultures from a sample of spinal cord–injured veterans, two groups were created: those with evidence of antibiotic resistance and those with no evidence of antibiotic resistance. Each veteran was also divided into two groups based on having had a history of recent (in the past 6 months) antibiotic use for more than 2 weeks or no history of recent antibiotic use.

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The data are presented in Table 35-1. The null hypothesis is: “There is no difference between antibiotic users and non-users on the presence of antibiotic resistance.”

TABLE 35-1

ANTIBIOTIC RESISTANCE BY ANTIBIOTIC USE

Antibiotic Use No Recent Use
Resistant 8 7
Not resistant 6 21
The computations for the Pearson χ2 test are as follows:

Step 1: Create a contingency table of the two nominal variables:

Used Antibiotics No Recent Use Totals
Resistant 8 7 15
Not resistant 6 21 27
Totals 14 28 42 ←Total n
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Step 2: Fit the cells into the formula:

χ 2 =n[(A)(D)−(B)(C)] 2 (A+B)(C+D)(A+C)(B+D)

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χ 2 =42[(8)(21)−(7)(6)] 2 (8+7)(6+21)(8+6)(7+21)

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χ 2 =666,792158,760

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χ 2 =4.20

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Step 3: Compute the degrees of freedom:

df=(2−1)(2−1)=1

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Step 4: Locate the critical χ2 value in the χ2 distribution table (Appendix D) and compare it to the obtained χ2 value.

The obtained χ2 value is compared with the tabled χ2 values in Appendix D. The table includes the critical values of χ2 for specific degrees of freedom at selected levels of significance. If the value of the statistic is equal to or greater than the value identified in the χ2 table, the difference between the two variables is statistically significant. The critical χ2 for df = 1 is 3.84, and our obtained χ2 is 4.20, thereby exceeding the critical value and indicating a significant difference between antibiotic users and non-users on the presence of antibiotic resistance.

Furthermore, we can compute the rates of antibiotic resistance among antibiotic users and non-users by using the numbers in the contingency table from Step 1. The antibiotic resistance rate among the antibiotic users can be calculated as 8 ÷ 14 = 0.571 × 100% = 57.1%. The antibiotic resistance rate among the non-antibiotic users can be calculated as 7 ÷ 28 = 0.25 × 100% = 25%.

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SPSS Computations
The following screenshot is a replica of what your SPSS window will look like. The data for subjects 24 through 42 are viewable by scrolling down in the SPSS screen.

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Step 1: From the “Analyze” menu, choose “Descriptive Statistics” and “Crosstabs.” Move the two variables to the right, where either variable can be in the “Row” or “Column” space.

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Step 2: Click “Statistics” and check the box next to “Chi-square.” Click “Continue” and “OK.”

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Interpretation of SPSS Output
The following tables are generated from SPSS. The first table contains the contingency table, similar to Table 35-1 above. The second table contains the χ2 results.

Crosstabs
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The last table contains the χ2 value in addition to other statistics that test associations between nominal variables. The Pearson χ2 test is located in the first row of the table, which contains the χ2 value, df, and p value.

Final Interpretation in American Psychological Association (APA) Format
The following interpretation is written as it might appear in a research article, formatted according to APA guidelines (APA, 2010). A Pearson χ2 analysis indicated that antibiotic users had significantly higher rates of antibiotic resistance than those who did not use antibiotics, χ2(1) = 4.20, p = 0.04 (57.1% versus 25%, respectively). This finding suggests that extended antibiotic use may be a risk factor for developing resistance, and further research is needed to investigate resistance as a direct effect of antibiotics.

415
Study Questions
1. Do the example data meet the assumptions for the Pearson χ2 test? Provide a rationale for your answer.

2. What is the null hypothesis in the example?

3. What was the exact likelihood of obtaining a χ2 value at least as extreme or as close to the one that was actually observed, assuming that the null hypothesis is true?

4. Using the numbers in the contingency table, calculate the percentage of antibiotic users who were resistant.

5. Using the numbers in the contingency table, calculate the percentage of non-antibiotic users who were resistant.

6. Using the numbers in the contingency table, calculate the percentage of resistant veterans who used antibiotics for more than 2 weeks.

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7. Using the numbers in the contingency table, calculate the percentage of resistant veterans who had no history of antibiotic use.

