Premature infants frequently require supplemental oxygen to sustain life, but little is known  about how supplemental oxygen administered during the critical developmental window after  birth increases the risk of age-related disease, including obesity and diabetes. We  hypothesized that neonatal rats exposed to supplemental oxygen (OXY) would have  impaired glucose tolerance and that they would develop a diabetes phenotype earlier than  controls (CON), when offered a high fat diet. We used an established rat model of neonatal  oxygen exposure (80% O2 for 8-14 days) and glucose tolerance was evaluated 14 days and  12 months post-natally. To evaluate glucose tolerance, baseline blood glucose was  measured after an overnight fast, followed by an intraperitoneal injection of concentrated  glucose. Blood glucose was then measured 15, 30, 60 and 120 minutes post-injection. In a  second experiment, two month old OXY and CON rats were randomly assigned to an  animal-based fat diet (60% of calories from fat), or standard, low fat diet for ten weeks. At  the beginning of the study and each subsequent week, glucose tolerance was measured. At  14 days and 12 months, OXY rats had higher blood glucose at 15 and 30 minutes compared  to CON rats. OXY rats fed a high fat diet developed frank glucose intolerance after 4 weeks.  Ten weeks of high fat diet had minimal effect on glucose tolerance in CON rats. Taken  together, these data suggest that supplemental oxygen during the neonatal period may predispose  the premature infant to the development of metabolic disease later in life

Bates, Melissa L

Chandrasekar, Shreya

Hoover, Michael

Leuhrs, Rachel

Murphy, Austin

Sturgeon, Madison E

Vellookunnel, Shilpa

English

Iowa Research Online

Honors Theses at the University of Iowa 
Spring 2017 
Neonatal Supplemental Oxygen Exposure Promotes the 
Development of Metabolic Disease in Adult Rats 
Madison E. Sturgeon 
University of Iowa 
Michael Hoover 
University of Iowa 
Rachel Leuhrs 
University of Iowa 
Shilpa Vellookunnel 
University of Iowa 
Shreya Chandrasekar 
University of Iowa 
See next page for additional authors 
Follow this and additional works at: https://ir.uiowa.edu/honors_theses 
 Part of the Biochemical Phenomena, Metabolism, and Nutrition Commons 
This honors thesis is available at Iowa Research Online: https://ir.uiowa.edu/honors_theses/90 
NEONATAL SUPPLEMENTAL OXYGEN EXPOSURE PROMOTES THE DEVELOPMENT OF 
METABOLIC DISEASE IN ADULT RATS 
by 
Madison E. SturgeonMichael HooverRachel LeuhrsShilpa VellookunnelShreya 
ChandrasekarAustin MurphyMelissa L. Bates 
A thesis submitted in partial fulfillment of the requirements 
for graduation with Honors in the Health and Human Physiology 
________________________________________________ 
Melissa L. Bates 
Thesis Mentor 
Spring 2017 
All requirements for graduation with Honors in the 
Health and Human Physiology have been completed. 
________________________________________________ 
Gary Pierce 
Health and Human Physiology Honors Advisor 
This honors thesis is available at Iowa Research Online: https://ir.uiowa.edu/honors_theses/90 
Neonatal Supplemental Oxygen Exposure Promotes the Development of Metabolic Disease 
in Adult Rats 
 
Madison Sturgeon, Michael Hoover, Rachel Luehrs, Shilpa Vellookunnel, Shreya 
Chandrasekar, Austin Murphy, and Melissa L. Bates 
 
