Category Archives: Medicine

Follow Dr. Chris around the world for insight from a physician’s perspective

Acclimation, Altitude Science, Athletic Training, Exposure, Health, High Altitude, High Altitude Training & Fitness, Hyperbaric Therapy, Uncategorized, Wildlife

Of Mice & Men at Altitude: This Podcast Will Kill You, Episode 115 “Altitude Sickness: Balloons, though?’

Leave a comment

This comprehensive review of the biology, history and physiology of high elevation starts with a fatal hot air balloon ride that happened in 1875. The passengers went past 8,000 meters, or over 26,000 feet and lost consciousness. The balloon failed and fell to the ground but not until after the altitude related hypoxia killed two out of the three passengers. Currently the legal limit in many parts of the world for how high a hot air balloon can fly is around 3,000 feet.

The pressure the atmosphere exerts on our bodies, the barometric pressure, that is the pressure of all gasses including oxygen, decreases as we go higher in altitude. As seen in the graph below, the higher you go, the less barometric pressure. This leads to a decrease in the partial pressure of oxygen. The percentage of air that contains oxygen is 21% at any height. However, the oxygen molecules are less dense higher up so with every breath our bloodstream gets less oxygen which is called hypoxemia. Our tissues then get less oxygen as well which is called hypoxia.

Our bodies go through a process called acclimatization to help us adjust to these changes at altitude. The first change we see is increased ventilation. The decrease in oxygen stimulates chemoreceptors in our aorta and carotid which then regulate the depth and rate of our breathing, making our breaths deeper and faster to try and get more oxygen in. This involuntary action is called the hypoxic ventilatory response (HVR). There is an inverse relationship between carbon dioxide and oxygen in the alveoli of our lungs. Since we breathe deeper and faster at altitude we breathe out more carbon dioxide, hence increasing the partial pressure of oxygen. Discussions about carbon dioxide, how it affects the kidneys, what happens to hemoglobin, cardiac output, are very helpful for a deeper understanding of what happens in the body at altitude.

There are three major illnesses that can occur when our bodies do not go through acclimatization properly: acute mountain sickness (AMS), high altitude cerebral edema (HACE), and high altitude pulmonary edema (HAPE). AMS is the most common. It is seen within 4-12 hours of ascending to altitudes higher than 2500 meters. A headache is needed to diagnose AMS in most scoring systems used for diagnosis, other symptoms include GI symptoms, dizziness, fatigue, and sleep disturbances. HACE is a progression of these symptoms. It is dangerous since as the name implies it is cerebral edema or swelling. There may be signs of altered mental status, ataxia, and can progress to coma and death within 24 hours. According to the blog there is not much understanding/consensus of which part of the acclimatization process goes wrong to cause these potentially fatal  outcomes, nor is there a clear answer about whether you can have one without the other. The onset of HAPE is slower, occurring between 1-5 days, rarely after a week. There are more pulmonary symptoms as the name suggests such as excessive shortness of breath, chest tightness, cough, sputum production. The podcast discusses in detail theories about the causes of HAPE.

The history of altitude sickness goes back to Ancient Chinese, Greek and Roman medical texts. “The ancients also observed that the rarity of the air on the summit of Olympus was such that those who ascended it were obligated to carry sponges moistened with vinegar and water and to apply them now and then to their nostrils as the air was not dense enough for their respiration.” This suggested they believed there was no water vapor in the air at high altitudes making it difficult to breathe. Some other texts mentioned “headache mountains” suggesting the naming of mountains based on side effects they experienced at these high altitudes.

The podcast hosts reviewed landmark experiments showing the effects of hypoxia on people and animals. Robert Boyle and Robert Hooke’s experiments using an air pump to investigate an animal’s response to different air pressures. Results showed that survival was shortened at lower pressures. Hook also created a decompression chamber so humans could test low pressure effects. He personally sat in there for 15 minutes at 570 torr, the equivalent of 7,800 ft (2400 m), and experienced some hearing loss. Anton Lavoisier performed another experiment, he compared blood that passed through the lungs with fresh air with venous blood. Freshly ventilated blood was bright red and venous blood was darker red, suggesting something changes in our blood when having contact with fresh air. Another scientist, Mayow, put a mouse on a stool inside of a bowl of water then covered it with a glass bell, creating a sealed environment. The same thing was done with a candle.

Results were that the water levels inside the bell rose as the animal breathed or as the candle burned, suggesting the mouse or the flame was consuming some part of the air which the water came in to fill. He demonstrated there must be at least two different components in air, one of them being necessary for both animal respiration and combustion. Later on he also suggested this “component” is taken up by the lungs and passed into the blood where it is involved during heat production and muscle movement, explaining why breathing increases during exercise, as we need more of this substance in the air to move.

Mountaineering and hot air balloons led to further understanding during the 1700 and 1800s. Paul Bert used animals in hypobaric chambers, simulating the low pressure of high altitude. He found that illness and death always occurred at a certain level of blood oxygen. The same thing happened when air pressure was kept at sea level but the overall oxygen concentration was lowered. Bert also suspected that people and animals at high altitude produce more red blood cells for increased oxygen absorption. Now we know this is true. Plasma volume drops 15-25% which causes a rise in the concentration of hemoglobin. This occurs within around 1-2 days of ascent to altitude. This triggers erythropoietin which stimulates red blood cell production. However, this occurs over days or weeks. So if you are at high altitude for less time your body will not get to this step. (Read “Red Flags At Altitude blog about lab values seen in the patient portal).

To understand altitude effects many researchers now study small animals.  The highest mammal is the yellow-rumped leaf-eared mouse, at 21,000 ft, studied by Jay Storz and colleagues. North American deer mice are the only mammals above tree line in the Rocky Mountains.  University of Denver Assistant Professor of Biology Jon Velotta does studies comparing these high dwellers to their lower altitude cousins. With colleagues Catie Ivy andGraham Scott they were able to show that the breathing rate, red blood cells and hemoglobin increase proportionately to decreasing partial pressures of oxygen.

