: Discuss the process for characterizing cake solids derived from a liquid treatment process as being either hazardous or non-hazardous.

: Discuss the process for characterizing cake solids derived from a liquid treatment process as being either hazardous or non-hazardous.

Discuss liquid effluent management strategies related to a sewer cleanout of a petrochemical facility.

Discuss liquid effluent management strategies related to chemical cleaning operations within an oil refinery facility.

Discuss the process for characterizing cake solids derived from a liquid treatment process as being either hazardous or non-hazardous.

Discuss the relevance of the analytical testing methods as they relate to modeling waste behaviors in a landfill.

Hitzu uses the perpetual inventory system

Hitzu Co. sold a copier costing $3,500 with a two-year parts warranty to a customer on August 16, 2015, for $7,000 cash. Hitzu uses the perpetual inventory system. On November 22, 2016, the copier requires on-site repairs that are completed the same day. The repairs cost $124 for materials taken from the Repair Parts Inventory. These are the only repairs required in 2016 for this copier. Based on experience, Hitzu expects to incur warranty costs equal to 4% of dollar sales. It records warranty expense with an adjusting entry at the end of each year. 1. How much warranty expense does the company report in 2015 for this copier? 2. How much is the estimated warranty liability for this copier as of December 31, 2015? 3. How much warranty expense does the company report in 2016 for this copier? 4. How much is the estimated warranty liability for this copier as of December 31, 2016? 5. Prepare journal entries to record (a) the copier’s sale; (b) the adjustment on December 31, 2015, to recognize the warranty expense; and (c) the repairs that occur in November 2016. 5a. Record the sale of a copier for $7,000 cash. 5b.Record the cost of goods sold of $3,500. 5c. Record the estimated warranty expense at 4% of the sales. 5d. Record the cost of $124 towards repair of copier on November 22, 2016. Please show work…thank you.

Meeting the Needs of a Dying Patient


Title:


caring for a patient who is dying is an experience most nurses will


face at some stage of their career. With reference to patients you have cared


for, describe how you were able to meet the needs of dying patients.

As a certainty, all of us will have to face death at some stage. Some of us are fortunate enough to be able to do so with caring, supportive and empathetic people around us. (Seale C et al. 2003). Nurses must be able to discharge their professional responsibilities in this area with this comment in mind. In this short essay we will explore how a nurse can empathise, understand and assist the patient in dealing with the various issues that arise.

We will discuss these issues in relation to one specific case, Mrs G. The case was complex, but, in essence, it involved a lady who had just been given a terminal diagnosis and entered into a phase of complete denial and overt avoidance behaviour. She would change the subject when talking about her health and keep herself almost manically occupied with trivial tasks so as not to have to consider the reality of the situation.

Dobrantz (2005) points to the fact that it is well recognised that some patients deal with life crises simply by ignoring them, other will use mechanisms of varying degrees of cognitive distortion (CDs), which may range from undue optimism to complete denial (as Mrs.G did).

The main nursing dilemma here is should the nurse actively confront Mrs.G’s denial and allow her to see the reality of the situation or is it perhaps kinder to allow her to continue in her state of overt denial. (Dean A. 2002)

On first analysis, one might take the view that, given the fact that Mrs.G had only a short time left to live, it might be a kindness to allow her not to confront the psychological pain of anticipating her imminent death. Against this argument is the concept of “a good death”. (Cuttini et al. 2003). Many authorities (viz. Roy C 1991)

that in order for a patient to have “a good death”, they need time to accept the inevitable and to mentally come to terms with it, make what preparations they need (financial, practical, spiritual, personal) so that they can approach it in a calm and considered way. Clearly this cannot be achieved if they are actively entering into a degree of denial about the situation. (The A-M et al. 2000)

Demonstrate ability to apply relevant nursing knowledge to individualised patient care

The immediate therapeutic problem to be confronted by the healthcare professionals involved is to decide the degree of collusion with the denial that can be ethically employed. (Sugarman J & Sulmasy 2001). To a degree, this is a matter of personal and clinical judgement. Most experienced healthcare professionals would suggest that truth is generally the best policy, the degree of truth however, can be a matter of negotiation. (Parker and Lawton 2003).

The important concept to embrace in this type of situation is that of individualised patient care. In order to come to a considered decision, the nurse must carefully consider all the elements of the patient’s coping mechanisms and assume a holistic approach to the matter. We note that the concept of holistic care can best be visualised with the understanding that the concept of “Health” is based on a translation of the Anglo Saxon word for “wholeness” (or holism). The key to this approach is that it recognises that health has both spiritual and psycho-social elements as well as the overtly physical. (Wright et al 2001)

The main elements of managing Mrs.G ‘s case seem to revolve around the ethical concept of autonomy (Coulter A. 2002). One has to make a professional decision whether or not Mrs.G is considered to have the right to make completely autonomous decisions for herself. In many clinical situations (such as consent, for example), the issue of autonomy is virtually inviolate. There are other situations, and we suggest that this is one, where other ethical principles may take precedence. The Principle of Beneficence suggests that the healthcare professional should effectively do “goodness” or more accurately in these circumstances, as doing what is the best for the patient. (Dordrecht et al. 1983

Demonstrate ability to make own judgment and decisions based upon the evaluation of the nursing situation.

