Sleep Medicine | Sleep Scholar

Study links abnormal sleep and schizophrenia for the first time

January 1, 2012 by Randy Clare Leave a Comment

By Christian Shepherd The Oxford Student Last updated: 16:07, 01/01/2012

A study by Oxford researchers of schizophrenia patients has found a link between sleep disruption and schizophrenia independent of medication and social isolation.
The study was the first of its kind in that it looked at the sleep-wake patterns of schizophrenia patients in the community rather than in hospital and over a period of weeks rather than a period of days.

Researchers suggest that the stabilization of sleep-wake patterns may be important in the treatment of schizophrenia and that a stabilized pattern could help patients become less social isolated.

Head of the research group Professor Russell Foster said: “For a long time people have noted that sleep is disrupted in mental health but it has always been assumed to be associated with medication or the fact that they are socially isolated and, as a result, it has been largely dismissed.”
Foster continued: “We have now shown in humans that there is a profound disruption of sleep wake timing. It is the first time that this has been quantified in a cohort of patients. It also seems to be independent of the drugs that they are on and independent of any form of social isolation, such as the lack of a job.”
According to Foster the most important thing to note about sleep-wake timings is that they are “more than just the inconvenience of not sleeping at the appropriate time of day. They have been associated with a whole raft of additional problems.”

These problems are not only social issues of isolation and difficulty in interaction but include immune dysfunction, cognitive disruption and metabolic abnormalities.
“If you can stabilize sleep-wake in these patient groups then you will hopefully mitigate, and maybe even eliminate, some of the comorbid (secondary) pathologies that you find in mental health.”

Second year experimental psychology student Roseanna Sharville said: “Like food and water, sleep is crucial for all living, breathing things. Intuitively, therefore, it certainly seems possible that long-term sleep disturbances could cause severe physical and mental health problems.”
The importance of the findings is supplemented by Foster’s statement that “one in every hundred members of the public is likely to have schizophrenia”.
“The mental health burden to the economy is greater than the cancer burden. Since its effects are long term and impact on family and carers also,” he continued. “We haven’t had any major innovation in mental health in years.”

Foster described possible methods of stabilizing sleep-wake patterns, which involve “trying to impose a temporal order on these individuals” by “stabilizing the light dark cycle and stabilizing the time that they eat”, as well as the use of drugs such as melatonin, which has been “shown under certain circumstances to stabilize sleep-wake in certain individuals with conditions where sleep can be disrupted, such as bilateral eye loss, but might also apply to patients with schizophrenia”.
The study has also has raised a much bigger picture about the nature of the link between mental health problems and sleep-wake abnormalities.
Foster notes how “most people ask ‘Is it cause and effect?’, but I don’t think you can really think about it in that way any longer. I think you have to think about it as common neurotransmitter pathways that are being affected.”

Foster describes a follow up study on mice where gene abnormalities previously linked to schizophrenia are created in mice to see whether “you would also have a big affect upon the sleep wake profile of the mouse and in the paper that has just been accepted, that is exactly what we see.”
The results of the work are not only applicable to schizophrenic patients but are “part of big and really exciting picture”.

According to Foster, the study is also the basis for a big initiative to look at “sleep-wake timings in mental health generally”, with preliminary data suggesting that “we might be able to use sleep as a predictor of impending psychiatric illness. If you have an early indicator then there is chance of going in early”.
Sharville said how the study would either “have led to a breakthrough in the study of this, and other, mental disorders”, or will have “encouraged the treatment of sleep difficulties in schizophrenic patients, no doubt improving the lives of the many suffering from this debilitating, and often terrifying, disorder.”

Filed Under: sleep medicine

Spotlight on Sensors

February 17, 2011 by SleepDT Leave a Comment

Obtaining Accurate Signals

At the base of all sleep units, the question is essentially the same: Is what you see on the screen an accurate reflection of what is physiologically going on with patients? The recorded and displayed signals have meaning to the trained eye, but are they reliable? If you can’t trust your equipment, or know how to effectively use it, says Bradley, you have a fundamental problem. Sensors are the primary piece of equipment for obtaining signals and they must accurately reflect the physiological event being measured.