Anyone interested in the nitty gritty of altitude will learn from this podcast, as well as many other medical topics covered by Colorado-based hosts Erin Allmann Updike MD, PhD and epidemiologist and Erin Welsh PhD disease ecologist and epidemiologist.  Each podcast is accompanied by original recipes for a themed cocktail and nonalcoholic drink.

Claudia Ismerai Reyes is a PA student at Red Rocks Community College in Arvada, Colorado. She grew up in Phoenix, Arizona and went to Arizona State University to get her bachelor’s degree in biology. The first in her family to graduate college. She moved to Colorado a little over five years ago and worked as a CNA at Denver Health for over two years before getting into PA school. In her free time, she likes to watch movies with her husband, trying new places to eat, or playing board games at home. 

Acclimation, Altitude Science, Athletic Training, Child Growth & Development, Health, High Altitude, High Altitude Training & Fitness, Neonatal

Maternal Exercise and Its Effect on the Development of High-Altitude Pulmonary Hypertension in Children

Leave a comment

by Julia Wu, PA-S

Every newborn I have managed while rotating at Ebert Family Clinic in Frisco, Colorado at 9000′ has needed oxygen supplementation. It is known that at high altitudes, there is a lower oxygen concentration in the air, which poses challenges to our bodies. What exactly happens, and what are the consequences of chronic high-altitude exposure? There are approximately 140 million people that live at high altitudes, defined as at least 2500 meters above sea level, who are affected by chronic hypoxic conditions.1 In this article, I will focus on how hypoxia — low levels of oxygen in the blood — affects pregnant women, alters fetal to newborn transition and development, and whether cardiorespiratory exercise by mothers during pregnancy can prevent diseases such as high-altitude pulmonary hypertension (HAPH) development in offspring.  

Pulmonary hypertension (PH) is abnormally high blood pressure in the pulmonary arteries. PH is classified into 5 groups based on the cause. High-altitude pulmonary hypertension (HAPH) is Group III PH and defined as mean pulmonary arterial pressure (PAP) ≥25 mm Hg. Chronic high-altitude hypoxia can lead to the development of HAPH, which has adverse effects on the heart from right ventricular wall thickening to reduced cardiac output, and eventual right heart failure and death. HAPH can occur in utero, so it’s imperative to understand how hypoxia affects mothers and their fetuses during and after birth.2

During pregnancy, the fetus doesn’t breathe air and the lungs are not used. The fetus receives all its oxygen and nutrition needs from the mother’s blood, which flows through the blood vessels in the umbilical cord to the placenta and then to the baby.3 Circulating blood bypasses the lungs by flowing in different pathways through openings called shunts that close at birth to allow for adult circulation. In utero, the baby’s lungs fill with a special fluid that helps the lungs grow.4 The fluid in the lungs, in combination with naturally thicker pulmonary vascular and pulmonary vessel vasoconstriction from low PO2, causes higher vascular resistance in pulmonary circulation that allows for the diversion of blood away from the lungs through the shunts.2 At low altitudes, in the first few days after birth, the high PAP in the lungs drops. The sharp drop in PAP is due to “expansion of the lungs, pulmonary vasodilation from higher PO2, a gradual receding of fluid, a thinning of pulmonary vascular smooth muscle, and… closing of the [shunts]”. This process is known as cardiopulmonary transition. However, at altitude, perinatal hypoxia negatively affects cardiopulmonary transition. The elevated pressures in the pulmonary arteries and vascular resistance persist into early childhood delaying cardiopulmonary transition, which can have developmental consequences such as HAPH and right heart failure, as discussed.

It was discovered that cardiopulmonary transition delay is linked to a high-altitude hypoxia-induced proinflammatory state within the pulmonary vasculature that leads to pulmonary artery remodeling and HAPH. Hypoxia activates or upregulates transcription factor, nuclear factor kappa-light-chain-enhancer of activated B cells (NK-kB), that signals for inflammatory mediators such as hypoxia-inducible factors (HIF). HIF-1a inhibits mammalian target of rapamycin (mTOR). mTOR signaling has an important role in cell metabolism, cell proliferation, and survival, thus inhibiting mTOR prevents “non-proliferative branching and elongation of conducting airways and fluid removal from the lungs,” which contributes to increases in pulmonary vascular resistance and lung development during the cardiopulmonary transition and the onset of newborn gas exchange. 2,5 HIF also contributes to the uncontrolled proliferation and resistance to apoptosis of pulmonary artery smooth muscle cells (PASMC) which is also a crucial contributing factor to pulmonary vessel wall thickening, pulmonary vascular remodeling, and vascular resistance. 5 Metabolic studies showed that chronic hypoxia not only increased the expression of these proinflammatory molecules and mediators but also reduced anti-inflammatory products like omega-3 fatty acids.2

Studies have shown that cardiorespiratory exercise reduces proinflammatory markers and increases anti-inflammatory stimulus in healthy and HAPH populations.2 However, exercise training is not sufficient to reverse PAH, so we need to prevent HAPH from developing in utero with maternal exercise.  The American College of Obstetrics and Gynecologists (ACOG) recommends resistance training twice a week and moderate-intensity cardiorespiratory training daily for a total of 150 minutes a week. Studies showed that pregnant women who followed this recommendation had a 25% reduced risk of developing conditions like gestational diabetes and hypertension that contribute to compromised uterine blood flow and fetal hypoxic conditions. At low altitudes, exercise by pregnant mothers leads to benefits such as decreased fat mass, leptin, oxidative stress, pulmonary valve defects, aortic valve defects and inflammation, and increased neurogenesis in the fetus. Some animal studies at high altitudes showed that offspring of physically active pregnant rodents also received similar benefits from maternal exercise. The offspring were protected against proinflammatory stressors evidenced by low levels of inflammatory mediators, which protected them against the inflammatory processes that drive pulmonary artery remodeling and pressures that lead to HAPH. Further animal studies should be conducted to further explore the possibilities that maternal exercise can counteract the inflammatory changes and prevent HAPH development in fetus and newborns.