8. What kind of design was used in the example?

9. What result would have been obtained if the variables in the SPSS Crosstabs window had been switched, with Antibiotic Use being placed in the “Row” and Resistance being placed in the “Column”?

10. Was the sample size adequate to detect differences between the two groups in this example? Provide a rationale for your answer.

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Answers to Study Questions
1. Yes, the data meet the assumptions of the Pearson χ2:

a. Only one datum per participant was entered into the contingency table, and no participant was counted twice.

b. Both antibiotic use and resistance are categorical (nominal-level data).

c. For each variable, the categories are mutually exclusive and exhaustive. It was not possible for a participant to belong to both groups, and the two categories (recent antibiotic user and non-user) included all study participants.

2. The null hypothesis is: “There is no difference between antibiotic users and non-users on the presence of antibiotic resistance.”

3. The exact likelihood of obtaining a χ2 value at least as extreme as or as close to the one that was actually observed, assuming that the null hypothesis is true, was 4.0%.

4. The percentage of antibiotic users who were resistant is calculated as 8 ÷ 14 = 0.5714 × 100% = 57.14% = 57.1%.

5. The percentage of non-antibiotic users who were resistant is calculated as 7 ÷ 28 = 0.25 × 100% = 25%.

6. The percentage of antibiotic-resistant veterans who used antibiotics for more than 2 weeks is calculated as 8 ÷ 15 = 0.533 × 100% = 53.3%.

7. The percentage of resistant veterans who had no history of antibiotic use is calculated as 6 ÷ 27 = 0.222 × 100% = 22.2%.

8. The study design in the example was a retrospective comparative design (Gliner et al., 2009).

9. Switching the variables in the SPSS Crosstabs window would have resulted in the exact same χ2 result.

10. The sample size was adequate to detect differences between the two groups, because a significant difference was found, p = 0.04, which is smaller than alpha = 0.05.

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Data for Additional Computational Practice for Questions to be Graded
A retrospective comparative study examining the presence of candiduria (presence of Candida species in the urine) among 97 adults with a spinal cord injury is presented as an additional example. The differences in the use of antibiotics were investigated with the Pearson χ2 test (Goetz, Howard, Cipher, & Revankar, 2010). These data are presented in Table 35-2 as a contingency table.

TABLE 35-2

CANDIDURIA AND ANTIBIOTIC USE IN ADULTS WITH SPINAL CORD INJURIES

Candiduria No Candiduria Totals
Antibiotic use 15 43 58
No antibiotic use 0 39 39
Totals 15 82 97
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EXERCISE 35 Questions to Be Graded
Name: _______________________________________________________ Class: _____________________

Date: ___________________________________________________________________________________

Follow your instructor’s directions to submit your answers to the following questions for grading. Your instructor may ask you to write your answers below and submit them as a hard copy for grading. Alternatively, your instructor may ask you to use the space below for notes and submit your answers online at http://evolve.elsevier.com/Grove/statistics/ under “Questions to Be Graded.”

1. Do the example data in Table 35-2 meet the assumptions for the Pearson χ2 test? Provide a rationale for your answer.

2. Compute the χ2 test. What is the χ2 value?

3. Is the χ2 significant at α = 0.05? Specify how you arrived at your answer.

4. If using SPSS, what is the exact likelihood of obtaining the χ2 value at least as extreme as or as close to the one that was actually observed, assuming that the null hypothesis is true?

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5. Using the numbers in the contingency table, calculate the percentage of antibiotic users who tested positive for candiduria.

6. Using the numbers in the contingency table, calculate the percentage of non-antibiotic users who tested positive for candiduria.

7. Using the numbers in the contingency table, calculate the percentage of veterans with candiduria who had a history of antibiotic use.

8. Using the numbers in the contingency table, calculate the percentage of veterans with candiduria who had no history of antibiotic use.

9. Write your interpretation of the results as you would in an APA-formatted journal.

10. Was the sample size adequate to detect differences between the two groups in this example? Provide a rationale for your answer.

(Grove 409-420)

Grove, Susan K., Daisha Cipher. Statistics for Nursing Research: A Workbook for Evidence-Based Practice, 2nd Edition. Saunders, 022016. VitalBook file.

The citation provided is a guideline. Please check each citation for accuracy before use.

 

Need answers of questions to be graded at the end of each exercise.