All sensors have limitations, and those limitations must be understood. Without proper understanding, you cannot expect to obtain accurate signals. The same type of sensor can use different technologies to give you a signal.

Accurately assessing the chest and abdominal effort of breathing is a basic function. When sensors are plugged into a PSG system, some technicians are simply hoping the filters and sampling rates are set right and that the sensor is working according to what they need. “The information comes up on the screen and you take that as gospel,” says Bradley, who in addition to his role as founder also serves as chief technology officer at Braebon. “But is that really what is happening? Is there effort happening on the chest and abdomen? One cannot answer that question without having a basic understanding of the technology involved.”

Quality Sensors Matter
There are many technologies and methods for measuring airflow: pressure sensors; thermal sensors; and esophageal balloons to name three. Whatever method is used, Bradley contends that quality matters. “I could go out and buy the cheapest pressure sensor, and then I could buy a more expensive one,” says Bradley.

“If you put a cannula on the patient and feed it simultaneously to both pressure sensors, you will see two totally different signals—yet people think if it is a pressure sensor, they are measuring accurately.”

In fact, the signal from the lower quality unit will be heavily filtered, as well as baseline shifted, leading to inferior and possibly inaccurate information—which in turn can lead to a poor diagnosis. On the other hand, more expensive sensors may yield a more realistic representation, but require more initial effort to set up on the PSG system. “This isn’t necessarily always the case,” cautions Bradley. “It just goes to show that you need to understand the technology being used and see if you are getting the signals you want.”

The effort could be worth it, because once the technology is understood better, increased accuracy will likely follow. Troubleshooting time will be reduced, and patient setup will be faster. That accuracy, says Bradley, will ultimately lead to better interpretations and improved patient outcomes.

Inaccurate data collection during the sleep study causes a domino effect that wastes the time of all concerned. Manufacturers can halt this chain reaction through renewed efforts to educate technicians about what is really going on with their devices.

In keeping with this philosophy, Braebon started offering courses to train people on the technology and show them simple techniques that can improve patient care. “For example, if you are measuring a breathing signal, don’t set the low frequency filter at 1 Hz simply because it looks nice,” says Bradley. “I’ve seen techs do that. We are also trying to improve the understanding of piezo-electric pressure sensors. The less expensive ones do not have the frequency response necessary to indicate UARS—that is, the sensor inside does not have the frequency response capability to give you an accurate signal. The signal will have premature decay because of the technology used.”

You Get What You Pay For
In sleep medicine as in life, price typically goes up with quality. More expensive pressure sensors have batteries and the technology inside to give accurate signals. “As an example, if there is constant flow as in UARS, then you should see a plateau or flattening in the signal,” explains Bradley. “In the piezo (non battery) type pressure sensors, you will not see this flattening. You will see a significant decaying of the signal to the zero baseline. This is due to the poor frequency response of the sensor technology used with respect to the physiological event being measured. In the end, paying a bit more for higher quality technology may be worth it.”

Technicians typically want sensors to have a frequency response similar to that shown in Figure 1. In this illustration, the sensor is able to output the entire input signal at all frequencies. However, Bradley points out in Figure 2 that typical piezo sensors only output signals in a specific frequency band. There is a usable region for this type of sensor, and this is why piezo sensors make good snoring sensors and poor respiratory effort sensors.

ScreenShot051 Spotlight on Sensors

If a patient inhales and holds his breath, we want to see that signal. A piezo-based sensor will show the signal decaying to zero fairly rapidly. This is why they are not the greatest for measuring UARS. Figure 3 shows the outputs from a piezo-based pressure sensor and a Braebon PT1 pressure sensor. Both sensors were simultaneously connected to the same patient. One can see the decay in the UARS, the poor quality in the snoring signal, and the shifted baseline in the Piezo-based sensor compared to the PT1 signals.

ScreenShot052 Spotlight on Sensors

Merely paying attention to these differences is often a foreign concept, and that can also be the case with snoring. In determining snores per hour, Bradley again casts a skeptical eye on much of the industry’s existing technology. If you have the number of snores per hour, asks Bradley, then what about the effect in magnitude i.e. volume? Is it not important to know the actual change in volume when a patient undergoes therapy? That is one reason why Braebon developed the Q-Snor, as well as placing this technology within the MediByte portable sleep screener.