Resources

  1. Mirrakhimov AE, Strohl KP. High-altitude Pulmonary Hypertension: an Update on Disease Pathogenesis and Management. The Open Cardiovascular Medicine Journal. 2016; 10: 19-27. doi: 10.2174/1874192401610010019
  2. Leslie E, Gibson AL, Gonzalez Bosc LV, Mermier C, Wilson SM, Deyhle MR. Can Maternal Exercise Prevent High-Altitude Pulmonary Hypertension in Children?. High Altitude Medicine & Biology. 2023; 24: 1-6. https://doi.org/10.1089/ham.2022.0098
  3. 2023. Blood Circulation in the Fetus and Newborn. Stanford Medicine Children’s Health. https://www.stanfordchildrens.org/en/topic/default?id=blood-circulation-in-the-fetus-and-newborn-90-P02362
  4. 2023. Transient tachypnea- newborn. Icahn School of Medicine at Mount Sinai. https://www.mountsinai.org/health-library/diseases-conditions/transient-tachypnea-newborn#:~:text=As%20the%20baby%20grows%20in,start%20removing%20or%20reabsorbing%20it.
  5. He S, Zhu T, Fang Z. The Role and Regulation of Pulmonary Artery Smooth Muscle Cell in Pulmonary Hypertension. International Journal of Hypertension. 2020; 2020: 1478291. doi: 10.1155/2020/1478291
Acclimation, Alcohol at Altitude, Altitude Science, Athletic Training, Backcountry, Backpacking, Child Growth & Development, Exposure, Health, High Altitude, High Altitude Training & Fitness, Huts, Hyperbaric Therapy, Medicine, Mountaineering, Naturopathic Medicine, Sleep at Altitude, Summit Huts

HAFE: High-Altitude Flatus Expulsion

Leave a comment

Often, at high altitude we hear complaints of gas pain and increased flatus in our infant population. Parents often wonder, are we doing something wrong? Is my child reacting to breastmilk, or showing an intolerance to certain foods?  Actually there is another explanation for increased flatus and gas pain in the high-altitude region of Colorado. 

The term HAFE was coined by Dr. Paul Auerbach and Dr. York Miller and published in the Western Journal of Medicine in 1981. Their discovery began In the summer of 1980, when the two doctors were hiking in the San Juan Mountains of Colorado on a quest to summit three 14ers. During their ascent they noticed that something didn’t smell right! As the pair continued to emit noxious fumes, they began to put their scientific brains to work and discovered HAFE. The symptoms include an increase in frequency and volume of flatus, or in other terms an increase in toots! We all have familiarity in watching our bag of potato chips blow up when reaching altitude or our water bottle expanding as we head into the mountains. This reaction is due to a decrease in barometric pressure. Based on Boyle’s law, decreased barometric pressure causes the intestinal gas volume to expand, thus causing HAFE (Skinner & Rawal, 2019).

A graphic illustrating how Boyle's law works: the pressure of a gas increases as its volume decreases.

To my surprise, a gas bubble the size of a walnut in Denver, Colorado (5280 ft) would be the size of a grapefruit in the mountain region of Summit County, CO (8000+ ft)! Trapped gas is known to lead to discomfort and pain. The use of simethicone may have merit in mitigating the effects of HAFE. Simethicone works by changing the surface tension of gas bubbles, allowing easier elimination of gas. This medication, while benign, can be found over the counter and does not appear to be absorbed by the GI tract (Ingold, C. J., & Akhondi, H., 2022). 

While this phenomenon may not be as debilitating as high-altitude pulmonary edema (HAPE), it deserves recognition, as it can cause a significant inconvenience and discomfort to those it inflicts. As the Radiolab podcast explained in their episode The Flight Before Christmas , expelled gas in a plane or car when driving up to the mountains can be embarrassing. While HAFE can be inconvenient, it is a benign condition and a matter of pressure changes rather than a disease or pathological process. We would love to talk more about HAFE at Ebert Family Clinic if you have any questions or concerns!

A bald eagle flies over a misty settled into the valley against the blue-green pine forest of a mountain.
A bald eagle flies toward its nest atop a bare lodgepole pine.

As always, stay happy, safe, and healthy 😊

Taylor Hollingsworth is finishing her final semester as a family nurse practitioner (FNP) student at Georgetown University. Originally from the east coast, Taylor plans to start her FNP career in North Carolina close to family. She has a passion for pediatric and family wellness and has worked as a pediatric intensive care unit nurse for 6 years! In her free time, Taylor loves to hike, fly fish, run, and spend time with her fiancé Logan. 

References

Auerbach, P. & Miller, Y. (1981). High altitude flatus expulsion. The Western Journal of Medicine, 134(2), 173-174.

Chemistry Learner. (2023). Boyle’s Law. https://www.chemistrylearner.com/boyles-law.html

Ingold, C. J., & Akhondi, H. (2022). Simethicone. StatPearls Publishing. 

McKnight, T. (2023). The Flight Before Christmas [Audio podcast]. Radiolab. https://radiolab.org/episodes/flight-christmas

Skinner, R. B., & Rawal, A. R. (2019). EMS flight barotrauma. StatPearls Publishing. 

Acclimation, Altitude Science, Backpacking, Child Growth & Development, Doc Talk, Exposure, Genetics, Health, High Altitude, High Altitude Training & Fitness, Medicine

Re-Entry HAPE: Leading Cause of Critical Illness in Mountain Teens

Leave a comment

Health care providers and people who live at altitude often believe that living in the mountains protects from altitude related illness. And yes, there are many ways the body acclimatizes over days, weeks, months, and years, as addressed in previous blog entries. However, as a physician who has practiced in high altitude communities for over 20 years, my personal observation that we are still at risk for serious complications was reenforced by a recent publication by Dr. Santiago Ucrós at the Universidad de los Andes School of Medicine in Santa Fe de Bogotá, Colombia. His article, High altitude pulmonary edema in children: a systemic review, was published in the journal Pediatric Pulmonology in August 2022. He included 35 studies reporting 210 cases, ages 0-18 years, from 12 countries.

