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Nota Importante

Aunque pueda contener afirmaciones, datos o apuntes procedentes de instituciones o profesionales sanitarios, la información contenida en el blog EMS Solutions International está editada y elaborada por profesionales de la salud. Recomendamos al lector que cualquier duda relacionada con la salud sea consultada con un profesional del ámbito sanitario. by Dr. Ramon REYES, MD

jueves, 30 de mayo de 2013

The dangers of too much O2. EMSWORLD.COM

The dangers of too much O2

More Oxygen Can’t Hurt…Can It?

What have we learned about oxygen? The dangers of too much O2

It was 0635. Larry and Adriane always got to the station early to check out the truck and, if a late call came in, take it so Greg and Chad could get off on time. This was an arrangement the Medic 2 crews shared, and it worked well for them.
As Adriane checked out the D cylinders and M tank, she said offhandedly, “Better be sure we have plenty of Os. We’re due for a chest pain call.” “Watch your mouth,” said Larry, grinning as he tossed her the last of the Twinkies he’d saved. “You know what happens when you say things like that.”
Twenty minutes later they were at the home of Doris, one of their regular patients, a 64-year-old type 2 diabetic who was, in fact, experiencing chest pain she described as 5 on a scale of 0–10.
While Larry attached the 12-lead, Adriane noted the pulse oximeter read 97% on room air, so she put Doris on a non-rebreather mask and turned the oxygen on at 15 liters per minute. “You can’t have enough of this good stuff,” she said. “Let’s get that sat up to 100% for those heart cells.”
After giving an aspirin, starting an IV and giving a squirt of nitroglycerin, they transported Doris to the nearby Level III hospital, where she went immediately to the cath lab, got a stent in her right coronary artery, went to the CCU and eventually returned home three days later, feeling great.
“Good job, folks,” Dr. Chutney said at the chart review the next week, “but here’s something I need to pass along to you: We don’t do 15 liters per minute by non-rebreather for routine chest pain patients anymore.”
“Why?” said Adriane. “In my book it says not to worry about problems from too much oxygen, that they only develop after several days of more than 50% inspired oxygen delivered at higher-than-normal pressures.”
“What book are you reading from, Adriane?” asked Dr. Chutney.
“From my Orange Book,” said Adriane, “Emergency Care and Transportation of the Sick and Injured, seventh edition, from my EMT class back in 2000.”

The Problem

In 2000 that was what we were taught about oxygen therapy for patients with chest pain. But times have changed. We now know that while some oxygen may be good, more is not necessarily better.
We have always known that oxygen is necessary for all animal life, and that lack of oxygen damages tissues. It is beyond argument that patients who are hypoxic must receive supplemental oxygen. What we’ve not always known is that too much oxygen can harm patients in a number of ways.
One is through reactive oxygen species (ROS), often called free radicals. A radical is an atom that has one or more unpaired electrons. Oxygen has two unpaired electrons that make it susceptible to radical formation. When ROS form in cells, damage can occur. Hypoxic cells are greatly susceptible to ROS. These can damage tissues throughout the body, but of particular concern are lung, heart and brain tissues. Not all radicals are bad, and the role of radicals is far beyond the scope of this article, but we know that damage to the plasma membranes, mitochondria and endomembrane systems by ROS is significant.
High oxygen concentrations can also cause atelectasis. Air is about 21% oxygen and 79% nitrogen. The alveoli depend on nitrogen to maintain surfactant production and alveolar patency; when high concentrations of oxygen are administered, oxygen may “wash out” nitrogen and leave the alveoli susceptible to a lack of gas as oxygen diffuses into the blood, causing them to collapse. This “washout” may be desirable temporarily in patients being preoxygenated for rapid- or delayed-sequence intubation, but over time atelectasis may occur, and this is not good. Once intubation is accomplished, a natural mixture of gases must be allowed to reconstitute in the lungs to avoid collapse of alveoli and atelectasis. There is little to be gained by achieving an oxygen pressure of greater than 100 mmHg.

Trauma Patients

 Over the last 20 years we’ve been in the habit of giving high-flow oxygen to just about everybody. Every trauma patient gets oxygen at 15 lpm by non-rebreather mask, regardless of their blood oxygen saturation. What many do not realize is that this was taught not because it was beneficial, but because it was considered an acceptable risk when time limitations necessitated deletion of much of the medical theory during the 1994 revision of the EMT-Basic curriculum. Everyone was taught to deliver high-flow oxygen by non-rebreather without understanding why it was beneficial…or potentially harmful. There is no medical evidence to support this practice unless the patient is hypoxic or in shock.