Within the three main types of technologies used to determine snoring, technicians can access sensors that qualitatively measure vibrations on the neck, or qualitative auditory signals, or quantitative auditory signals. “The vibratory signal may contain movement artifacts such as cardiac pulses or head movements,” explains Bradley. “The qualitative or quantitative audio sensor may contain external artifacts such as talking. It is the quantitative audio sensor that can give us the most valuable information related to snoring in the patient. The quantitative audio sensor (Braebon Q-Snor) allows you to do a proper pre- and post-comparison of both snoring indices and change in overall volume in patients. This is paramount if one is to assess the effectiveness of certain types of therapies.”

Bradley explains that understanding sensor technology is paramount in ensuring the collection of accurate signals. As an example, piezo technology cannot measure events with low frequency content. At 10 Hz or higher, a piezo sensor responds acceptably well to what is going on. “If, however, you are looking to measure respiratory effort in patients with breathing rates of between 6 to 30 breaths per minute, and look for relative amplitude changes for each breath, a piezo sensor cannot give you what you need.” explains Bradley. “An accurate signal refers to not only the sensor’s ability to react quickly enough to the physiological event being measured, but to also output a signal that should be linearly proportional to the physiological event being measured.

“If I inhale and then exhale quickly, you won’t see the proper signal with a piezo-based sensor,” continues Bradley.

“There will be a slow decay because of the filtering that has been added by the manufacturer to generate signals in the low frequency band that do not really exist. Properly developed sensors ensure that the sensor technology used generates an accurate signal. Some technologies are better than others. One must also consider the fact that just because a manufacturer states a type of technology is being used, it is not a guarantee that the sensor will accurately reproduce the physiological signal being measured.”

Respected organizations such as the American Academy of Sleep Medicine (AASM) are always concerned with accuracy standards for things such as oral hypopneas. Bradley points out that the AASM did in fact come out with guidelines on oral hypopneas. Calling them “a great first stab” he laments that the guidelines could only go so far since there has not yet been enough research to substantiate measuring oral pressure.

Problems with Pressure
There are several different types of cannulae used to measure airflow to gauge the nasal and/or oral breathing component. “You’ve got the thermal side, so you can measure nasal and oral apneas because you’ve got a thermal sensor,” says Bradley. “However, you don’t have the oral component on the cannula, and that is something Braebon looked at and worked out. We have the PureFlow and PureFlow Duo cannulae, These cannulae have a big scoop designed to give you an accurate, almost 1:1 relationship between the nasal breathing and the oral breathing—as well as give you a reliable signal. The PureFlow combines both the nasal and oral component into one signal where as the PureFlow Duo, when working with the Braebon PT2 Dual Pressure Transducer, gives you separate oral and nasal signals. This family of cannulae will allow you to now look into oral breathing and be able to determine oral hypopneas or other phenomena that may be present in the oral signal and not in the nasal signal.”

There are a lot of technical issues in trying to grab oral pressure and accurately represent it, because engineers are not dealing with an enclosed system. “You’ve got leaks everywhere as well as the changing shape of the oral orifice,” laments Bradley. “The nasal one is a little easier because you design prongs that go in and they act like pitot tubes so you can measure the pressures and infer airflow fairly accurately. Even though people have different diameters on their nose, there is not that much of a change. But the mouth really changes shape throughout the night plus, it has been shown, people change their breathing patterns throughout the night between nasal and oral. They have even had studies showing that the person will actually change their breathing between left and right nostrils throughout the night. It is almost like we are just getting into the science of these types of things and it is all coming down to how can we easily and accurately measure the amount of air moving in and out of the patient.”

Determining the inherent truth in any testing scenario can be hampered by complacency, and Bradley believes that technology has been taken for granted for too many years. The answer is a deeper understanding and a renewed focus on issues such as filters, or even the positioning of sensors. “A tech may say the body position sensor does not work, but if you have a well endowed lady and you’re putting a body sensor on, then you have to be careful about how you put it on,” cautions Bradley. “Many body sensors out there will report standing when the person is lying down when the sensor is not within a few tens of degrees of horizontal.”