There are a number of nursing models which could be used to construct a response to this situation. They all assimilate the general nursing scheme of assessment, planning, implementation and evaluation. (Fawcett J 2005)

The Roper, Logan, Tierney model (2000) would be appropriate to assess the activities of daily living in a problem solving manner, but this process is primarily of use in those situations that are physically orientated and therefore the psychological denial element is not clearly addressed by this model.

The Roy Adaptation model (Roy 1991) is certainly more useful in explaining the adaptive processes that the patient experiences as they come to terms with the “illness role”. Mrs.G however, did not adapt and, by adopting a strategy of denial, was able to maintain her belief of “wellness” almost until the end, when her illness eventually forced her into accepting it. In real terms, Mrs.G did not adapt at all.

The Johnson Behavioural System model (Wilkerson et al 1996) suits our purposes better as it clearly describes the processes of illness denial, but it doses not combine it with the adaptive processes that eventually overtook Mrs.G at the end of her life.

Wadenstein (et al. 2003) sums up this type of situation with the conclusion that when there is multifactorial aetiology in a given situation there is seldom one nursing model that will encompass all eventualities.


Conclusions

Mrs.J.’s emotional pain of trying to cope with imminent death was clearly too great for her to assimilate. This must be understood by her medical attendants if she is to have a “good death” (Marks-Moran & Rose 1996)

In order to try to provide Mrs.G with the best care that she could have, the clinical staff tried to help Mrs.G towards the realisation that she should confront her own imminent mortality. Unfortunately for all concerned, this proved to be impossible and Mrs.G died about two weeks after her admission, only openly acknowledging the imminence of her death when she became too weak to lift a cup of tea to her mouth on the day before she died. Arguably, when this acceptance came home to her, the nursing staff were actually able to help and support her more than Mrs.G had allowed them to in the preceding two weeks. (Yura H et al. 1998


References

Coulter A. 2002

The autonomous patient.

London: The Nuffield Trust, 2002.

Cuttini, Veronica Casotto, Rodolfo Saracci, and Marcello Orzalesi 2003

In search of a good death: Health professionals’ beliefs may undermine effective pain relief for dying patients

BMJ 2003 327 : 222.

Dean A. 2002 Talking to dying patients of their hopes and needs. Nurs Times. 2002 Oct 22-28 ; 98( 43) : 34-5.

Dobratz, M 2005

Gently Into the Light: A Call for the Critical Analysis of End-of-Life Outcomes. Advances in Nursing Science.

Nursing Care Outcomes. 28(2):116-126, April/June 2005

Dordrecht: Kluwer. Beauchamp, T. and Childress, J., 1983,

Principles of Biomedical Ethics, 2nd edition.,

New York: Oxford University Press. 1983

Fawcett J 2005

Contemporary Nursing Knowledge: Analysis and Evaluation of Nursing Models and Theories, 2nd Edition

Boston: Davis & Co 2005 ISBN : 0-8036-1194-3

Marks-Moran & Rose 1996

Reconstructing Nursing: Beyond Art and Science

London: Balliere Tindall October, 1996

Parker and Lawton 2003 Psychological contribution to the understanding of adverse events in health care Qual. Saf. Health Care, Dec 2003; 12: 453 – 457.

Roper, Logan and Tierney (2000)

Activities of Living model London : Churchill Livingstone 2000 ISBN 0443063737

Roy C 1991

An Adaption model (Notes on the Nursing theories Vol 3)

OUP: London 1991

Seale C, van der Geest S. 2003

Good and bad death: introduction.

Soc Sci Med. 2003. 58 (5) : 883–885.

Sugarman J & Sulmasy 2001

Methods in Medical Ethics

Georgetown Univeristy Press 2001 ISBN: 0878408738

The A-M, Hak T, Koeter G, Wal Gvd. 2000

Collusion in doctor-patient communication about imminent death: an ethnographic study.


BMJ

2000 ; 321 : 1376-1381

Wadensten & Carlsson 2003

Nursing theory views on how to support the process of ageing

J. of Advanced Nursing Volume 42, Number 2, April 2003, pp. 118-124(7)

Wilkerson, S. A., & Loveland-Cherry, C. J. (1996).