Department of Human Physiology, University of Iowa, Iowa City, IA 
 
Background 
The survival rate for prematurely born (<37 weeks gestation) babies has increased 
dramatically in the past 25 years, resulting in a large population of prematurely born adults. 
Since then, these preterm babies have been commonly treated with supplemental oxygen (>80%) 
immediately after birth, during the critical window of development. Supplemental oxygen 
treatment facilitates oxygen diffusion in the undeveloped lungs of the prematurely born infant, 
and assists synthesized surfactant to allow for survival.  
The long-term effects of this early life exposure are poorly understood, and are becoming 
increasingly relevant with the growth in the affected population. While it is well-established that 
oxygen exposure causes damage to the eyes and lungs of the premature infant, there is a need for 
information about the effects of supplemental oxygen on other physiological processes, including 
metabolism. Adults born prematurely are at an increased risk of obesity and diabetes (4).  
Emily Farrel, et. al collected additional supporting information in the study titled, 
Pulmonary Gas Exchange and Exercise Capacity in Adults Born Preterm (3). This study 
provided information about the subclinical disadvantage experienced by adults born prematurely 
under exercise conditions. Adults born prematurely consumed the same amount of oxygen, but 
had a lower power output during a high-intensity exercise session.  
The goal of this study was to understand the impact of supplemental oxygen exposure in 
the neonatal period on metabolic function. There were several ways to investigate this question, 
but the most effective and informative experiment at this juncture was to focus on the 
development of a diabetic phenotype. To answer our questions, we used a well-established rat 
model of premature birth in which newborn rats were exposed to supplemental oxygen for the 
first 14 days after birth. We hypothesized that exposure to supplemental oxygen immediately 
after birth caused impairments in the response to a glucose challenge, and that these rats 
developed a diabetes phenotype earlier than controls when offered a high fat diet. As secondary 
endpoints, we also evaluated weight gain and food intake in this model. 
Methods 
Pregnant Sprague-Dawley rats were obtained in pairs from Charles River. At the time of 
delivery, one dam was placed in a plexiglass environmental cabinet containing 80% O2 (OXY) 
and the other was placed in a cabinet containing 21% O2, as a control (CON). Pups were 
maintained in the chambers for 14 days. Dams were offered standard chow and water, as well as 
water ad libitum, and rotated daily to prevent hyperoxic lung injury. Post exposure, all rats were 
returned to standard housing. 
Experiment 1 – Baseline Glucose Tolerance: At 14 days and 12 months post-exposure, glucose 
tolerance was evaluated in OXY and CON rats. These rats were fasted for eight hours, then 
baseline glucose was measured using a standard, clinical glucose meter. Blood was taken from 
the tails of OXY and CON rats. An intraperitoneal injection of glucose was administered (3g/kg, 
time = 0 minutes), followed by glucose monitoring at set time points. Specifically, these time 
points were: 15 minutes, 30 minutes, 60 minutes, and 120 minutes post-administration. Then, 
rats were returned to normal housing.  
Experiment 2 – High Fat Diet: Eight-week-old OXY and CON rats were randomly assigned to a 
high fat diet, with 60% of calories from animal fat, or to a control diet for nine weeks. Total body 
weight and food intake was measured 5 days a week for all subjects. Once per week for eight 
weeks, fasting blood-glucose measurement was measured, followed by a glucose tolerance test, 
as described above. Plasma insulin concentration was measured every three weeks, 30 minutes 
after glucose injection. 
Data Analysis: Results were analyzed with a repeated measures, nested general linear model 
(Minitab, Stat College PA) where the animal was nested in the condition. Post hoc comparisons 
were completed with a Dunnett test where the 21% control chow group was designated as the 
control. Significance was considered when p<0.05. 
Results 
 
Groups with 21% oxygen exposure exhibit an expected blood-glucose concentration 
curve, rising after glucose administration and returning to baseline around 120 minutes (3). 
Analysis of blood glucose concentration at each time point during the glucose tolerance tests 
shows statistically significant difference at 15 minutes, 30 minutes, and 60 minutes between 
groups of different oxygen exposure. Concentration is significantly higher in the group with 80% 
supplemental oxygen exposure during the glucose tolerance test. Baseline and final 
concentrations are similar between oxygen exposure groups on the same diet.  
Figure 1: Blood glucose concentration 
versus time points during glucose tolerance 
tests. This data has been analyzed using a 
repeated measures ANOVA test, 
considering age, oxygen exposure groups, 
and time. Age groups were combined.  
  