A chart titled "HAPE in Children" illustrates cases of high altitude pulmonary edema by country.

Consistent with our experience in Colorado, the most common ages were 6-10 years and second most common 11-15 years. I have not seen or read any reports of adults affected. Cases included two deaths, which I have also seen here.

I receive reports on any of my patients seen in urgent or emergency care. Accidents, avalanches, and suicide attempts are what we think of first needing emergency care in the mountains. However, the most common critical condition is Reentry HAPE. This is a form of pulmonary edema that can occur in children who are returning from a trip to lower altitude. Think visiting Grandma during school break.  Dr. Ucrós’ review also confirms that all presentations of HAPE (classic, as in visitors, reentry, and HARPE, resident children with no history of recent travel) are more common in males by a 2.6 to 1 ratio. Analysis of time spent at lower altitude before the episode showed a range of 1.6 to 30 days with a mean of 11.3 days. Mean time between arrival and onset of symptoms for all types of HAPE was 16.7 hours. The minimum altitude change reported in a HAPE case was 520 meters (1700 feet), which is the difference between Frisco, CO (Summit County) and Kremmling, CO (Grand County, the next county over). A new form of HAPE in high altitude residents who travel to higher altitude was designated HL-HAPE in this review.  A case report will be featured in an upcoming blog interview with a Summit County resident who traveled to Mt. Kilimanjaro.

As with all cases of HAPE, the victims develop a cough, sound congested as the fluid builds up in their lungs, have fatigue, exercise intolerance, with rapid onset over hours of exposure to altitude, usually above 8000 ft or 2500m. Oxygen saturations in this paper ranged from 55 to 79%. My patients have been as low at 39% in the emergency room.  Children presenting earlier or with milder cases come to the office with oxygen saturations in the 80’s. An underlying infection such as a cold or influenza is nearly always present and considered a contributing factor. Everyone living or visiting altitude should have an inexpensive pulse oximeter which can measure oxygen on a finger. Access to oxygen and immediate treatment for values under 89 can be life-saving.

The recurrence rate for all types of HAPE is about 20%. Most children never have another episode, but some have multiple. Preventive measures include slower return to altitude, such as a night in Denver, acetazolamide prescription taken two days before and two days after, and using oxygen for 24-48 hours on arrival. Most families learn to anticipate, prevent, or treat early and don’t need to see a health care provider after the first episode.

On January 26, 2023 I met with Dr. Ucrós and other high altitude scientists including Dr. Christina Eichstaedt, genetics expert at the University of Heidelberg in Germany, Dr. Deborah Liptzen, pediatric pulmonologist, and Dr. Dunbar Ivy, pediatric cardiologist, both from the University of Colorado and Children’s Hospital of Colorado, and Jose Antonio Castro-Rodríguez MD, PhD from the Pontifica Universidad Católica in Santiago de Chile.

We discussed possible genetic susceptibility to HAPE and hypoxia in newborns at altitude with plans to conduct studies in Bogotá and Summit County, Colorado.

Acclimation, Altitude Science, Athletic Training, Child Growth & Development, Doc Talk, Exposure, Health, High Altitude, High Altitude Training & Fitness, Medicine, Mountaineering

Going Home to the Mountains Can Be Dangerous: Re-Entry HAPE (High Altitude Pulmonary Edema)

Leave a comment

Louie was excited to get out on the slopes after spending Thanksgiving with family in Vermont. He got tired early and felt his breathing was harder than usual, leaving early to go home and rest. As a competitive skier he thought that was strange. But he was getting over a cold. He could not have imagined that in 24 hours he would be in the emergency room, fighting for his life.

Louie experienced a dangerous condition, set off by altitude, and inflammation from his “cold”, that caused his lungs to fill with fluid.  His oxygen saturation was 54 % instead of the normal 92, he had been vomiting and feeling very weak and short of breath. His blood tests showed dehydration, hypoxemia and acute kidney injury. His chest x-ray looked like a snowstorm. He was transferred to Children’s Hospital in Denver and admitted to the intensive care unit.

The diagnosis of Re-entry HAPE was confirmed by echocardiogram showing increased pressures in his lungs. He improved rapidly with oxygen and low altitude.

Re-entry HAPE is not rare, affecting several Summit County children every year.  Many do not come to medical attention because after their first episode parents carefully monitor their oxygen and have a concentrator available in their home when they return from travel. 

Medical providers may not be aware of this risk, expecting that children living at altitude are acclimatized. (See previous blog entry on Acclimatization vs. Adaptation, April 17, 2019) Re-entry HAPE seems to occur mostly in children between the ages of 4 and 15. Inflammation, such as a viral respiratory infection, seems to play a role.  Trauma may also predispose a returning resident to Re-entry HAPE, as described in our blog post from February 5, 2018, Re-entry HAPE in High Altitude Residents.

Louie agreed to share his story on our blog to help educate medical personnel and families living in the mountains about this dangerous condition. Further research will help define who is at risk.  The University of Heidelberg recently published an article on the genetics of pulmonary hypertension (HARPE is the New HAPE) and is interested in testing families here who have had more than one person affected by HAPE.

Acclimation, Altitude Science, Child Growth & Development, Doc Talk, Exposure, Health, High Altitude, Medicine

HARPE is the New HAPE

Leave a comment

It took ten years for me to convince high altitude experts that children living in the mountains get high altitude pulmonary edema (HAPE) without leaving home. My observations were published in 2017 in the Journal of High Altitude Medicine and Biology,

High-Altitude Pulmonary Edema
in Mountain Community Residents

This week Dr. Jose A Castro-Rodriguez MD PhD ATSF discussed HAPE in children at the 8th World Hypoxia conference in La Paz including the now renamed high altitude resident pulmonary edema (HARPE) in his presentation.