Johnson’s behavioral system model. In J. J. Fitzpatrick & A.L. Whall (Eds.),

Conceptual


models of nursing: Analysis and application

(3

rd

ed., pp. 89-109). Stamford, CT: Appleton & Lange. 1996

Wright S, Sayre-Adams J. 2001

Sacred space: right relationship in health and healing: not just what we do but who we are. In: Rankin-Box D, ed. The nurses’ handbook of complementary therapies. 2nd ed.

London: Baillière Tindall, 2001.

Yura H, Walsh M. 1998

The nursing process. Assessing, planning, implementing, evaluating. 5th edition. Norwalk, CT: Appleton & Lange, 1998.

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9.5.06 PDG Word count

ESL students in nursing programs Research Paper.

ESL students in nursing programs Research Paper.

This is a presentation about what can nursing programs do to promote the success and prevent attrition of english as a second language students in nursing programs. The presentation should be mostly based in the paper that i am attaching along with newer information that will be researched by the writer. I am also attaching the grading rubrick. in a five-to-six page paper explaining how the project addresses each of the elements in the grading rubric below. The paper should be formatted in APA 6th edition style and include any references. Materials used for the teaching project, such as handouts, PowerPoint presentations, and evaluation materials.

qualitative research and quantitative research

Hello class,

Qualitative research and quantitative research have both made vast contributions to the field of nursing. Although these two types of research are very different, they also hold some similarities as well. When conducting a quantitative research study, the researcher is trying to come to a conclusion that is not debatable. The outcome is a matter of fact and there is no questioning the truth of the outcome. For example, the researcher is conducting a study on the breakdown of the US population by age. There is a certain number of people per each age group and there is no opposition to the outcome. By definition, quantitative research, “involves the process of objectively collecting and analyzing numerical data to describe, predict, or control variables of interest. The goals of quantitative research are to test causal relationships between variables, make predictions, and generalize results to wider populations” (McLeod, 2019).          Qualitative research is “the process of collecting, analyzing, and interpreting non-numerical data, such as language. Qualitative research can be used to understand how an individual subjectively perceives and gives meaning to their social reality.” (McLeod, 2019) Data for this method of research can be done, for example, through surveys. In that survey, let us ask the question of, “How do you like to celebrate your birthday?” There is no expected outcome and the researcher is not trying to prove anything correct or incorrect. It is more of an open-ended question. While researching these different methods of research, one source mentioned a strength of qualitative research that is powerful, that strength is, “Qualitative methods that allow researchers to explore the views of homogeneous as well as diverse groups of people help unpack these differing perspectives within a community” (Choy 2014) Regardless of which method is used, there are pros and cons to each depending on what the subject of the study really is and each method has contributed greatly to the field of medicine.

Choy, L.T. (2014) The Strengths and Weaknesses of Research Methodology: Comparison and Complimentary between Qualitative and Quantitative                Approaches. IOSR Journal of Humanities and Social  Sciences.                                                                                                                               https://www.academia.edu/27908525/The_Strengths_and_Weaknesses_of_Research_Methodology_Comparison_and_Complimentary_between_Qualitative_and_Quantitative_Approaches?from=cover_page

McLeod, S. (2019). What is the Difference between Qualitative and Quantitative Research? Simply Psychology.                                                                       https://www.simplypsychology.org/qualitative-quantitative.html

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Select a speaker who shared their story of recovery in the Psy8430: Portrait of Addiction video viewed in Unit 2. Assume that they present for treatment as they were when they were early in recovery with their family or significant other.

Select a speaker who shared their story of recovery in the Psy8430: Portrait of Addiction video viewed in Unit 2. Assume that they present for treatment as they were when they were early in recovery with their family or significant other.

Describe how a specific systemic treatment approach could be used to assist the couple or family and how it might be applied given what the speaker describes of their life before recovery. (Note that the speakers are identified by name at the end of the film at 53:40.)

Response Guidelines

Respond to the main discussion posts of two learners. What reactions do you have to the ideas they have presented? Include examples from the course readings or your own experience to support your perspective, and raise questions to continue the dialogue.

Resources

· Discussion Participation Scoring Guide.

· Portrait of Addiction. | Launch Presentation.

Please S25.00 for the Assignment. Due (Monday) 2/12/2018.

Discuss any relevant history related to the legislation, pertinent votes, and issues that are stalling the legislation, etc.

Discuss any relevant history related to the legislation, pertinent votes, and issues that are stalling the legislation, etc.

Select an active bill at the state or federal level that impacts the professional practice of nursing. In a 3-4 page paper (excluding the title and reference pages), summarize the provisions of the bill and clearly explain what the bill will accomplish. The paper should be no more than 4 pages, typed in Times New Roman using 12-point font, and double-spaced with 1″ margins.