In 2004, Tulane MDs Zsolt Stockinger and Norman McSwain monitored 5,090 trauma patients not requiring assisted ventilation to see whether supplemental oxygen improved their outcomes. The results showed those who received oxygen did no better or worse than those who did not. The authors concluded supplemental oxygen does not improve survival in traumatized patients who are not in respiratory distress.1

Chest Pain Patients

It has been our traditional practice to give high concentrations of oxygen to patients with chest pain and MI, for reasons no better than “this is how we’ve always done it.” As Israeli physician Chaim Lotan said at a conference in 2011, “We have been brainwashed into using oxygen” even though recent data suggests it has harmful effects that are mediated primarily by coronary artery vasoconstriction. “Before I started looking into the data,” Lotan said, “I didn’t understand how much damage we were causing by giving oxygen.”2
In fact, it is true that 100% oxygen given by non-rebreather reduces coronary artery flow by 30% after 5 minutes. It also reduces the effects of vasodilators such as nitroglycerin.3
This is not exactly a result we’d desire while treating a patient with coronary artery disease. For this reason, the American Heart Association’s emergency cardiac care guidelines have, since 2010, recommended as follows: There is insufficient evidence to support [oxygen’s] routine use in uncomplicated ACS. If the patient is dyspneic, hypoxemic or has obvious signs of heart failure, providers should titrate therapy, based on monitoring of oxyhemoglobin saturation, to ≥94% (Class I, LOE C).4
In a Cochrane review of the literature, researchers in New Zealand led by Meme Wijesinghe found that, although evidence is limited, it suggests that routine use of high-flow oxygen in uncomplicated MI may result in a greater infarct size and possibly increase the risk of mortality.5 These authors concluded it is well-established that arterial oxygen tension is a major determinant of coronary artery blood flow and that high-flow oxygen therapy can cause a reduction in cardiac output and stroke volume. They concluded there is insufficient evidence to support the routine use of high-flow oxygen in the treatment of uncomplicated MI, and that it may increase mortality.

Stroke Patients

Stroke patients should be managed similarly. Administer supplemental oxygen to stroke patients who are hypoxemic or when oxygen saturations are not obtainable; the goal is to maintain a saturation of 94% or greater.

COPD Patients

The role of oxygen in chronic obstructive pulmonary disease (COPD) patients has been debated for decades. Issues such as a theoretical “hypoxic drive” in patients with COPD and chronic hypercarbia have led to controversies over how much oxygen to give them. While hypoxia must be corrected quickly when it exists, the definition of hypoxia in terms of oxygen saturation has been unclear. For example, a normal person without a respiratory condition breathing room air will usually have a saturation varying from 97%–99%, depending on tidal volume and other normal respiratory variances. It is almost impossible to achieve 100% saturation by breathing room air. We know a saturation of 90% correlates to approximately 60 mmHg pressure, and that is the normal threshold of respiratory distress. However, COPD patients may be accustomed to less saturation, and they typically do well at 88%–92%.
In a study of 405 patients in Australia published in 2010, Dr. Michael Austin and colleagues compared the outcomes of COPD patients who were given standard high-flow oxygen treatment with those given titrated oxygen treatment by paramedics. Titrated oxygen treatment reduced mortality compared with high-flow oxygen by 58% for all patients.6


In a 2012 study of prehospital noninvasive ventilation in patients with pulmonary edema and/or COPD, asthma and pneumonia, a team led by Dr. Bryan Bledsoe found that use of CPAP with a low oxygen percentage (FiO2) of 28%–32% was highly effective in treatment of respiratory emergencies by medics. Since most CPAP setups deliver 100% oxygen, it may be worthwhile for services to explore the value of using setups with a lower oxygen percentage.7

Post-Cardiac Resuscitation Patients

Finally, the role of oxygen after cardiac resuscitation must be mentioned. At one time we attempted to push as much oxygen as possible into cardiac arrest patients on the theory that myocardial oxygen supplies were quickly dwindling, and that if we wanted to save people, we had to replenish the missing oxygen. During arrest, and if we were fortunate enough to get a return of spontaneous circulation, we bagged patients as fast and hard as we could, thinking we were restoring oxygen to ischemic cardiac and brain cells.
Now we know that while ischemia is responsible for most cases of cardiac arrest, managing reperfusion of ischemic cardiac cells is more complicated than we thought. Because of the role of ROS (free radicals), we now understand that a flood of oxygen into previously ischemic cardiac cells is harmful.
The latest post-cardiac arrest care guidelines from AHA recommend the following: Avoid excessive ventilation. Start at 10–12 breaths/min and titrate to target PetCO2 of 35–40 mmHg. When feasible, titrate FiO2 to minimum necessary to achieve SpO2 equal to or greater than 94%.8