The upside of better understanding is that correcting problems during sleep tests can suddenly become easier. If a signal on the PSG goes flat, for example, it could be something as simple as sensor positioning, but all too often the problem does not get addressed as going in to fix something will take too long. “The technologist or physician may think s/he can’t interrupt the patient’s sleep, and I understand that,” says Bradley. “But if you need accurate quality information, you can go in and fix it—and get out quickly—if you know exactly what to look for. I would rather have somebody come in and wake me up for five minutes to fix something, so I know that we are going to have accurate data at the end of the night.”

It all goes back to knowing what you are working with. As another example, Bradley says he has visited a couple of labs were the filters were set so that they would get a nice looking waveform on their respiratory effort signals. The people in the lab wondered why at times there was almost no movement on the effort signals, yet they had flow and no desaturations. Ultimately, understanding the tools is critical to ensuring accurate data collection.

Speaking of Signals

As an inventor, Bradley is keenly aware of how signals are collected, interpreted, and represented. Variations in breathing, such as hyperventilation, can wreak havoc on some systems and these problems must be addressed. Indeed, with some manufacturers, hyperventilation will cause the signal to be completely filtered away. A good technologist wants to see that hyperventilation on the screen, but these limitations are often unknown until the equipment is sold and returns are a hassle.

As someone who has actually written many programs on RIP calibration, Bradley knows that unexplained signal changes can happen in some RIP systems when the output recalibrates on its own. “We take the actual output and recognize it as a one-to-one calibration,” says Bradley. “You take the chest and abdomen, add them together, and look at the sum. When you use our system, you can see what is going on and get an accurate indication of what is happening. You can know whether to trust the signal or not. In other words you know when you have adjusted gain on poor effort signal and can then make a properly informed decision to ignore or fix it.”

Tracking the nuances of human sleep is one thing, but predicting the future is an endeavor that Bradley and his colleagues rarely indulge. Admittedly reluctant to reveal Braebon’s plans, Bradley will concede that smarter sensors are likely on the horizon. “This is something we developed with our titration sensor for manufacturer Fisher and Paykel, where you have â€˜brains’ inside the sensor and it operates like a mini PSG system, digitizing the signal and processing the signal that is taken in,” reveals Bradley. “If you are measuring a pressure, you may translate it into an accurate flow signal that comes out. This is done within PSG systems, but I think you are going to see sensors start to build up and get real time information to the technicians.”

In the realm of pressure sensors, improved amplitude response could be on the horizon to accurately output a qualitative flow signal. Bradley laments that many sensors are not linearly proportional and lack a linear relationship between the input signal being measured and the output signal (what the sensor is sending out [See Figure 4]). This can cause issues when trying to make decisions based on relative amplitude comparisons.

ScreenShot053 Spotlight on Sensors

Some sensors are linear on the positive scale, but when they go negative they may end up changing the equation which equals a change in flow. “In that case, you would have a sensor that does not report on both the positive and negative side accurately,” says Bradley. “This is something that nobody really goes into and asks: What is the amplitude response of your sensor? How does it work compared to the physiological conditions I am trying to measure? How does the sensor’s output respond to the input? If I hold a constant flow, what is the amplitude output of the sensor? Is it linear? Is it a quadratic equation? Is it an equation that I can’t even define?” The quality of the oral/nasal cannula can directly influence the usability of information. For example, pressure loss due to a common chamber between the nose and the mouth can compromise the signal. While some techs may not understand these nitty gritty details, Bradley believes they can comprehend enough to help patients and make better choices when it comes to selecting equipment. “The bottom line is that if patients are going to undergo a medical test, they want to make sure that the person giving the test is using the best possible equipment,” says Bradley. “The best equipment is also the most accurate, and that means fewer misdiagnoses.”

__________________________________________________________________________________________Don Bradley is founder and chief technology officer for Braebon. He has worked in the sleep diagnostic industry for over 19 years. He has designed and developed many medical devices included PSG systems and sleep sensors and authored several articles in technical and research publications as well as given talks on technology in sleep.