Your review of a bill paper should:

Discuss the major provisions of the bill.
Demonstrate an in-depth understanding of the legislation by explaining the background and all relevant facts.
Discuss any relevant history related to the legislation, pertinent votes, and issues that are stalling the legislation, etc.
Use primary sources for this information.
Identify key supporters and those who do not support the bill. Explain why some of these individuals support the bill and why some do not.
Explore the positions of the key stakeholders in the bill, both pros and cons. Do not make assumptions about potential key stakeholders. Examine this area carefully so you are correctly reflecting the stakeholders positions.
Discuss how the bill would impact a nurse’s ability to provide safe and quality care or to practice to the highest scope of the nursing license.
Explain specific actions that nurses can take to assist with the passage or defeat of the legislation
Use APA format, headings and references as appropriate.

Hazards of Hypoxia in Aviation


Introduction

Hypoxia as related to human physiology describes a condition where there is an insufficient supply of oxygen to the body. Each of the billions of cells that make up the human body requires an adequate supply of oxygen for survival and optimum functioning. The supply of oxygen to all the cells is accomplished by the distribution of the oxygen in the air that we breathe-in being transferred into blood circulation through the alveolar (air-sac) epithelium of the lungs and carried by blood to all parts of the body. Although there are many situations where the body could become hypoxic, the cause that is relevant to aviation is the decrease in the amount of oxygen that is inhaled and transferred to the blood circulation, encountered by pilots when flying at high altitude. This essay discusses several aspects of the hazards of ‘hypoxia’ as it relates to aviation, its physiological effects on pilots, why it remains a threat even today and the available preventive measures to minimise the exposure to hypoxia.


High Altitude Atmosphere

Planet earth’s atmosphere is a mixture of gases comprising nitrogen (78%), oxygen (21%) with carbon dioxide and other rare gases making up the remainder. The layers of air in the earth’s atmosphere exert pressure, referred to as ‘atmospheric pressure,’ which understandably, is more on the earth’s surface and gradually lessen as we move away from the earth, deeper into the atmosphere, because the air gets lighter. The unit of measurement of atmospheric pressure is pounds per square inch (psi) or millimeters/inches of mercury (mmHg/inHg). Atmospheric pressure at sea level is 14.7 psi, or 760 mm/Hg.

In terms of human tolerance, three atmospheric zones have been recognized. They are the physiological zone at or closer to round level, the physiologically-deficient zone at high altitude and the space-equivalent zone (Alaska Air Medical Escort Training Manual). In the physiological zone that extend from sea level to 10,000 feet above sea level, despite the lowering of air pressure to about two-thirds of that at sea level, the oxygen partial pressure is adequate to support normal breathing in a healthy person without the need of oxygen supplementation.

The next zone that extends from 10,000 to 50,000 feet above sea level is quite risky to humans without breathing support. For example, at 50,000 ft altitude, the atmospheric

pressure is about 10% of that at sea level, with a corresponding decrease in oxygen partial pressure. This causes difficulties in inhaling enough oxygen as well as in the transfer of the relatively little oxygen in the lungs to the blood stream, leading to hypoxia. Above 50,000 feet altitude is what is called space-equivalent where humans cannot survive without the supply of an artificial environment.

The oxygen in the inhaled air, when carried to the air sacs in the lungs, gets to the bloodstream by a mechanism that is facilitated by the difference in oxygen partial pressure between the air sacs and the blood. The greater this pressure difference is, it is easier for oxygen molecules to transfer across the barrier. As the altitude increases the atmospheric pressure decreases, with a decrease in the partial pressure of oxygen. This makes the pressure difference between the air in the lungs and in the blood vessels (arteries) lower making it harder for the oxygen to transfer across the alveolar membrane and get into the bloodstream. For example, at sea level the alveolar partial pressure of oxygen (pO2) = 100mm, blood vessel pO2 = 40mm. Therefore, the gradient (difference) = 60mm. At 10,000ft altitude, the alveolar pO2 = 60mm and blood vessel pO2 = 26mm, with the gradient reduced to 34mm. It should be noted that the percentage of oxygen in the air at high altitude remains the same as at low altitudes but, the low partial pressure means that relatively fewer oxygen molecules are inhaled when breathing.


Physiological effects of hypoxia

Hypoxia is of special significance for those engaged in aviation (Cable, 2003). In general, aircrews do receive training in hypobaric chambers that provide similar conditions to 25,000 feet or greater altitude. They are trained to identify symptoms of hypoxia and instructions on how to respond. At high altitudes, the bodily reactions occur because the body attempts to compensate for the low oxygen supply. The immediate response is hyperventilation – an increase in the breathing rate as well as depth of each breath (gasping for breath) to increase the volume of air taken with each breath. There is an increase in heart rate, as the body tries to achieve enough oxygen supply to various vital organs. Many researchers have observed fluid collection in the lungs. This happens because the pressure in the blood vessels that surround the lungs increase causing effusion of fluid into the lungs (Cremona et al., 2002).