Conclusion

In Adriane’s copy of Emergency Care and Transportation, pulse oximetry was not even mentioned because it was not routinely available on ambulances then. Now that we routinely monitor SpO2 for most patients and know what we do about the dangers of hyperoxygenation, it makes sense to give only as much oxygen as the patient requires.
In the early days of EMS, venturi masks were popular and routinely used for COPD and cardiac patients. Following the 1994 revision of the EMT National Standard Curriculum, these were largely abandoned because it was felt high concentrations of oxygen were an acceptable risk, given the curriculum’s time limitations. We may see a return of venturi masks to EMS as we become more aware of the need to limit oxygen percentages in our therapy.
In the past 20 years, the debate in oxygen therapy has largely been confined to high-flow versus low-flow. Given the current research and assessment tools available to us, it would seem the debate should shift to low-flow versus no supplemental oxygen at all. We have the means to titrate oxygen therapy to patients’ needs, and those needs most often can be met by low-flow oxygen.
By no means do we suggest that patients who need oxygen be denied it. Hypoxia must be corrected immediately. But you can have too much of a good thing.

References

1. Stockinger ZT, McSwain NE Jr. Prehospital supplemental oxygen in trauma patients: its efficacy and implications for military medical care. Mil Med, 2004 Aug; 169(8): 609–12.
2. Hughes S. Oxygen for MI: More harm than good? TheHeart.org, www.theheart.org/article/1270299.do.
3. McNulty PH, et al. Effects of supplemental oxygen administration on coronary blood flow in patients undergoing cardiac catheterization. Am J Physiol Heart Circ Physiol, 2005; 288: H1057–62.
4. Circulation, 2010; 122: S787–817.
5. Wijesinghe M, Perrin K, Ranchord A, Simmonds M, Weatherall M, Beasley R. Routine use of oxygen in the treatment of myocardial infarction: systematic review. Heart, 2009; 95: 198–202.
6. Austin MA, Wills KE, Blizzard L, Walters EH, Wood-Baker R. Effect of high flow oxygen on mortality in chronic obstructive pulmonary disease patients in prehospital setting: randomized controlled trial. BMJ, 2010 Oct 18; 341: c5462.
7. Bledsoe BE, Anderson E, Hodnick R, Johnson L, Johnson S, Devendorf E. Low-fractional oxygen concentration continuous positive airway pressure is effective in the prehospital setting. Prehosp Emerg Care, 2012 Apr–Jun; 16(2): 217–21.
8. Circulation, 2010; 122: S768–86.
William E. “Gene” Gandy, JD, LP, has been a paramedic and EMS educator for more than 30 years. He has implemented a two-year associate degree paramedic program for a community college, served as both a volunteer and paid paramedic, and practiced in both rural and urban settings and in the offshore oil industry. He has testified in court as an expert witness in a number of cases involving EMS providers and lectures on medical/legal aspects of EMS. He lives in Tucson, AZ.


Steven “Kelly” Grayson, NREMT-P, CCEMT-P, is a critical care paramedic for Acadian Ambulance in Louisiana. He has spent the past 14 years as a field paramedic, critical care transport paramedic, field supervisor and educator. He is a former president of the Louisiana EMS Instructor Society and board member of the Louisiana Association of Nationally Registered EMTs. He is a frequent EMS conference speaker and author of the book En Route: A Paramedic’s Stories of Life, Death, and Everything In Between, and the popular blog A Day in the Life of an Ambulance Driver.

Information from: EMSWORLD.COM

Una guia para mejorar la conduccion de la bici en las calles de la ciudad. Infografia

una guia para mejorar la conduccion de la bici en las calles de la ciudad

El uso del casco previene dos de cada tres lesiones graves en ciclistas
La DGT quiere que sea obligatorio en las zonas urbanas, lo que pone en pie de guerra a ciclistas y ayuntamientos

Un 20% de los fallecidos en accidente entre 10 y 14 años iba sin casco en la bicicleta, España
El uso del casco al montar en bicicleta reduce el riesgo de lesión craneal y cerebral en hasta en un 90% y el riesgo de fallecimiento en un 26%. La Asociación Española de Pediatría (AEP) ha dado a conocer una serie de consejos específicos sobre su utilización entre menores detalles en en el enalce http://emssolutionsint.blogspot.co.uk/2013/04/un-20-de-los-fallecidos-en-accidente.html

miércoles, 22 de mayo de 2013

1st Annual International Emergency Medicine, Trauma and Critical Care Conference. Punta Cana, Dominican Republic 02-03 August 2013