Practicum Professional Development Objectives

Section 2: Practicum Professional Development Objectives

Refer to the instructions in Week 1 to create practicum professional development objectives that meet the requirements for this course.

Objective 1: Analyze three common barriers to effective communication, then compare and contrast two effective resolution strategies as defined in evidence-based literature.

Objective 2: Contrast units that have success with retention and recruitment of novice nursing staff and those who have high turnover; identifying factors of influence and comparing to peer reviewed literature.

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Assignment 1:
Practicum Professional Experience Plan (PPEP)Success comes from knowing that you did your best to become the best that you are capable of becoming.
— John Wooden, My Personal Best: Life Lessons from an All-American JourneyAs you considered in this week’s Discussion, your experiences in the practicum can provide a vital avenue for professional development.For this Assignment, you develop a Practicum Professional Experience Plan (PPEP) to outline how your involvement in the practicum will contribute to your growth as a professional and allow you to hone your specialization knowledge and skills. The PPEP consists of two or three objectives related to professional development that you will address during your Practicum Experience.Note: In the practicum manual these are referred to as your individualized learning objectives.To prepare:As necessary, review the information related to developing objectives provided in this week’s Learning Resources.Revisit the objective(s) you crafted for this week’s Discussion, and reflect on the ideas exchanged in this forum. Refine the objective(s) as needed, making sure they reflect the higher-order domains of Bloom’s Taxonomy (i.e., Application level and above). Note: You will be developing two to three professional development objectives for this assignment.Think more deeply about areas for which you would like to gain application-level experience and/or continued professional growth. How can your experiences in the practicum help you achieve these aims?Discuss your professional aims and your proposed practicum professional development objectives with your Preceptor to ascertain if the necessary resources are available at your practicum site.Download and save the Practicum Professional Experience Plan Form provided in this week’s Learning Resources.

To complete your Practicum Professional Experience Plan:Record the required information in each area of the Professional Practicum Experience Plan, including two or three objectives you will use to facilitate your professional development during the practicum.

Objective 3: Develop and prioritize a one-month productivity expense report that will be used to budget upcoming expenditures and incorporate a balanced unit financial statement in accordance with previous budgets and evidence based literature.

Resources

Cipriano, P. F., & Murphy, J. (2011). The future of nursing and health IT: The quality elixir. Nursing Economic$, 29(5), 286–289.
Note: Retrieved from the Walden Library databases. “Technology tools will continue to revolutionize how we plan, deliver, document, review, evaluate, and derive the evidence about care” (p. 289). This article examines how nurses can use information technology to transform nursing and redesign the health care system. It focuses on the use of technology to promote quality and notes that technology can also be used to address challenges in education, research, leadership, and policy.McKimm, J., & Swanwick, T. (2009). Setting learning objectives. British Journal of Hospital Medicine, 70(7), 406–409.
Note: Retrieved from the Walden Library databases. This article clarifies the terminology associated with learning objectives and explains how learning objectives relate to professional development and the transformation from novice to expert. It also introduces common pitfalls when setting learning objectives and provides suggestions for avoiding them.Murphy, J. (2011). The nursing informatics workforce: Who are they and what do they do? Nursing Economic$, 29(3), 150–153.
Note: Retrieved from the Walden Library databases. The author examines the nursing informatics workforce, explaining that professionals in this well-established specialty area can play an integral role in transforming health care.Sørensen, E. E., Delmar, C., & Pedersen, B. D. (2011). Leading nurses in dire straits: Head nurses’ navigation between nursing and leadership roles. Journal of Nursing Management, 19(4), 421–430.
Note: Retrieved from the Walden Library databases. “Successful nursing leaders navigate between nursing and leadership roles while nourishing a double identity” (p. 421). In this article, the authors examine how individuals in key professional roles negotiate between and apply nursing and leadership skills.

Case Study On Death And Dying

The practice of health care providers at all levels brings you into contact with people from a variety of faiths. This calls for knowledge and acceptance of a diversity of faith expressions.

The purpose of this paper is to complete a comparative ethical analysis of George’s situation and decision from the perspective of two worldviews or religions: Christianity and a second religion of your choosing. For the second faith, choose a faith that is unfamiliar to you. Examples of faiths to choose from include Sikh, Baha’i, Buddhism, Shintoism, etc.