 Figure 2 displays the cumulative weight gain for all groups, in which both high fat diet 
groups follow a similar pattern. Rats under the 80% control chow condition also gained more 
weight than their 21% exposed control chow counterparts. Statistical analysis of all groups 
revealed significance in all groups compared to the 21% control chow group.  
 
 Weight gain efficiency is plotted for the duration of the nine-week protocol in Figure 3, 
where weight gain efficiency is determined in kilocalories consumed per gram of total body 
weight each day. All treatment groups exhibit similar patterns for all nine weeks, and no 
significance was found (p>0.05).  
                         
 Figure 4: Average blood-glucose concentration difference between the 120-minute time point 
and the baseline measurements per week for rats exposed to 21% (Figure 2.A) and 80% (Figure 
2.B) neonatal oxygen as compared to the value calculated for the first week of the protocol. 
Groups are divided by assigned diet. 
A B 
Figure 2: Average cumulative weight gain 
of rats over the course of the nine-week 
protocol. Groups are divided by oxygen 
exposure and diet. 
Figure 3: Comparison of caloric 
consumption per weight gained on a 
daily basis averaged across each 
week of the protocol. Each group is 
defined by oxygen exposure and diet. 
 
In Figure 4, the difference in blood-glucose concentration at time = 0min and time = 
120min during a standard, fasted glucose tolerance test as compared to the value calculated for 
the first week increased significantly in the 80% exposed high fat diet group (p=0.003) when 
compared to the control group (21% exposed, control chow). The 120min-0min difference of the 
21% exposed high fat diet group is trending toward being increased from the control, but is not 
significant. The 80% exposed control chow group is not significantly different from the control.  
Discussion 
The results of this study have illuminated the way supplemental oxygen exposure in the 
neonatal period impacts metabolic function through discovery of differences in glucose handling 
and weight gain. One portion of the study analyzed the difference between 21% and 80% 
oxygen-exposed rats of different ages. Another part of the study was the effects of a high fat diet 
in combination with 21% and 80% oxygen exposure. Finally, weight gain was recorded and 
displayed in Figure 2 as an additional measure of metabolism. These findings are an important 
part of understanding the health and well being of a new population of people that have only 
recently begun to reach adulthood, and could have an impact on how adults born prematurely are 
treated for metabolic diseases such as diabetes.  
How does neonatal supplemental oxygen impact glucose tolerance? Because a 
statistically significant increase in blood-glucose concentration was observed at the 15, 30, and 
60 minute time points, evaluation of glucose tolerance curves in Figure 1 suggests that neonatal 
80% supplemental oxygen affects the response to a glucose challenge in rats regardless of age. 
While this fact alone does not constitute a diabetic phenotype, it does indicate improper handling 
of glucose and hyperglycemia at these points, which can cause damage to internal organs if 
sustained. The fact that there was no statistical difference between the 14-day-old and 12-month-
old rats indicated that supplemental oxygen exposure causes immediate and sustained metabolic 
impairments. These results also justified further inquiry into the effects of a high fat diet in 
addition to oxygen exposure on the development of a diabetic phenotype, to see if this diet would 
exacerbate the improper handling of glucose.  
How does the combination of high fat diet and supplemental oxygen affect weight gain? 
All non-control (21% high fat diet, 80% high fat diet, and 80% control chow) groups in the 
protocol experienced statistically significant weight gain as compared to the 21% control chow 
group. Cumulative weight data is provided in Figure 2 and it shows that the high fat diet groups 
were similar between the two oxygen exposure conditions. However, there is a significant 
difference between the 80% and 21% control chow groups, indicating that supplemental oxygen 
can cause additional weight gain between subjects on the same diet. In order to understand the 
factors that contribute to this excessive weight gain, we evaluated the kilocalories consumed per 
gram of body weight per day between the four groups in Figure 3. This weight gain efficiency 
was not significantly elevated or depressed in any one group, leaving the conclusion that the 80% 