1st Annual International Emergency Medicine, Trauma and Critical Care Conference. Punta Cana, Dominican Republic
02-03  August 2013

Dear Colleagues,
The Dominican Emergency Medicine Interest Group Network along withUniversidad Nacional Pedro Henriquez Ureña and the American Academy of Emergency Medicine  are proud to present its 1st Annual International Conference on Emergency Medicine with the theme "Emergency Medicine, Trauma and Critical Care: State of the Art".
This will take place on days August 2nd and 3rd , 2013 at the Hotel Barcelo Punta Cana, Dominican Republic. The program includes a wide range of issues to be addressed by highly qualified professionals, which present the latest advances in clinical practice.
Ensuring the highest level professional education and we have the participation of specialists from the United States and Latin America, who will present their knowledge based on years of clinical expertise.
We hope that this conference will be of beneficial learning for all  and serves as well to strengthen relations between our countries and centers.

Best regards,



Dr. Amado Alejandro Baez, MSc, MPH, FAAEM, FCCP
Conference Chairman

1st Annual International Emergency Medicine, Trauma and Critical Care Conference. Punta Cana, Dominican Republic 02-03  August 2013
PRE CONFERENCE COURSE Advanced Ultrasound in Emergency and Critical Care    Santo Domindo, Rep. Dom 30 -31 July 2013


http://youtu.be/5JmI8m_8pIU

Desarrollan el primer simulador virtual de intubación para neonatos de hasta tres kilos


Redacción | Madrid

La Fundación Alcalá Innova y pediatras españoles han desarrollado conjuntamente el primer simulador virtual de intubación para neonatos de entre uno y tres kilos, lo que supone una alternativa fiable al actual entrenamiento para la praxis de intubación en el área neonatal y pediátrica.

El proyecto, que ha obtenido financiación del Ministerio de Sanidad en competencia con otros proyectos presentados por los principales centros de investigación en salud del país, será presentado, bajo el nombre de ‘Simulador dinámico de intubación neonatal’, en el ‘27 Congreso Internacional de la Asociación de Pediatría’, que se celebrará entre el 24 y 29 de agosto en Melbourne, Australia. 

El simulador, que cuenta con diversas fases de formación, permite “un entrenamiento fiable y sin riesgos para el paciente, ya que el programa genera las variables necesarias para simular situaciones reales y complejas que se producen a diario en los hospitales”.

Para sus creadores supone,“una revolución en el ámbito formativo, ya que las condiciones creadas son idénticas a una intubación real, pero sin el riesgo que presenta realizarla con un neonato vivo”. 

El sistema consta de un maniquí a tamaño real y un laringoscopio que permitirán al especialista simular el acceso a una vía aérea en condiciones realistas. Se dispone también de un sistema de sensores que traquean la posición del maniquí así como los movimientos que realice el especialista con el laringoscopio y el tubo endotraqueal. 

Tras ello, toda la información generada es procesada por un simulador virtual que recreará las mismas condiciones de una intubación real y hará que el usuario esté inmerso en el escenario virtual donde tendrá que simular todo el proceso de intubación.

El simulador, además de permitir el entrenamiento de los movimientos adecuados que el especialista debe llevar a cabo para acceder correctamente a la vía aérea, permite también que el especialista se entrene en la toma de decisiones, ya que presenta una serie de casuísticas basadas en datos reales que permiten que el médico interiorice de forma más rápida el protocolo de actuación médica para cada caso.

“No solo se presentará a nivel internacional en el próximo Congreso Internacional de la Asociación de Pediatría, sino que ya se han cerrado convenios, por ejemplo, en Hungría donde la Universidad Semmelweis, ampliamente reconocida por ser uno de los principales centros de medicina de Europa, se ha interesado por la herramienta. Así como la Fundación Peter Cerny, con una experiencia de 24 años en el ámbito del transporte entre instalaciones de neonatos y de emergencias de prematuros, o elHospital Uzsoki”, indica el gerente de la Fundación Alcalá Innova, Marcelino Colete.