Dr. Castro-Rodriguez emphasized the importance of recognizing the three forms of HAPE, including reentry HAPE when children return to the mountains from vacation, since these can be life threatening.

My work has been cited in articles by pulmonologists Deborah Liptzin and Dunbar Ivy from Children’s Hospital of Colorado and geneticist Christine Eichstaedt and her team at the University of Heidelberg.

At Ebert Family Clinic we give every patient/family a free pulse oximeter. The ability to measure the oxygen saturation of anyone with cough, congestion, or fatigue can facilitate early treatment with oxygen and prevent visits to the emergency room, hospital and intensive care unit.

I recently received first prize for a poster presentation on HARPE at the fall Colorado Medical Society meeting, and second prize for a poster on Trauma and HAPE.

For more information about HAPE, HARPE and Trauma-related HAPE, see previous blog entries.

References

Ebert-Santos C. High-Altitude Pulmonary Edema in Mountain Community Residents. High Alt Med Biol. 2017 Sep;18(3):278-284. doi: 10.1089/ham.2016.0100. Epub 2017 Aug 28. PMID: 28846035.

Giesenhagen AM, Ivy DD, Brinton JT, Meier MR, Weinman JP, Liptzin DR. High Altitude Pulmonary Edema in Children: A Single Referral Center Evaluation. J Pediatr. 2019 Jul;210:106-111. doi: 10.1016/j.jpeds.2019.02.028. Epub 2019 Apr 17. PMID: 31005280; PMCID: PMC6592742.

Liptzin DR, Abman SH, Giesenhagen A, Ivy DD. An Approach to Children with Pulmonary Edema at High Altitude. High Alt Med Biol. 2018 Mar;19(1):91-98. doi: 10.1089/ham.2017.0096. Epub 2018 Feb 22. PMID: 29470103; PMCID: PMC5905943.

Eichstaedt CA, Mairbäurl H, Song J, Benjamin N, Fischer C, Dehnert C, Schommer K, Berger MM, Bärtsch P, Grünig E, Hinderhofer K. Genetic Predisposition to High-Altitude Pulmonary Edema. High Alt Med Biol. 2020 Mar;21(1):28-36. doi: 10.1089/ham.2019.0083. Epub 2020 Jan 23. PMID: 31976756.

Acclimation, Altitude Science, Backpacking, Exposure, Health, High Altitude, High Altitude Training & Fitness, Medicine, Mountaineering, Technology

High-Altitude Pulmonary Edema is not just for tourists

Leave a comment

HAPE can affect long term locals too. There is no specific test to diagnosis HAPE leading to delayed treatment or improper treatment, including death.

HAPE is defined as fluid accumulation in the lungs when an individual spends about 48 hours at elevations of 8,200 feet or higher. This can occur when 1) tourists who are not accumulated to high altitudes appropriately 2) locals who re-enter high altitude after being at lower elevation for a period of time or 3) long term residents who develop an illness.

What are the signs and symptoms you ask? Exhaustion, dyspnea on exertion, productive cough, tachypnea, tachycardia, low oxygen saturation levels, and crackles upon lung assessments are the most common to be seen. These are very generic symptoms and resemble many other diseases, such as pneumonia and asthma, leading to misdiagnosis and improper treatment.

How is HAPE treated?

The answer is simple, oxygen. The body is being deprived of oxygen and is unable to feed our cells. By giving oxygen (either through an artificial source or returning to lower elevation) and allowing the body to rest, the body is able to meet its demand for oxygen and symptoms resolve. If one receives oxygen and symptoms do not improve, there is most likely an underlying cause that is contributing to the symptoms unrelated to HAPE.

A pulse oximeter is the easiest way that one can monitor their oxygen levels at home. This device can be purchased over the counter, relatively inexpensive, and easy to use. By placing the pulse oximeter on one’s finger, the device will read the individual’s oxygen level which should be greater than 90% (when at altitude). The heart rate will also be recorded which tends to be between 60-100 beats per minute when at rest for adults.

References

A new mechanism to prevent pulmonary edema in severe infections. Lung Disease News. (n.d.). Retrieved September 2, 2022, from https://lungdiseasenews.com/2015/01/14/researchers-discover-a-new-mechanism-to-prevent-pulmonary-edema-in-severe-infections/

Bhattarai, A., Acharya, S., Yadav, J. K., & Wilkes, M. (2019). Delayed-onset high altitude pulmonary edema: A case report. Wilderness & Environmental Medicine, 30(1), 90–92. https://doi.org/10.1016/j.wem.2018.11.002

Fixler, K. (2017, October 12). Colorado doctor: Health effects of living in mountains unknown to medical establishment. SummitDaily.com. Retrieved September 2, 2022, from https://www.summitdaily.com/news/summit-county-doctor-makes-a-case-for-high-altitude-disorder-that-affects-even-the-acclimated/

Acclimation, Altitude Science, Athletic Training, High Altitude, High Altitude Training & Fitness, Hyperbaric Therapy, Technology

Interview with Retired Fighter Pilot Andrew Breithaupt: Altitude Earth and Sky

Leave a comment

I had the honor of interviewing Andrew Breithaupt who recently retired from US Customs and Border Protection in the Department of Homeland Security where he served as an Air Interdiction Agent piloting multiple types of aircraft.  He currently serves as a Lieutenant Colonel on active duty for the US Army, stationed in Minneapolis, MN.  He began Army flight school in 1992 to become a helicopter pilot, ultimately qualifying in 4 different types of Army helicopters including the UH-1H, OH-58, AH-1, and the AH-64 Apache for which he became an Instructor Pilot training new Army aviators at Fort Rucker, Alabama.  Later he began his transition to fixed-wing aircraft in the civilian community. After nearly 10 years of Army active duty and multiple overseas tours, he was selected to enter service for US Customs and Border Protection where he served as a federal law enforcement agent for over 20 years, retired in December of 2021.  He holds his commercial pilot license for single engine & multi-engine fixed wing as well as rotorcraft with instrument privileges and aircraft type ratings. He has over 30 years of aviation experience and more than 2,500 hours of flight time over his career. I sat down to chat with him about his accomplished career and learn more about his aviation and altitude expertise.