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In your comparative analysis, address all of the worldview questions in detail for Christianity and your selected faith. Once you have outlined the worldview of each religion, begin your ethical analysis from each perspective.

In a minimum of 2,000 words, provide an ethical analysis based upon the different belief systems, reinforcing major themes with insights gained from your research, and answering the following questions based on the research:

How would each religion interpret the nature of George’s malady and suffering? Is there a “why” to his disease and suffering? (i.e., is there a reason for why George is ill, beyond the reality of physical malady?)
In George’s analysis of his own life, how would each religion think about the value of his life as a person, and value of his life with ALS?
What sorts of values and considerations would each religion focus on in deliberating about whether or not George should opt for euthanasia?
Given the above, what options would be morally justified under each religion for George and why?
Finally, present and defend your own view.
Support your position by referencing from lectures, the Bible, and the textbooks for each religion. Each religion must have a primary source included.

A total of six references are required according to the specifications listed above. Incorporate the research into your writing in an appropriate, scholarly manner.

Prepare this assignment according to the guidelines found in the APA Style Guide

NO PLAGIARISM PLEASE

Assignment 2

This assignment consists of both an interview and a PowerPoint (PPT) presentation.

Assessment/Interview

Select a community of interest. It is important that the community selected be one in which a CLC group member currently resides. Students residing in the chosen community should be assigned to perform the physical assessment of the community.

  1. Perform a direct assessment of a community of interest using the “Functional Health Patterns Community Assessment Guide.”
  2. Interview a community health and public health provider regarding that person’s role and experiences within the community.

Interview Guidelines

Interviews can take place in-person, by phone, or by Skype. Complete the “Provider Interview Acknowledgement Form” and submit with the group presentation.

Develop one set of interview questions to gather information about the role of the provider in the community and the health issues faced by the chosen community.

Compile key findings from the interview, including the interview questions used, and submit with the group presentation.

PowerPoint Presentation

Within your group, create a PowerPoint presentation of 15-20 slides (slide count does not include title and reference slide) describing the chosen community interest.

Include the following in your presentation:

  1. Description of community and community boundaries: the people and the geographic, geopolitical, financial, educational level, ethnic, and phenomenological features of the community as well as types of social interactions, common goals and interests, barriers, and challenges, including any identified social determinates of health.
  2. Summary of community assessment: (a) funding sources and (b) partnerships.
  3. Summary of interview with community health/public health provider.
  4. Identification of an issue that is lacking or an opportunity for health promotion. The issue identified can be used for the Community Teaching Plan: Community Teaching Work Plan Proposal assignment.
  5. A conclusion summarizing your key findings and a discussion of your impressions of the general health of the community.

In addition to submitting this assignment in the LoudCloud dropbox, email a copy of your submission to RNBSNclientcare@gcu.edu.

While APA style is not required for the body of this assignment, solid academic writing is expected, and documentation of sources should be presented using APA formatting guidelines, which can be found in the APA Style Guide, located in the Student Success Center.

This assignment uses a rubric. Please review the rubric prior to beginning the assignment to become familiar with the expectations for successful completion.

You are not required to submit this assignment to Turnitin.

When submitting this assignment, include the interview questions, the interview findings, completed “Provider Interview Acknowledgement Form,” and the community assessment PPT presentation.

NRS-427V.R.ProviderInterviewAcknowledgementForm_10-14-13.doc NRS427V.R.FunctionalHealthPatternsCommAssessment_Student_10-14-13.doc

Diary Of Medical Mission Trip

Throughout this course, you have viewed the “Diary of Medical Mission Trip” videos dealing with the catastrophic earthquake in Haiti in 2010. Reflect on this natural disaster by answering the following questions:

  1.  Propose one example of a nursing intervention related to the disaster from each of the following levels: primary prevention, secondary prevention, and tertiary prevention. Provide innovative examples that have not been discussed by a previous student.
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  3. Under which phase of the disaster do the three proposed interventions fall? Explain why you chose that phase.
  4. With what people or agencies would you work in facilitating the proposed interventions and why?