Porque salud necesitamos todos… ConSalud.es
@ConSalud_es - See more at: http://consalud.es/see_news.php?id=5532#sthash.v5AK4rQI.dpuf

lunes, 13 de mayo de 2013

'II JORNADA DE PREVENCIÓN Y ATENCIÓN EN ACCIDENTES DE MOTO' DEL CEU La llamada a Urgencias y la atención antes de llegar al hospital es fundamental en el pronóstico del accidentado en moto


Pasado el peligro es precisa una rehabilitación junto a un fisioterapeuta

   MADRID, 12 May. (EUROPA PRESS) -
   La llamada a Urgencias y la asistencia por parte de los profesionales sanitarios antes de llegar al hospital es "fundamental" de cara al pronóstico del accidentado en motocicleta, según señala el coordinador del Grado de Fisioterapia de la Universidad CEU San Pablo de Madrid, el profesor José Antonio Martín Urrialde.
   Así lo ha asegurado el experto a Europa Press con motivo de la celebración este sábado en la Facultad de Medicina de este centro universitario de la 'II Jornada de Prevención y Atención en Accidentes de Motocicleta', que organiza la universidad junto a la Asociación para el Estudio de la Lesión Medular Espinal (Aesleme) y la iniciativa solidaria 'Conducción Segura en Moto'.
   A juicio de Martín Urrialde, en la primera llamada tras auxiliar al accidentado "hay que informar de si éste está consciente y de si respira", además de indicar la localización del herido. No obstante, la persona que le socorre "no debe moverle, ni manipularle el casco", aclara.
   En este sentido, especifica que "es un error ponerle boca arriba si se encuentra en una posición rara", ya que puede tener una pequeña fractura en una vértebra. Por su parte, y en relación al casco, hay que seguir el mismo criterio, y es que "sólo se lo puede retirar personal de Emergencias, que son los que están capacitados para ello", explica.

EL PROTOCOLO DE AUXILIO CONSISTE EN PROTEGER, ASISTIR Y SOCORRER

   Lo que sí puede hacer la persona auxiliadora es seguir el protocolo para este tipo de casos, que consiste en "proteger, asistir y socorrer", afirma. En el primer aspecto, lo que debe hacer la persona que encuentra al herido es salvaguardar al motorista y a los que se paran a prestar auxilio "colocando algún medio visual que avise a otros conductores de que en ese punto ha habido un accidente", mantiene.
   Tras ello, y en el apartado de asistencia, se enmarca la mencionada llamada telefónica, que es el paso previo al socorro. En este punto, "hay que taparle, transmitirle seguridad, decirle que ya se ha avisado a los servicios de rescate e informarle de que se le va a acompañar hasta que lleguen", declara.
   Además, Martín Urrialde sostiene que se le tiene que coger el móvil "para llamar a alguien". Todo ello es fundamental, pero no lo único, ya que en casos de pérdida de extremidades o miembros "se le puede colocar algún dispositivo para parar la hemorragia", manifiesta.
   Una vez que se encuentren los servicios de Emergencias en el lugar del siniestro, éstos deben de encargarse "de conseguir que el motorista llegue en la mejor condición posible al hospital", asegura. Para ello, optan por "controlar las hemorragias, garantizar la respiración y el pulso y administrar suero para que no baje la presión", indica.
   Dicho esto, y centrándose en el ámbito madrileño, sostiene que "hay que romper una lanza en favor del SAMUR, que llega al lugar en un tiempo medio de seis o siete minutos, lo que minimiza el riesgo", y es que la primera hora "es fundamental".

LAS LESIONES VARÍAN EN FUNCIÓN DEL IMPACTO

   La gravedad de las lesiones del siniestrado dependen, en gran medida, de la velocidad con la que se transita con la motocicleta y "del impacto contra el guardarraíl", y es que, si hay colisión, pueden producirse "hemorragias internas, amputaciones de miembros o la rotura de una vértebra que deje al motorista parapléjico", además de la posibilidad de que sea un accidente mortal, asegura.
   No obstante, y en una situación "ideal", el motorista puede resbalar y caer, y no golpear contra uno de estos elementos, lo que provoca, frecuentemente, "fracturas de húmero o de clavícula", sostiene. Por ello, apuesta por el cambio de los guardarraíles, que "son como una cuchilla".
   Además, Martín Urrialde señala que durante la jornada se va a hacer hincapié en la importancia de "llevar casco, ropa adecuada y protecciones de manos pies", así como que se va a realizar un ejercicio práctico para enseñar a saber si el accidentado respira sin tener que moverle.
   Una vez que el motorista ha sido intervenido en el hospital y está considerado como fuera de peligro, llega el momento de la rehabilitación fisioterapéutica. "Las lesiones a tratar suelen ser roturas y desgarros de músculos que provocan un largo periodo de trabajo", asegura al respecto.
   Durante el tiempo de trabajo compartido, el fisioterapeuta y el paciente adquieren "una buena relación", tras la cual se devuelve la capacidad para montar en motocicleta, "siempre que se supere el aspecto psicológico", concluye.