In army flight school, specifically aeromedical training, he was taught the effects of aviation on the body. One of the first lessons they learned in their training was how to recognize the early warning signs of hypoxia. These include shortness of breath, dysphoria, nausea, vomiting and lightheadedness. This type of training is often done in altitude chambers, so trainees can experience these effects before they are in the air, including how aviation can affect your vestibular senses. A position change as simple as looking down to change a radio or instrument can completely disorient a pilot due to the change in direction of the fluid within the inner ear against the cilia. This can lead to the sensation that the plane has rotated and flying sideways. They are taught to trust their instruments because an overcorrection can lead to what they teach in flight school as a “death spiral.” The training is often done in a Barany Chair and simulates vestibular senses experienced during flight.

Elevation in Summit County, Colorado ranges from 7,947 feet to 14,270 feet, the highest peak being Gray’s Peak. With people living as high as 11,200 feet, as Andrew does at his home in Blue River located south of of Breckenridge, CO.  Andrew shared some very interesting aviation altitude requirements which might surprise some. He spent much of his career operating non-pressurized helicopters and Federal Aviation Regulations prohibited him from going between 10,000 feet to 12,000 feet for more than 30 minutes without oxygen. When flying above 12,000 feet, pilots are required to have supplemental oxygen regardless of the amount of time spent at that elevation depending on the category of aviation being conducted such as commercial operations. This is according to the CFR (Code of Federal Regulations) Part 135 which governs commercial aircraft operations. How interesting is it that pilots have these regulations, yet many people who live in Summit County or those summiting 14ers (peaks at 14,000 ft. or above) are at or above these elevations with no supplemental oxygen on a daily basis. When flying private aircraft, CFR part 91.211 specifies flight crew can fly without pressurization or supplemental O2 below 14,000 feet and passengers below 15,000 feet.

While in the Army, Andrew would rarely operate aircraft above 8,000 feet and would typically not have supplemental oxygen on board. They were trained to begin descent immediately if they were to notice the early signs of hypoxia. Keeping a pilot’s license requires strict annual or even semi-annual FAA physicals and continued training to ensure their bodies can withstand the effects of aviation.  As you can imagine those holding these licenses are some of the most fit men and women in the country.  Andrew rarely felt the effects of altitude even with altitude changes as great as 8,000 feet coming from sea level. He would typically remain at these elevations for two hours or less piloting non-pressurized aircraft.

To give some perspective, when you hop on a commercial flight for your next adventure these planes typically fly around 28,000 to 36,000 feet of elevation. When beginning the ascent, the aircraft pressure stabilizes at 6,000 to 8,000 feet, approximately when the dreaded “popping of the ears” is felt. Supplemental oxygen and quick donning masks are required on all these aircraft in case depressurization were to occur due to the rapid hypoxia which would occur at such high altitudes.

Andrew moved to Summit County in November of 2021 from Stafford, VA with his wife and five sons ages 24, 22, 19, 14, and 11.  Andrew and his family spent a significant amount of time in Summit County for snowboarding and skiing competitions and quickly fell in love with the area prior to spending the last 5 years living in Stuttgart, Germany. This is when they decided one day, they would become full-time residents of the county. They moved here for the “people, climate and lifestyle,” a combination I am learning is hard to beat outside of Summit County. With ski and snowboard season right around the corner, he and his family are excited to get back out on the slopes.   Andrew currently travels between his home in Blue River and Minneapolis for his position in the Army. With each trip back he feels his body more quickly adjust to the altitude changes. Thank you for your service Andrew, and welcome to the community!

Ellie Martini grew up in Richmond, VA and is currently a second-year Physician Assistant student at Drexel University in Philadelphia, PA. She completed her undergraduate degree at The College of William and Mary in Williamsburg, VA where she received her BS in Biology. Before PA school she worked as a rehab tech and medical scribe at an addiction clinic. In her free time she enjoys hiking, biking, group fitness, traveling and spending time with friends and family. 

Backcountry, Backpacking, Exposure, Health, High Altitude, High Altitude Training & Fitness, Huts, Medicine, Mountaineering, Naturopathic Medicine, Wildlife

Lost, Stranded, and Hungry in the Mountains of Western Colorado? A Mini Guide to Edible Plants

Leave a comment

From backpacking and camping to skiing and snowboarding, there are plenty of activities outdoors in the Colorado high country. If you find yourself wandering around and lost without food in the mountains, there are several wild plants that you can eat. 

However, before you consume the delectable greens, there are a few precautions to take.

Moose shopping
  • Do not eat any wild plants unless you can positively identify them. There are iOS and Android apps that you can download prior to your hike to help distinguish plants, such as PictureThis and NatureID. 
  • Be aware of environmental factors such as pollution or animal waste. Avoid popular wild animal gathering areas.
  • Make sure you’re not allergic to the plant by rubbing it against your skin and observing for a reaction. If so, do not eat the plant. Before ingesting a large quantity, eat a small amount and check for a reaction. 

It may be difficult to cook if you did not come prepared with a portable stove, pots, and water, which could limit ways to enjoy vegetation. Here is a list of edible plants, how to identify them, where can they be found, and which part you can eat.

Wild plants

Dandelions (Taraxacum officinale): yellow ray florets that spread outward from center with toothy, deep-notched, hairless basal leaves and hollow stems. They can be found everywhere and anywhere. Every part of the dandelion plant is edible including the leaves and roots.

Yellow-green hemispheres bud in a bunch from green stems with pine needle-like leaves.