Altitude sickness

What is called altitude sickness is actually the physiological reaction by the human body to the environmental change from low altitude to above 8,000 feet (2,400 metres). It was a French physiologist

Paul Bert

who first demonstrated that this reaction is due to the deficiency in oxygen supply to the vital organs of the body (cited by Ghosh and Pant, 2010). The signs and symptoms of hypoxia include loss of peripheral vision, skin sensations (numbness, tingling, or hot and cold sensations), cyanosis (skin becoming bluish due to the accumulation of less oxygenated blood), euphoria, and eventually unconsciousness (Nishi, 2011). One of greatest dangers is the likelihood of the impairment of cognitive functions almost with the appearance of the first symptoms of hypoxia, resulting in possible inability to take any remedial action (Van Puyvelde et al., 2017).

The following case study reported by Ghosh and Pant (2010) illustrates the usual symptoms that a pilot exposed to hypoxia would experience. A test pilot of the Indian Air Force was scheduled to fly a high-altitude sortie. He took off in a modern combat aircraft, in suitable clothing; an Anti ‘G’ suit, Alpha Helmet and oxygen mask. He was flying at 46000 ft altitude (cabin altitude equivalent of 18,000 ft), when he felt a slight tingling on the left side of the upper lip. He responded by tightening the mask. Quickly the upper lip became numb. He switched the regulator to 100% Oxygen and then to overpressure position to deliver 100% oxygen at 2-3 mm Hg pressure. Still the symptoms didn’t go away, instead he also was developing a headache and a slightly dimmed vision. The pilot realized the danger and started immediate descent and reached 8000m altitude but, symptoms did not disappear. The sortie was aborted and descent to land initiated. The pilot recovered at about below 3000 m altitude.

Although hypoxia can occur at less than 10,000 feet altitude, it is generally not considered as a major problem for aviators (Department of Defence, 1998; Air Force Flights Standards Agency, 2006). In military helicopters without a pressurized cabin, pilots without oxygen supplement are permitted to fly at/up to 10,000 ft (or at up to 13,000 ft for 2 hr) by the Japan Air Self-Defence Force (JASDF) (Japan Air Self Defence Forces, 2002). In the United States Air Force (USAF), pilots can fly continuously up to 10,000 ft, up to 12,500 ft for 1 hr, or 14,000 ft for 30 min, without supplemental oxygen. Nonetheless, hypoxic incidents have been reported in flights even at below 10,000 ft. A report made to the Director of Flying Safety of the Australian Defence Force about incidents of hypoxia for the period 1990–2001, indicated that 4 out of a total of 27 incidents occurred at altitudes of less than 10,000 ft (Cable, 2003). Similar study by Smith (2005) reported that 40 of the 53 Australian Army helicopter pilots that were surveyed have experienced symptoms of hypoxia at less than 10,000ft altitude.

Schindler (2017) has drawn attention to the need to address hypoxia issues in relation to general aviators, considering that there are almost 600,000 certified general pilots (not engaged in military or commercial aviation and operate their own aircrafts for personal travel or recreation), in the US. Reporting an analysis of 130 hypoxic events reported by general aviators found the commonest symptoms experienced to be light-headedness (39%), headache (29%) dizziness (18%) and mental confusion (16%). Furthermore, the author drew special attention to the fact that most hypoxic incidents among general aviators go unreported and found that almost 70% of general aviators have had no hypoxic training.


In-flight hypoxia – Still a worry

The first recorded aviation victims of high-altitude hypoxia were two young French scientists Croce Spinelli and Sivel who in 1875 attempted to reach a 26,200 ft altitude in a balloon (Ghosh & Pant, 2010). Almost 150 years later. hypoxia continues to be major safety concern for aircrews who operate high altitude flights. Most recent incidents have been due to failure of pressure cabin or failure of the oxygen delivery system. The latter may be the result of inefficient ground servicing, mechanical failure of oxygen equipment, or an ill-fitting mask. Oxygen deficiency during flying not only causes fatalities but also reduces military capabilities. USAF data have shown that there were 10,700 reported incidents attributable to hypoxia during the second world war period 1941-45. Hypoxia incidents were responsible for 110 deaths and the abandoning of 1% of sorties, without accomplishing their missions (Gosh & Pant, 2010).

With the use of aircrafts that can fly faster and higher, preventing in-flight hypoxia has gained increased attention. The development of aircraft oxygen systems and their improvement have been very effective in addressing this concern. The first practical automatic oxygen delivery system was Dreyer’s apparatus designed by Col George Dreyer of British Royal Air Force (Gosh & Pant, 2010). These oxygen delivery systems became mandatory in 1919, for All US planes flying at high altitude. Research and development efforts since then helped in building the sophisticated aircraft oxygen systems that are currently in use. Despite the availability of such advanced and sophisticated systems, in-flight hypoxia still occurs, albeit less frequently.