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Filed Under: sensor technology, Sleep, sleep diagnostic, sleep medicine, sleep sensor, sleep study, sleep test, snore, Snoring, System Tagged With: sleep, system

Man vs. Machine

January 28, 2011 by SleepDT Leave a Comment

Giving Automatic Scoring a Second Thought

Changes in technology have been exponential over the last two decades. The sleep medicine industry has advanced significantly by software innovation. In our enthusiasm to wholeheartedly welcome these enhancements to our processes, we sometimes forget that technology in the form of automation is meant to assist, not replace, our skilled technologists.

To automate or not to automate the scoring of sleep studies remains an ongoing debate in our industry and with software giants looking for ways to expand service offerings, the discussion is unlikely to end any time soon. While the notion of computerized analysis holds the promise of decreased staffing costs and increased efficiency, the reality of this premise is far less simplistic. One would no doubt question the rationale behind the insistence that a plane does not require a pilot in light of autopilot technology. Yet there exists a movement that would apply such logic, resulting in the ultimate redundancy of scoring technologists.

Whether as a primary or secondary resource, a registered technologist is essential for an accurate analysis of a patient study—period.

Sleep medicine is still very much a human-centered industry. With over 80 different sleep disorders currently documented, nothing comes close to replicating the nuance and contextually- reliant assessments made possible by intensive, real-life training and experience.

Any sleep facility or homecare company that are uses automatic scoring as a one-for-one alternative to human analysis is neglecting the clinical aspect of patient care. What begins as a well-intentioned, cost-cutting measure emerges as a practice that risks undermining the credibility of an entire industry.

Like every industry, efforts to streamline business and make processes leaner are present in sleep medicine. What we are seeing, however, are moves to market such software as a turnkey solution—completely undermining the specialized nature of sleep scoring and the skills, knowledge and training that go into delivering this process. Laboratories that wish to remain reputable should take a critical look at automated scoring and question whether the absence of registered technologists involved in this process is putting patient care in jeopardy.

The Reality of No Regulations

None of this is to say that automated scoring is without value. On the contrary, it can prove to help the technologist become a more effective clinician—especially as automation matures and is improved.

Early detection, identification of irregularities, cost-efficiency and timely performance are just some of the benefits that automated systems bring to the table. To ignore these benefits would be denying progress for the sake of it. However, as the sleep industry is itself still coming of age, it remains vulnerable to unscrupulous business models that risk tarnishing an entire sector by making patient care an after thought.

Discount scoring services have gained significant traction with unsustainably low price points underwritten by unregistered and clinically inexperienced scoring staff. What such practices fail to respect is that scoring is far more than an objective matter of computation. There are qualitative factors that only trained, registered and clinically experienced technologists can assess.

With minimal regulation of the effects of automatic scoring currently in place, the credibility of an entire industry rests on education and best practices. While sleep medicine awaits increased governance to prevent such fly-by-nights from infiltrating a valuable healthcare service, automation could aid in the standardization of certain scoring processes. As long as laboratories incorporate the technology primarily as a labour- cutting device, it may prove to be detrimental.

Assist not Replace

Another area of concern lies in the homecare and home testing sectors. Level III sleep studies are being conducted and automatic analysis is being used for diagnosing patients going against the AASM recommendation to have a secondary review by a Registered Polysomnographic Technologist.

In such a case, automated scoring is not only the primary but the solitary mode of analysis. But scoring software can never comprehensively analyze a Level III study—results must be reviewed and assessed against clinical correlation. Software should be viewed as serving a complementary function in that it assists an RPSGT, who later verifies the automated scores manually and cross-references them with clinically-obtained observations.

Furthermore, one must consider the long-term impact of reliance on scoring software. Crucial information is gathered in the RPSGT’s current role as a front-line, integrated health- care professional. The knowledge and skills that arise from working with different patients and various symptoms and conditions could be lost should technologists be removed from the equation.

Know What You’re Getting Into

Pharmacists have also found their profession impacted by automated “advances”. The automated dispensing model they were recently introduced to have raised questions about accountability as dispensing errors can put patients (and businesses) at risk.