Link to the “Diary of Medical Mission Trip” videos:

http://lc.gcumedia.com/zwebassets/courseMaterialPages/nrs427v_nrs427v.php

Assignment 2

Part 1. The Systems Development Life Cycle for Implementation

In a 2-page narrative, address the following:

Explain each step of the systems development life cycle (SDLC) for a nursing informatics project. (1 page)

Explain why nurse leaders should be involved in each step of the SDLC by identifying at least two ways that nurse leaders can contribute to best practices for implementation of nursing informatics projects. Be specific and provide examples. (1 page)
Part 2. Job and Role Description of the Nurse in Systems Development and Implementation

Develop a 1- to 2-page job and role description for a graduate level nurse to guide his/her participation on the implementation team for a new nursing documentation system. The job and role description should be based on the systems development life cycle (SDLC) stages and tasks, and should clearly define how this individual will participate in and impact each of the steps.

Define the role of the nurse in the planning and defining requirements stage of the SDLC. (1–2 paragraphs)
Define the role of the nurse in the analysis stage of the SDLC. (1–2 paragraphs)
Define the role of the nurse in the design of the new system stage of the SDLC. (1–2 paragraphs)
Define the role of the nurse in the implementation stage of the SDLC. (1–2 paragraphs)
Define the role of the nurse in the testing and maintenance stages of the SLDC. (1–2 paragraphs)

Nursing case study analysis

Nursing case study analysis

Question 1 A patient asks the nurse practitioner about food sources such as soybeans and soy products. The nurse practitioner understands that these foods are considered

A) phytoestrogens.

B) monotherapy.

C) taboo.

D) inappropriate

Question 2 A 12-year-old boy is being discharged from the hospital after major surgery. The boy will be taking two medications at home for an extended period. The nurse who is discharging the patient should provide medication teaching specifically to

A) the mother regarding why the boy needs to take the medications.

B) both the boy and his mother regarding all medication issued.

C) the boy by telling him not to worry about the medications and to take them as directed

D) The mother and be sure to reinforce the need to force the medications, if her sondoes not want to take them

Question 3 A 15-year-old boy who has been taking dextroamphetamine for the treatment of ADHD has been experiencing a depressed mood and a sense of hopelessness. He confides in the school nurse that he has begun taking his stepfather’s antidepressant to improve his mood. After immediately phoning the boy’s stepfather, the nurse learns that the drug in question is phenelzine (Nardil), a monoamine oxidase inhibitor (MAOI). The nurse should recognize that this combination of drugs creates a serious risk of what health problem?

A) Cardiac dysrhythmia
B) Hypertensive crisis
C) Nephrotoxicity
D) Hypokalemia

Question 4 A child is admitted to the burn unit with second and third degree burns on both arms and part of his or her face. When administering topical medications to the burned areas, the nurse should

A) cool the medication prior to administration.
B) use sterile technique when applying the medication.
C) allow the child to apply the medication if possible.
D) use clean technique only when applying the medication.

Question 5 A patient is being seen in the emergency department for a sprained ankle and is given a drug to relieve pain. When a second dose of the pain medication is given, the patient develops redness of the skin, itching, and swelling at the site of injection of the drug. The most likely cause of this response is

A) a hepatotoxic response.
B) an idiosyncratic response.
C) a paradoxical response.
D) an allergic response.

Question 6 A 5-year-old boy needs an IM injection. The least painful and most effective injection site would be the

A) deltoid muscle.
B) rectus femoris muscle.
C) ventrogluteal muscle.
D) dorsogluteal muscle.

Question 7 A patient reports to a clinic with complaints of breast tenderness, a right lumpy breast, and no breast discharge. The breast tenderness occurs primarily during her menstrual cycle. The nurse practitioner probably suspects

A) breast cancer

B) PMS

C) pain in the heart

D) cancerous breast tenderness

Question 8 A 29-year-old woman who is morbidly obese has recently begun a comprehensive, medically-supervised program of weight reduction. Prior to adding dextroamphetamine (Dexedrine) to her regimen, the patient should be questioned about her intake of

A) alcohol.
B) trans fat.
C) caffeine.
D) grapefruit juice.

Question 9 A nurse is caring for a 10-year-old boy who complains of chronic headaches. His mother reports that she gives him Tylenol at least three times a day. Which of the following will the nurse work with the physician to evaluate?

A) Renal function
B) Hepatic function
C) Respiratory function
D) Cardiac function

Question 10 A 21-year-old female has a history of irregular menses. She recently became sexually active, and would like to begin taking oral contraceptives (OCs). The nurse practitioner recognizes that most likely this patient would benefit from taking which category of OCs.