Causes of Accidents

As mentioned earlier, most modern day in-flight hypoxia incidents are reported as due to failure of oxygen systems. The risk of accidents is increased because of the difficulties in recognising hypoxia symptoms for a person never exposed to it and the fact that more serious effects can happen so quickly leaving no time for corrective action. The subject would become unconsciousness and lose control of the aircraft. This is what was suspected to have happened in the October 1999 death of the world-famous golf champion – Payne Stewart, and four others. The crash of the Learjet they were flying was attributed to loss of cabin pressure resulting in the occupants becoming unconscious (The Guardian, 26

th

October 1999). Apparently, the jet flew out of control for 1,500 miles at 45,000 ft altitude and crashed on a rane of mountains in South Dakota, USA.

Cable (2003) analysed the hypoxia incidents between 1990 and 2001 in the Australian Defence Force reviewing all cases by aircraft type, number of occupants, number affected by hypoxia, deaths, symptoms experienced, and the altitude of incidence. Twenty-seven hypoxia incidents, involving 29 aircrew, had been reported. Unconsciousness occurred in only two one of whom died. Fighter and training jets with aircrew supplied with oxygen equipment were mostly (85%) involved, and mostly occurred between 10,000 and 19,000 ft. Mask or regulator failure including mask leaks accounted for most (63%) of incidents. Symptoms involved cognitive impairment or light-headedness as reported by aircrews. Aircrews were able to recognize the symptoms in majority (75.8%) of these episodes because they have received hypoxia training.

In another report (Gradwell, 2006), analysing 397 incidents of hypoxia reported to the British Air Force, found 57% of all cases were due to failure of oxygen regulator and cabin decompression. Other causes included breaks in the hose connecting the regulator and mask and face mask defects.Similar issues have been reported as the causes of oxygen supply problems leading to aircrews being exposed to dangers of hypoxia in the Australian study by Cable (2003).

There have been several incidents involving commercial flights too. The biggest disaster proven to be due to hypoxia-related incapacitation of the aircrew in a commercial flight is what happened to the Helios Airways Flight 522 on 14 August 2005 from Larnaca, Cyprus, The aircraft crashed into a mountain in Greece, 3 hours into the flight (Sgobba, 2014). The Air Traffic Control at Nicosia, after failing in repeated attempts to contact the aircraft, sent two F-16 fighter aircrafts. They did make visual contact with Flight 522 and reported that the first officer was slumped motionless at the controls while the captain was not at his seat. They also saw the freely dangling oxygen masks in the passenger cabin oxygen masks with no evidence of any movin passengers. Minutes later, both engines the plane crashed killing all 121 passengers and crew.

The disappearance, in March 2014, of the

Malaysian Airlines Flight 370

, a 777 carrying 239 people flying from Kuala Lumpur to Beijing, too is suspected as a hypoxia-related incident according to some experts. Evidently, the aircraft has changed course and travelled in southern direction, and experts think that it may have flown for up to seven hours on autopilot, run out of fuel and crashed into the Indian Ocean. They theorize that hypoxia caused by rapid decompression, just like what happened to Helios Flight 522 in Greece, must have been the reason (Sgobba, 2014).


Preventive Measures

Hypoxia from altitude exposure happens because of the lowering of oxygen partial pressure in the lungs to less than 60 mm Hg (Pilmanis, 2003). Therefore, civilian and military regulations make it mandatory for providing supplemental oxygen when flying above 10 000 feet of aircraft or cabin altitude. Sea level equivalent of oxygen can be attained by increasing the percentage of oxygen in the breathing gas, using an oxygen apparatus, up to an altitude of 34 000 feet. Positive pressure breathing with 100% oxygen is required above 40,000feet altitude (Pilmanis, 2003).

The development of aircraft cabin pressurisation system was a major breakthrough in efforts to safeguard against hypoxia (Pilmanis, 2003). Most modern aircrafts are pressurised. However, it has been reported that many civilian and military aircrafts do operate at times with no pressurising mechanisms. This is particularly common among general aviators who fly as high as 30 000 feet unpressurised. Oxygen equipment for hypoxia protection for such aircrafts range from simple nasal cannulas at lower altitudes to highly sophisticated regulators and masks at the higher levels. Large civilian and military passenger and cargo planes are equipped to maintain a cabin pressure that is equivalent to that of air at 4000–8000 feet altitude (Pilmanis, 2003). These large planes have a large cabin space and therefore, the effects of an accidental loss of cabin pressure develops slowly, so that there is plenty of time for the aircraft to descend to lower altitude. In contrast, in military aircrafts such as fighter jets and reconnaissance aircrafts cabin volumes are smaller and therefore, can lose cabin pressure very rapidly.