exposed control diet group was hyperphagic compared to the control chow 21% exposed group. 
Other studies, such as that performed by Archer et al. with adult Sprague-Dawley rats on a high 
fat diet show that the rats gained a maximum average total body weight of 600 to 700 grams, 
which is consistent with our findings (1). It is therefore possible that the two high fat diet groups 
have such similar cumulative weight gain because the rats were physically incapable of gaining 
more weight than they did during the protocol. 
How does a high fat diet in addition to neonatal oxygen exposure impact glucose 
handling? Impaired glucose tolerance is expressed by the failure of blood-glucose concentration 
to return to a similar level as the baseline measurement (2). In Figures 4.A and 4.B, the 
difference between concentration at the 120 minute time point and the baseline measurement is 
compared to the value calculated for the first week of the study to express changes across the 
nine week protocol. Increased changes from the initial 120min-0min calculation suggest that 
glucose handling is becoming more impaired as the blood-glucose concentration fails to return to 
original levels by larger margins after a glucose challenge, ultimately leading to hyperglycemia. 
As seen in Figure 4, rats exposed to 80% oxygen and put on a high fat diet began to display 
significant improper glucose handling after four weeks, as compared to the control group. The 
80% control chow group and 21% exposed high fat diet both did not exhibit significantly higher 
120-0min blood-glucose change across the nine-week protocol. However, the 80% oxygen 
exposed rats given the high fat diet group did display significant hyperglycemia by the end of the 
protocol.  It is therefore reasonable to conclude that the relation between the supplemental 
oxygen exposure and the high fat diet is responsible for the improper glucose response.  
What can be done in the future to further this study? As of now, hyperglycemia has been 
established in subjects exposed to supplemental oxygen during the critical developmental 
window, but a true diabetic phenotype will require analysis of plasma insulin activity. 
Examination of GLUT4 receptors will expose the effectiveness of glucose uptake at the receptor 
level in subjects with oxygen-exacerbated impaired glucose, as well. Pancreatic RNA-
sequencing will illuminate the protein synthesis in rats with impaired glucose response as well, 
which will provide understanding of pancreatic function. This study has also established the 
effect of supplemental oxygen on weight gain, but further investigation into the body 
composition of subjects under these conditions will confirm or deny the presence of enhanced 
adiposity.  
What does this study mean from a clinical perspective? Neonatal supplemental oxygen 
clearly creates adverse effects on glucose handling and weight gain, but it is also necessary for 
facilitating oxygen diffusion for infants born before 37 weeks gestational age. The aim of our 
study has been to determine the development of a diabetic phenotype, and going forward is to 
continue this pursuit and to determine the mechanism by which hyperglycemia and enhanced 
adiposity occurs in the face of supplemental oxygen and a high fat diet. From there, prematurely 
born adults will not only be able to make informed decisions about their health, but we will be 
much closer to finding potential additional treatments to reduce the impairments caused by 
supplemental oxygen exposure.  
References 
1. Archer, Z. A., Rayner, D. V., Rozman, J., Klingenspor, M. and Mercer, J. G. (2003), 
Normal Distribution of Body Weight Gain in Male Sprague-Dawley Rats Fed a High-Energy 
Diet. Obesity Research, 11: 1376–1383. doi:10.1038/oby.2003.186 
2. Ernsberger P and Koletsky RJ. The glucose tolerance test as a laboratory tool with 
clinical implications. Research Gate 2012.  
3. Farrell ET, Bates ML, Pegelow DF, Palta M, Eickhoff JC, O'Brien MJ, and Eldridge 
MW. Pulmonary Gas Exchange and Exercise Capacity in Adults Born Preterm. Annals of the 
American Thoracic Society 2015. 
4. Thomas EL, Al Saud NB, Durighel G, Frost G, and Bell JD. The effect of preterm birth 
on adiposity and metabolic pathways and the implications for later life. Clinical Lipidology 7: 
275-288, 2012. 
 


Neonatal Supplemental Oxygen Exposure Promotes the Development of Metabolic Disease in Adult Rats

https://ir.uiowa.edu/cgi/viewcontent.cgi?article=1111&amp;context=honors_theses

Neonatal Supplemental Oxygen Exposure Promotes the Development of Metabolic Disease in Adult Rats

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