Pineapple Weed/ Wild Chamomile (Matricaria discoidea): the flower heads are cone-shaped and yellowish-green and do not have petals. Often found near walking paths and roadsides, harvest away from disturbed, polluted areas. If you’re feeling anxious about being lost, pineapple weed promotes  relaxation and sleep and serves as a  digestive aid.

Fireweed (Epilobium angustifolium): vibrant fuchsia flowers. Grows in disturbed areas and near recent burn zones. Eat the leaves when they are young as  adult leaves can stupefy you. Young shoot tips and roots are also edible. 

Wild onions (Allium cernuum): look for pink, lavender to white flowers with a strong scent of onion. They grow in the subalpine terrain and are found on moist hillsides and meadows. Caution: do not confuse with death camas. If it doesn’t smell like an onion and has pink flowers, it is not likely an onion.

Cattails (Typha latifolia or Typha angustifolia): typically 5-10 feet tall. Mature flower stalks resemble the tail of a cat. Grow by creek, river, ponds, and lakes. This whole plant is edible, from the top to the roots. Select from pollution-free areas as it is known to absorb toxins in the surrounding water.

Wild berries:

Wild strawberries (Fragaria virginiana): they are tiny compared to  store-bought. Can be identified by their blue-green leaves; small cluster of white flowers with a yellow center; and slightly hairy, long and slender red stems.

Huckleberries (Vaccinium spp): They grow in the high mountain acidic soil and flourish in the forest grounds underneath small, oval-shaped, pointed leaves. They resemble blueberries and have a distinguishable “crown” structure at the bottom of the berry. They can be red, maroon, dark blue, powder-blue, or purple-blue to almost black, and they range from translucent to opaque.

Deep blue berries stand out against bright red and green, waxy leaves.

Oregon grapes (Mahonia aquifolium): powder-blue berries, resembling juniper berries or blueberries, with spiny leaves similar to hollies that may have reddish tints.

Fun fact: The roots and bark of the plant contain a compound called berberine. Berberine has antimicrobial, antiviral, antifungal, and antibiotic properties.

Mushrooms

Brown whole and halved mushrooms lie on a green table with ridged, sponge-looking caps.

True morels (Morchella spp.): cone-shaped top with lots of deep crevices resembling a sponge. They will be hollow inside. A false morel will have a similar appearance on the outside but will not be hollow on the inside and are toxic. Morels are commonly found at the edge of forested areas where ash, aspen, elm, and oak trees live. Dead trees (forest wildfires) and old apple orchards are prime spots for morels.

Short, stubby mushrooms with white stems and brown camps stand in a row growing over grass.

Porcini (Boletus edulis): brown-capped mushrooms with thick, white stalks. Found at  high elevations of 10,500 and 11,200 ft in  areas with monsoon rains and sustained summer heat.

There are many more edible plants, flowers, berries, and mushrooms in the mountains. These are just 10 that can be easily identifiable and common in the Western Colorado landscapes. I recommend trying out the apps listed above and reading “Wild Edible Plants of Colorado” by Charles W. Kane, which includes 58 plants from various regions, each with details of use and preparation. Hopefully this post made you feel more prepared for your next adventure. 

Resources:

Davis, E., 2022. Fall plant tour: Frisco, CO | Wild Food Girl. [online] Wildfoodgirl.com. Available at: <https://wildfoodgirl.com/2012/eleven-edible-wild-plants-from-frisco-trailhead/> [Accessed 10 July 2022].

McGuire, P., 2022. 8 Delicious Foods to Forage in Colorado | Wild Berries…. [online] Uncovercolorado.com. Available at: <https://www.uncovercolorado.com/foraging-for-food-in-colorado/> [Accessed 10 July2022].

Rmhp.org. 2022. Edible Plants On The Western Slope | RMHP Blog. [online] Available at: <https://www.rmhp.org/blog/2020/march/foraging-for-edible-plants> [Accessed 10 July 2022].

Lifescapecolorado.com. 2022. [online] Available at: <https://lifescapecolorado.com/2014/01/edible-plants-of-colorado/> [Accessed 10 July 2022].

Pfaf.org. 2022. Plant Search Result. [online] Available at: <https://pfaf.org/user/DatabaseSearhResult.aspx> [Accessed 10 July 2022].

Cindy Hinh is a second-year Physician Assistant student at Red Rocks Community College in Arvada, CO. She grew up in southern Louisiana and received her undergraduate degree in Biology from Louisiana State University. Prior to PA school, she was a medical scribe in the emergency department and an urgent care tech. In her free time, she enjoys baking, cooking, going on food adventures, hiking, and spending time with family and friends.

Acclimation, Child Growth & Development, Health, High Altitude, Medicine

Beneficial Effects of Chronic Hypoxia

Leave a comment

Living in Summit County, Colorado has its perks – residents are within a 20 to 40 minute drive to five world class ski resorts, and some of the most beautiful Rocky Mountain trail systems are accessible right out our back door. With the endless opportunities drawing residents outdoors to partake in physical activity, it comes as no surprise that Summit County is considered one of the healthiest communities in the country. However, there may be more than meets the eye when it comes to explaining this, as it also has something to do with the thin air.

As a Summit County native, you have likely heard the term “hypoxia” or “hypoxemia” mentioned a time or two. So what does this mean? Simply put, these words describe the physiological condition that occurs when there is a deficiency in the amount of oxygen in the blood, resulting in decreased oxygen supply to the body’s tissues. When this occurs in the acute setting, it may result in symptoms such as headache, fatigue, nausea, and vomiting. These are common symptoms experienced by those with altitude illness, also known as acute mountain sickness. While these symptoms can cause extreme discomfort and may put a huge damper on a mountain vacation, they are not usually life threatening. However, in a small number of people, development of more serious conditions such as a high altitude pulmonary edema (HAPE) and high altitude cerebral edema (HACE) can occur. The treatment for all conditions related to altitude illness is oxygen, whether via return to lower elevations or by a portable oxygen concentrator that allows you to stay where you are. While altitude illness generally affects those who rapidly travel from sea level to our elevation, it has also been known to affect residents returning home to altitude, usually after a period of two or more weeks away. In a very small subset it can occur after a period of only a day or two. This generally occurs in those with a preexisting illness, where altitude exacerbates the condition.