Following are some of the recommendations to reduce the incidents of in-flight hypoxia (Ghosh & Pant, 2010); The risk of hypoxia for aviators is real and therefore, this needs to be emphasized in all training programmes and manuals. Additionally, there is a need for the strict adherence to what is described as “oxygen system discipline” which includes taking a serious note of the dangers of hypoxia and knowing how to recognise and what to do in an incidence. All crew members must be aware of the potential for failure of oxygen delivery systems and therefore must be fully conversant with properly fitting of masks, importance of helmet mask compatibility, how to check and correct leaks, oxygen equipment checks, both pre-flight and in-flight. The importance and relevance of hypoxia training is evident from the findings that many pilots have averted disaster by being able to recognize symptoms early and take timely corrective action. It is equally important to ensure that each and every hypoxia incident is recorded, the information from which can be extremely useful in building strategies for continuous improvements in effective preventive strategy.


Conclusion

Considerable improvements have been made in aircraft pressurization systems and oxygen delivery systems, improving their performance and reliability enabling the protection of aircraft cabins to safeguard crews and passengers against hypoxia. However, the potential risk of hypoxia is still present as evident from recently reported incidents and unpublished reports that are confined to aviation agencies. The good news is that incidents are less frequent compared to the occurrences a few decades ago. Yet, there is no room for complacency and the safety of the pilots and those accompanying in an aircraft must be ensured always. The objectives of precautionary measures must be to meet the aviators’ physiological needs under all types of conditions like altitude, acceleration, temperature, and workload. The system testing must be done under simulated operational conditions across full range of anticipated use.


References

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    Multidisciplinary Respiratory Medicine

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    Indian Journal of Aerospace Medicine,

    vol.54, pp. 6-12.
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The Evolution Of Telemedicine Health And Social Care Essay

Who would have ever imagined that a doctor’s visit could be conducted through a phone-line, video, or the use of a computer 1000 plus miles away? Medical records can be view by another medical professional for a second opinion three counties away before you arrive. A radiologist in Singapore has diagnosis your femur fracture here in the United States. Medical diagnosis, treatment and consultations are being performed from miles away because of technology. It seems as if there is no limitation to the well being of a patient through a wide range of telemedicine services.

What is telemedicine?

According to the American Telemedicine Association “telemedicine is the use of medical information exchanged from one site to another via electronic communications to improve patients’ health status. Emails, videoconferencing, transmission of still images, e-health including patient portals, remote monitoring of vital signs, continuing medical education and nursing call centers are all considered part of telemedicine”.(http://www.americantelemed.org) This interactive form of medical services has provided healthcare to individuals many miles away or minutes away in the comfort of their homes, physician offices and hospitals.

Ways to communicate services

Store-and -forward is a means of transmission of medical information to other medical professionals and facilities that will provide the recipient pertinent medical history, vital signs, medical records, lab results and images. “Store-and-forward telemedicine systems have the ability to capture and store digital still or moving images of patients, as well as audio and text data. A store-and-forward system eliminates the need for the patient and the clinician to be available at the same time and place. Store-and-forward is therefore an asynchronous, no interactive form of telemedicine. It is usually employed as a clinical consultation (as opposed to an office or hospital visit)”. (http://www.ahrq.gov) One of the major concerns with store and forward is whether it is as effective as face to face medical visits, does it have comparable outcomes, is it appropriate for appropriate medical management, is the patient truly satisfied with the outcome and level of services and is it cost effective? There are several benefits of store-and-forward technology. Patients in rural areas are able to be seen by specialty physician miles away when there is limited access to the services in the area. The store-and-forward of medical information is also being used with emergency response teams to communicate the information to the emergency room staff for an efficient transfer of vitals and medical status. The store and forward technology is said to be the least expensive way to communicate and the most accurate in real time for patients at a distance needing medical consultation. Another type of store and forward technology is videoconferencing technology. The two way television allows two doctors in two different areas to communicate to provide treatment, a diagnosis, or telesurgery. There are several healthcare areas that benefit from telemedicine

Some of the common teleservices

Telemedicine includes several medical disciplines that benefit from the services. Services like radiology, dermatology, nursing, pharmacy, pathology, neurology and psychiatry. The need for a second opinion in healthcare has seen a demand, and the shortage of specialty doctors in rural areas increased. The development of telemedicine has benefited the patient in many ways because of technology.

Teleradiology- is the transmission of x-ray, CT, MRI, PET, and SPEC images that can be read by radiologist in another facility or country. The information is sent via the store and forward process of telemedicine. Large and small hospitals have began to use teleradiolgist to cut down on expense and having access to immediate diagnosis.

Teledermatology- is the use of video conferencing and store and forward images to provide a consultation for an individual that requires a dermatologist. There have been concerns with the consistency of this tyoe of visit for patients due to unclear images of the skin and the possibility of not having that face to face visual from the dermatologist to make an adequate diagnosis.