A) Monophasic

B) Triphasic OC

C) Ortho Tri-Cyclen

D) Biphasic OC

Question 11 A nurse who provides care on a pediatric medicine unit has conducted a medication reconciliation of a recently-admitted patient. In light of the fact that the child takes methylphenidate (Ritalin), the nurse is justified in considering a history of what health problem?

A) Anxiety
B) Respiratory depression
C) Obesity
D) ADHD

Question 12 A nurse working in a cancer center is preparing to administer medication to a 5-year-old child. The nurse will calculate the drug dosage by using

A) body surface area.
B) weight.
C) age in months.
D) age in years.

Question 13 A 13-year-old female took a weight loss drug that activated the sympathetic nervous system. Which of the following assessment findings would the nurse expect?

A) Decreased myocardial contraction
B) Decreased heart rate
C) Increased cardiac conduction
D) Increased intranodal conduction time

Question 14 A 6-month-old child has developed skin irritation due to an allergic reaction. He has been prescribed a topical skin ointment. The nurse will consider which of the following before administering the drug?

A) That the infant’s skin has greater permeability than that of an adult
B) That there is less body surface area to be concerned about
C) That there is decreased absorption rates of topical drugs in infants
D) That there is a lower concentration of water in an infant’s body compared with an adult

Question 15 A nurse is providing patient education to a 13-year-old girl who was just diagnosed with type 1 diabetes mellitus. Which of the following statements by the patient will alert the nurse that special instructions regarding insulin are necessary?

A) “I walk two blocks to school every day.”
B) “I am on the middle school track team.”
C) “We live in a two-story house.”
D) “My mother is going to give me my insulin.”

Question 16 A nurse who provides care on a pediatric unit of a hospital is aware that the potential for harm as a result of drug errors is higher among infants and children than adults. This fact is primarily due to

A) the inability of infants and children and describe symptoms of adverse drug reactions.
B) increased body surface area relative to body volume in infants and children.
C) increased heart rate and subsequently rapid drug distribution among infants and children.
D) immature liver and kidney function in infants and children.

Question 17 A nurse practitioner orders 150 mg of oral fluconazole for a patient with vulvovaginal candidiasis. The patient should expect to take medication

A) for 20 days.

B) once a day.

C) every day until the infection is gone.

D) for 30 days.

Question 18 To which of the following patients would a medication nurse most likely administer caffeine as part of the treatment plan?

A) A preterm neonate who has apnea
B) A 34-year-old woman with a diagnosis of gastric ulcerations
C) A school-age child with severe ADHD
D) A 52-year-old man with narcolepsy

Question 19 A nurse works at a weight management clinic. To which of the following overweight patients could the nurse safely administer dextroamphetamine?

A) A 38-year-old Caucasian woman with glaucoma
B) A 60-year-old African-American man who experiences angina
C) A 48-year-old Caucasian man who has adult-onset diabetes
D) A 28-year-old African-American woman with hyperthyroidism

Question 20 A 3-year-old boy has developed otitis media and requires antibiotics. In order to increase the chance that the boy will take his prescribed medication, the nurse should

A) teach the boy about the fact that he will feel much better after he takes his medications.
B) have the mother hold the child firmly and sooth him while the drugs are administered.
C) offer a choice between liquid and chewable medications, if possible.
D) insert a central intravenous line.

Question 21 The recommended treatment for trichomoniasis is

A) Flagyl.

B) Diflucan.

C) Meclizine.

D) Amoxicillan

Question 22 A school nurse has been teaching high school students about the risks associated with marijuana use. However, the nurse has been met with considerable skepticism on the part of students, most of whom believe that marijuana is a benign drug. Which of the following teaching points should the nurse provide?

A) “Most people don’t know that marijuana can be just as addictive as heroin or cocaine over time.”
B) “Marijuana can easily interact with other drugs and cause potentially fatal reactions.”
C) “Every year, thousands of Americans end up in emergency departments with marijuana overdoses.”
D) “Smoking marijuana is just as bad, or worse, for your lungs as smoking cigarettes.”

Question 23 A nurse is going to administer medication to an infant using a medicine dropper. The best method is to open the child’s mouth by gently squeezing the cheeks and placing the drops

A) at the back of the mouth.
B) in the buccal pouch.
C) under the tongue.
D) on top of the tongue.