It goes without saying that human error can, has and will occur in any facet of healthcare. To be certain, accuracy is one of the dominant selling points of many automated systems used in other fields. However, the rush to market this form of technology may fail because the underlying technology is immature and needs time to evolve as it finds a permanent home within the sleep medicine industry. Even if automatic scoring technology matures to the point that algorithms can account for most variables, it still cannot contend with even the common clinical problems and complexities that come with sleep disorders in order to perform accurate scoring.

This is not to say that automatic scoring has no place in the streamlining of sleep laboratory operations. On the contrary, as time progresses and automated software has been tried and tested perhaps this may well become a fixture in sleep facilities.

But with no current regulations governing the use of such software, it is imperative that we consider the following disclaimer: automatic scoring exists to assist technologists, not replace them.

Natalie Morin, RPSGT is president and CEO of Sleep Strategies Inc., a provider of professional scoring and consulting services for sleep disorders facilities worldwide.

Filed Under: enthusiasm, Home Testing, identification, nuance, Polysomnographic, sleep diagnostics, sleep disorders, Sleep Lab, sleep medicine, sleep technician, sleep technologist Tagged With: AASM, enthusiasm, home testing, identification, nuance, Polysomnographic, Sleep Disorders, sleep medicine

Scientists Measure the Cost of Missing a Nights Sleep

January 20, 2011 by SleepDT Leave a Comment

Scientists have added up the cost of losing a nights sleep. By measuring the actual number of calories the body expends to fuel an all-nighter versus a good night’s sleep, researchers from the University of Colorado at Boulder calculate that a full night of sleep helps the body conserve as much energy as is in a glass of warm milk.

Missing a night of sleep forces the body to burn about an extra 161 calories than it would have during eight hours of sleep (not counting what’s used in moving around while awake), but it’s no weight-loss miracle: The body tries to make up for the deficit by saving more energy than usual the next day and night, researchers report in the January Journal of Physiology.

Energy Conservation as a Function of Sleep in Human Beings
One of the proposed functions of sleep is to conserve energy. We determined the amount of energy conserved by sleep in humans, how much more energy is expended when missing a night of sleep, and how much energy is conserved during recovery sleep. Findings support the hypothesis that a function of sleep is to conserve energy in humans. Sleep deprivation increased energy expenditure indicating that maintaining wakefulness under bed-rest conditions is energetically costly. Recovery sleep after sleep deprivation reduced energy use compared to baseline sleep suggesting that human metabolic physiology has the capacity to make adjustments to respond to the energetic cost of sleep deprivation. The finding that sleep deprivation increases energy expenditure should not be interpreted that sleep deprivation is a safe or effective strategy for weight loss as other studies have shown that chronic sleep deprivation is associated with impaired cognition and weight gain.

Read Full Article: Energy expenditure during sleep, sleep deprivation and sleep following sleep deprivation in adult humans

Filed Under: chronic sleep deprivation, energy conservation, journal of physiology, sleep apnea, sleep diagnostics, sleep disorder center, sleep disorders, sleep labs, sleep loss, sleep medicine, sleep physicians, sleep products, university of colorado at boulder, weight loss miracle

Sleep Health is one of the New Goals of Healthy People 2020

January 18, 2011 by SleepDT Leave a Comment

The Department of Health and Human Services has launched its Healthy People 2020 goals, and among the objectives set forth in its “ambitious, yet achievable” 10-year agenda for improving the nation’s health are substantial improvements in sleep health, respiratory disease outcomes, and levels of tobacco use.

Read Full Document Healthy People 2020: Department of Health and Human Services

Sleep Health
Sleep health is a new topic in the Healthy People initiative. The main focus is on increasing public knowledge of how adequate sleep and treatment of sleep disorders improves health, productivity, wellness, quality of life, and safety on the roads and in the workplace.

The public health burden is substantial, and awareness of the problem is lacking; thus, Healthy People 2020 seeks to provide a “well-coordinated strategy to improve sleep-related health.”

Objectives are to:

Increase the proportion of persons with symptoms of obstructive sleep apnea who seek medical care (from 25.5% to 28%).
Reduce the rate of vehicular crashes per 100 million miles traveled that are due to drowsy driving (from 2.7 to 2.1).
Increase the proportion of students in grades 9-12 who get sufficient sleep, defined as 8 hours or more on an average school night (from 30.9% to 33.2%).
Increase the proportion of adults who get sufficient sleep, defined as 8 or more hours for those aged 18-21 years, and 7 or more hours for those aged 22 years and older (from 69.6% to 70.9%).