While the acute effects of altitude can clearly have detrimental effects on one’s physical well-being, there is emerging research demonstrating that chronic hypoxia may actually come with several health benefits. Long time Summit County business owner and community pediatrician, Dr. Chris Ebert-Santos of Ebert Family Clinic in Frisco, has spent quite some time studying the effects of chronic high-altitude exposure, and recently attended and presented at the Chronic Hypoxia Symposium in La Paz, Bolivia, the highest capital city in the world.

It is important to first understand the adaptations that occur in our bodies as a result of long-term hypoxia. The ability to maintain oxygen balance is essential to our survival.

So how do those of us living in a place where each breath we take contains about ⅓ fewer oxygen molecules survive?

Simply put, we beef up our ability to transport oxygen throughout our body. To do this, our bodies, specifically the kidneys, lungs and brain increase their production of a hormone called erythropoietin, commonly known as EPO. This hormone signals the body to increase its production of red blood cells in the bone marrow. Red blood cells contain oxygen binding hemoglobin proteins that deliver oxygen to the body’s tissues. Thus, more red blood cells equal more oxygen-carrying capacity. In addition to increasing the ability to carry oxygen, our bodies also adapt on a cellular level by increasing the efficiency of energy-producing biochemical pathways, and by decreasing the use of oxygen consuming processes2. Furthermore, the response to chronic hypoxia stimulates the production of growth factors in the body that work to improve vascularization2, thus, increased ability for oxygenated blood to reach its destination. 

So, how can these things offer health benefit?

To start, it appears that adaptation to continuous hypoxia has cardio-protective effects, conferring defense against lethal myocardial injury caused by acute ischemia (lack of blood flow) and the subsequent injury caused by return of blood to the affected area3. The exact mechanism of how this occurs is not well understood, but it seems that heart tissue adapts to be better able to tolerate episodes of ischemia, making it more resistant to damage that could otherwise be done by decreased blood flow that occurs during what is commonly known as a heart attack. This same principle applied to ischemic brain damage when tested in rat subjects. Compared to their normoxic counterparts, rats pre-conditioned with hypoxia sustained less ischemic brain changes when subjected to carotid artery occlusion, suggesting neuroprotective effects of chronic hypoxia exposure4.

Additionally, it appears that altitude-adapted individuals may be better equipped to combat a pathological process known as endothelial dysfunction5. This process is a driving force in the development of atherosclerotic, coronary, and cerebrovascular artery disease. Altitude induces relative vasodilation of the body’s blood vessels compared to lowlanders2. A relaxing molecule known as nitric oxide, or NO, assists with causing this dilation, and in turn the resultant dilated blood vessels produce more of this compound5. The molecule has protective effects on the inner linings of blood vessels and helps to decrease the production of pro-inflammatory cytokines that damage the endothelium5. This damage is what kickstarts the cascade that leads to atherosclerosis in our arteries. Thus, a constant state of hypoxia-induced vasodilation may in fact decrease one’s risk of developing occlusive vascular disease. 

The topics mentioned above highlight a few of the proposed mechanisms by which chronic hypoxia may be beneficial to our health. However, do keep in mind that there are potential detrimental effects, including an increased incidence of pulmonary hypertension as well as exacerbation of preexisting conditions such as COPD, structural heart defects and sleep apnea, to name a few6. Research regarding the effects of chronic hypoxia on the human body is ongoing, and given its significance to those of us living at elevations of 9,000 feet and above, it is important to be aware of the impact our physical environment has on our health. Dr. Ebert-Santos is avidly involved in organizations dedicated to better understanding the health impacts of chronic hypoxia, and has several current research projects of her own that may help us to further understand the underlying science.

Kayla Gray is a medical student at Rocky Vista University in Parker, CO. She grew up in Breckenridge, CO, and spent her third year pediatric clinical rotation with Dr. Chris at Ebert Family Clinic. She plans to specialize in emergency medicine, and hopes to one day end up practicing again in a mountain community. She is an avid skier, backpacker, and traveler, and plans to incorporate global medicine into her future practice.

Citations

  1. Theodore, A. (2018). Oxygenation and mechanisms for hypoxemia. In G. Finlay (Ed.), UpToDate. Retrieved May 2, 2019, from https://www-uptodate-com.proxy.rvu.edu/ contents/oxygenation-and-mechanisms-of-hypoxemia?search=hypoxia&source=search_ result&selectedTitle=1~150&usage_type= default&display_rank=1#H467959
  2. Michiels C. (2004). Physiological and pathological responses to hypoxia. The American journal of pathology, 164(6), 1875–1882. doi:10.1016/S0002-9440(10)63747-9. Retrieved May 2, 2019. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1615763/ 
  3. Kolar, F. (2019). Molecular mechanism underlying the cardioprotective effects conferred by adaptation to chronic continuous and intermittent hypoxia. 7th Chronic Hypoxia Symposium Abstracts. pg 4. Retrieved May 2, 2019. http://zuniv.net/symposium7/Abstracts7CHS.pdf
  4. Das, K., Biradar, M. (2019). Unilateral common carotid artery occlusion and brain histopathology in rats pre-conditioned with sub chronic hypoxia. 7th Chronic Hypoxia Symposium Abstracts. pg 5. Retrieved May 2, 2019. http://zuniv.net/symposium7/Abstracts7CHS.pdf
  5. Gerstein, W. (2019). Endothelial dysfunction at high altitude. 7th Chronic Hypoxia Symposium Abstracts. pg 11. Retrieved May 7, 2019. http://zuniv.net/symposium7/Abstracts7CHS.pdf
  6. Hypoxemia. Cleveland Clinic. Updated March 7, 2018. Retrieved May 9, 2019. https://my.clevelandclinic.org/health/diseases/17727-hypoxemia