Question 24 A nurse is obtaining baseline physical data from a 7-year-old patient who is to be started on dextroamphetamine for ADHD. After obtaining vital signs, height, and weight, the nurse will prepare the patient for an

A) electrocardiogram (ECG).
B) electromyelogram (EMG).
C) electroencephalogram (EEG).
D) electrophysiologic study (EPS).

Question 25 A 10-year-old boy is taking dextroamphetamine (Dexedrine) daily for ADHD. At each clinic visit, the nurse’s priority assessment would be

A) height and weight.
B) Vision.
C) body temperature.
D) blood pressure.

Question 26 A 7-year-old child has been taking tetracycline for a bacterial infection. The nurse will be sure to inform the parents that this drug could cause

A) orange-tinged urine.
B) staining of permanent teeth.
C) sleep deprivation.
D) deep muscle pain.

Question 27 A nurse is administering drugs to a 10-year-old child who has multiple health problems.The child is underweight and is on a special diet. Which of the following will the nurse consider when planning for the best absorption of the prescribed drugs? (Select all that apply.)

A) Age
B) Weight
C) Disease process
D) Diet
E) Route of administration

ACDE

Question 28 The clinical nurse educator who oversees the emergency department in a children’s hospital has launched an awareness program aimed at reducing drug errors. What measure addresses the most common cause of incorrect doses in the care of infants and children?

A) Having nurses check their math calculations with a colleague before administering a drug.
B) Ensuring that a full assessment takes place no more than 30 minutes before giving a drug.
C) Recording drug administration in both the nurse’s notes and the medication administration record (MAR)
D) Avoiding intravenous administration of drugs whenever possible.

Question 29 A 15-year-old boy has been diagnosed with bone cancer after several months of fatigue and pain. What question should the nurse include in an assessment when trying to minimize the potential for adverse drug reactions?

A) “Do you ever use alcohol or drugs?”
B) “How much do you weigh?”
C) “On a scale of zero to ten, what level of pain is acceptable to you?”
D) “Did Tylenol or other over-the-counter pain remedies ever relieve your pain?”

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Question 30 A 35-year-old woman is on a weight-loss program and is to begin taking sibutramine (Meridia). After baseline physical data are obtained, the nurse will assess the patient’s childbearing potential. The nurse will inform the patient that during sibutramine therapy she should

A) abstain from sex.
B) obtain a pap smear .
C) use adequate contraception.
D) take a pregnancy test every month.

Question 31 A 16-year-old boy is prescribed cromolyn sodium nasal spray to treat a nasal allergy. To maximize the therapeutic effects of the drug, which of the following will the nurse include in instructions to the patient?

A) Take the drug on a full stomach
B) Avoid high noise levels
C) Take the drug for one full week before coming in contact with allergens
D) Drink plenty of fluids.

Question 32 A 19-year-old patient reports to a clinic with vaginal discharge with a foul odor. A microscopic exam reveals trichomonas vaginalis.The nurse practitioner is aware that

A) trichomoniasis is an incurable disease.

B) trichomoniasis discharge is typically thin and clear.

C) asymptomatic women are diagnosed with trichomoniasis by a routine pap smear.

D) it is unusual to have an odor with trichomoniasis

Question 33 A 2-year-old child is diagnosed with a minor ailment and is to be administered medications at home for 2 weeks. The child lives with his mother, grandmother, and four other children between the ages of 14 months and 7 years. The home health nurse is asked to assess the home environment to determine if it is appropriate for the child to take his medication at home. Which of the following will have the greatest impact on the nurse’s assessment?

A) The mother and grandmother’s understanding about the drugs
B) How clean the house is
C) The health status of the other children
D) Where the medications will be stored

Question 34 A nurse is having difficulty administering a bitter drug to a 5-year-old child. The nurse should

A) have the parent gently force the child’s mouth open.
B) give the drug in a pill form.
C) involve the child in a play therapy session, and then tell the child that the medicine is candy.
D) offer the child a flavored ice chip or ice pop prior to administering the drug.

Question 35 A 22-year-old woman has given birth to an infant who exhibits the signs and symptoms of maternal cocaine use during pregnancy.These signs and symptoms are a result of what pathophysiological effect of opioid use during pregnancy?