Telenurse- the use of phone, electronic email, videoconferencing, and computers to provide healthcare services or consultation to a patient. Telenusring has continued to grow in the areas of telephone triage for health insurance carriers. Telenursing has grown with interactive patient training related to changing wound dressings, insulin administering, self management of a patient’s health.

Reimbursement

Many of the healthcare providers must follow certain guidelines to receive payment for telemedicine. According to Medicare “it’s condition for payment must include an interactive audio and video telecommunications system that is used and must permit real-time communication between the physician or practitioner at the distant site and the beneficiary at the originating site. The medical providers that are covered under this fee for payment are services rendered by a physician, nurse, physician assistant, midwife, clinical nurse specialist, or clinical psychologist.

The current list of Medicare telehealth services includes:

Consultations

Office or other outpatient visits

Individual psychotherapy

Pharmacologic management

Psychiatric diagnostic interview examination

End-Stage Renal Disease (ESRD)-related services

Neurobehavioral status examination

For ESRD-related services, at least one face-to-face, “hands on” visit (not telehealth) must be furnished each month to examine the vascular access site by a physician, NP, PA, or CNS. (http://www.cms.hhs.gov)

New Trends in telemedicine

Trends observed nationally include:

using telemedicine in correctional facilities and home health care settings, can significantly reduce the time and costs of patient transportation;

providing additional services to rural area

linking physicians together more efficiently

linking hospitals and schools together to improve care and widespread

The benefits

With a growing population and healthcare on the rise many public and private medical providers have seen a cost reduction with the use of telemedicine and patients have benefited from the technology in telemedicine. Insurance providers are paying for less hospital in patient days because the patient can be monitored from a distance. The patients are able to communicate with a nurse or physician at home through phone, video, or Bluetooth monitoring. Telemedicine allows more freedom to the patient to feel less restricted to home visits, they have access to some providers 24 hours a day and it cuts down on their travel time to medical visits. The patient’s family has also displayed satisfaction from the use of telemedicine because it’s less strenuous on their travel time and loss of work days. Another benefit of telemedicine provides an outreach to rural areas to be included in clinical trial studies and procedures. The providers have also benefited because they are able to receive real time feedback from other professionals that are able to transmitted medical information quickly, decreased travel time, and continued patient education and communication.

Issues that need to be addressed

Education regarding telemedicine and it’s usage. There are concerns that many do not know that he services exist.

Cost and evaluation of the services. Will the cost for reimbursement be lower because there is no face to face contact? How will the affects of technology increase cost?

Liability and malpractice issues.

Out of state practices of medical professionals crossing their licensed boundaries. How will they be regulated and which state laws and rules will they be governed under?

Security is always a concern regarding information sent via phone and internet lines. Can medical information be protected properly and the doctors will be held liable for the misappropriation of a patient’s medical information. Although there are HIPPA laws regarding patients privacy according to ORTCC “it’s much more difficult to guarantee confidentiality because several individuals outside the traditional medical team. The transmission procedure requires technical staff at both ends. In small communities, it is possible that the patient knows the nonmedical personnel socially, compounding the sense of loss of privacy. Thus, the nature of the doctor patient relationship changes dramatically with telemedicine, challenging traditional concepts of privacy and confidentiality”. (http://www.ortcc.org)

Conclusion

With technology making waves telemedicine has been able to grow through leaps and bounds allowing those that are limited and restricted to receive the medical attention of medical professionals. Physician has gain quicker access to other professionals without sitting face to face, digital images, and audio files of heartbeats and fetal movements. The privacy, protection, reimbursement, malpractice, and governing laws are still a concern but the efficiency of communication to provide medical care is needed.

Analyzing Parametric Statistics


Doctor of Nursing program


Analyzing Parametric Statistics

You locate a quasi-experimental research study as possible evidence to support a practice change. You notice that the study aims to make a prediction that relates to correlation between study variables. The study sample size is large and normally distributed. Reflect upon this scenario to address the following.

· In your appraisal of the evidence, you note that an independent variable is not present and that a Spearman’s ranked correlation is used to analyze data. Is this the correct level of correlational analysis? Explain your rationale.

· Are association and correlational analysis equivalent in determining relationships between variables?

· Do these findings impact your decision about whether to use this evidence to inform practice change? Why or why not?

Reading:

Polit, D. F., & Beck, C. T. (Eds.). (2017).

Nursing research: Generating and assessing evidence or nursing practice

(10th ed.). Wolters Kluwer.

· Chapter 16: Descriptive Statistics

· Chapter 17: Inferential Statistics

· Chapter 18: Multivariate Statistics

· Chapter 19: Processes of Quantitative Data Analysis

· Chapter 20: Clinical Significance and Interpretation of Quantitative Result

1 page-no spacing, Times new Roman. APA format

At lest 2 references -must be within 5 yrs.

Absolutely plagarism free.








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