A) Changes in blood chemistry as a result of nephrotoxicity and hepatotoxicity
B) Impaired maternal nutrition as a result of drug use
C) Vasoconstriction leading to reduced placental blood flow
D) Hypoxia as a result of a prolonged second stage of labor

Question 36 A preterm neonate received caffeine for the treatment of apnea. The nurse should monitor the neonate for which of the following?

A) Bloody stools
B) Bradycardia
C) Constipation
D) Hypoglycemia

Question 37 A 30-year-old man with a BMI of 59 has recently been diagnosed with type 2 diabetes mellitus. In light of the man’s lack of success with weight loss programs in the past, his care provider has prescribed sibutramine (Meridia). What instructions should the nurse consequently provide to this patient?

A) “Take this drug once each day on an empty stomach.”
B) “It’s best to take a dose of sibutramine after each meal.”
C) “This drug will help you to lose weight without having to exercise or change your normal diet.”
D) “Take a dose when you feel like you are tempted to binge on food.”

Question 38 A nurse practitioner orders a single dose of 2 g Metronidazole orally. How many milligrams will the patient receive in one dose?

A) 1000 mg

B) 2000 mg

C) 3000 mg

D) 4000 mg

Question 39 A nurse is explaining to the parents of a 6-year-old child suffering from angina why nitroglycerin patches for chest pain would not be appropriate. Which of the following will the nurse include in an explanation?

A) A child has an erratic blood flow from an immature peripheral circulation, which increases drug absorption, causing an increase in adverse effects.
B) A child’s gastric pH is decreased, causing less of the drug to be absorbed from the subcutaneous skin, therefore producing more adverse effects.
C) A child has a greater body surface area, creating greater permeability resulting in an increase in absorption of topical agents, which may result in more adverse effects.
D) A child has a smaller body surface area, resulting in an increase in topical absorption, which can cause more adverse effects.

Question 40 An immunocompromised 7-year-old child was recently discharged home with a peripherally-inserted central line (PIC line) for home antibiotic therapy. He has now been brought to the emergency department by his mother and father with signs and symptoms of line sepsis.Upon questioning, the mother states that she has been removing the PIC dressing daily and washing the site with warm water and a cloth. What nursing diagnosis is most appropriate in this situation?

A) Caregiver Role Strain
B) Ineffective Family Therapeutic Regimen Management
C) Delayed Growth and Development
D) Knowledge Deficit

Financial Statement Analysis in health care

Financial Statement Analysis in health care
Due Week 4 and worth 200 points

Select one (1) of the following publically traded health care organizations: Universal Health Services (NYSE: UHS) or Health Management Associates (NYSE: HMA).

Suppose you are a newly appointed CFO of your chosen health care organization. One of your first tasks is to conduct an internal financial analysis of the organization. Conduct a brief financial analysis and review of the chosen company’s financial statements for at least three (3) consecutive years. After conducting the analysis, interpret the data contained within the statements.

Write a three to four (3-4) page paper in which you:

  1. Based on your review of the financial statements, suggest a key insight about the financial health of the company. Speculate on the likely reaction to the financial statements from various stakeholder groups (employee, investors, shareholders). Provide support for your rationale.
  2. Identify the current industry trend that has the most significant impact on your chosen organization’s financial performance. Indicate the trend’s impact on the financial performance of the organization. As the CFO, suggest at least one (1) way that you might minimize the impact of the trend on the organization.
  3. As the CFO, suggest one (1) key strategy that you might use in order to improve the financial performance of the organization. Recommend an approach to implement the suggested strategy. Provide support for your recommendation.
  4. Use at least four (4) quality academic resources. Note: Wikipedia and other Websites do not qualify as academic resources.
  5. https://eazyweezyhomeworks.com/order/

Your assignment must follow these formatting requirements:

  • Be typed, double spaced, using Times New Roman font (size 12), with one-inch margins on all sides; citations and references must follow APA or school-specific format. Check with your professor for any additional instructions.
  • Include a cover page containing the title of the assignment, the student’s name, the professor’s name, the course title, and the date. The cover page and the reference page are not included in the required assignment page length.

The specific course learning outcomes associated with this assignment are:

  • Evaluate the financial statements and the financial position of health care institutions.
  • Analyze the role of important financial reporting statements – income statement, balance sheet, and statement of cash flows – and explain how they relate to one another and to the underlying sources of data.
  • Use technology and information resources to research issues in health financial management.
  • Write clearly and concisely about health financial management using proper writing mechanics.