Sleep is one of the three pillars to good health, along with exercise and balanced diet.

Source: HHS

Filed Under: Drowsy Driving, obstructive sleep apnea, respiratory disease, sleep apnea, sleep diagnostics, sleep disorder center, sleep disorders, sleep medicine, sleep physicians, tobacco, vehicular crashes Tagged With: tobacco

New Study: Reducing the Risk of Pulmonary Complications Among Patients with Sleep Apnea Undergoing Surgery

January 11, 2011 by SleepDT Leave a Comment

In patients with sleep apnea, perioperative pulmonary complications after orthopaedic and general surgery are significantly more frequent vs matched samples without sleep apnea, according to new research.

Stavros Memtsoudis, MD, with the Weill Medical College of Cornell University, in New York, NY, and colleagues reported their findings in the January 2011 issue of Anesthesia & Analgesia.

The current study of data from the National Inpatient Sample database was designed to compare perioperative pulmonary outcomes in patients with sleep apnea vs matched control participants and included 3,441,262 general surgery entries and 2,610,441 orthopaedic surgery entries collected between 1998 and 2007. Sleep apnea was diagnosed at a frequency of 2.52% and 1.40% for the 2 surgery types, respectively.

Read Abstract: Perioperative Pulmonary Outcomes in Patients with Sleep Apnea After Noncardiac Surgery2011 Jan;112(1):113-21

Filed Under: pulmonary complications, pulmonary outcomes, sleep apnea, sleep appliances, sleep diagnostics, Sleep Lab, sleep loss, sleep medicine, sleep physicians, stavros, treatment of insomnia, weill medical college of cornell university Tagged With: Stavros

CHEST Journal Launches free iPhone/iPad App to view Journal

January 11, 2011 by SleepDT 1 Comment

Unlike most apps released in scholarly publishing to date, this app handles all the content within the app (rather than referring users to the website for full text).

The CHEST Journal native iPhone/iPad app is feature rich:

Access the most recent issues, plus CHEST Papers in Press
Articles are optimized for the iOS, as well as available in PDF
Full-screen images, and figure/table only viewing options
Dynamic side navigation and internal hyperlinks allow users to jump within article sections, images, and references
Viewing history is tracked automatically, sorted by date viewed
E-mail article links to colleagues or self from any page
Mark and store favorite articles for later reference
Control article font size from any page

The app supports existing institutional and individual CHEST online subscriptions thru automatic IP authentication or username and password entry. The ACCP has made full-text access on the CHEST app free for users of these devices during an extended trial period.

Download from iTunes here: http://bit.ly/HWChest

Filed Under: insomnia, ip authentication, iPad, iPhone, iTunes, scholarly publishing, sleep apnea, sleep disorders, sleep labs, sleep medicine, sleep therapy Tagged With: IP authentication, iPhone

The Zeo Personal Sleep Coach – Raises $12.3 mm financing

January 11, 2011 by SleepDT Leave a Comment

Zeo a consumer device that enables people to track their sleep phases and calculate a daily sleep quality score called their ZQ. Zeo also offers highly personalized sleep coaching online and allows users to determine how their behaviors affect both the quantity and quality oftheir sleep. It is composed of a lightweight wireless headband, a bedside display, a set of analytical online tools, and an email-based personalized coaching program.

The company announced it has received $12.3 million in its third venture financing.

The mission of Zeo, Inc. is to help people discover new, scientifically-based ways to improve the quality of their lives through the power of sleep. Zeo will accomplish this by combining breakthrough personal sleep tracking technology, web-based tools and mobile applications with proven sleep coaching methods from both sleep and behavioral science. In 2010, Zeo won the Triple Tree Award for Best Consumer Experience in Wireless Life Sciences, as well as the prestigious Thomas Edison Award for Best New Product Innovation, presented by Discovery Channel. The Zeo Personal Sleep Coach is currently sold in the U.S. and the U.K.

For more information, visit www.myZeo.com.

Filed Under: insomnia, mobile applications, sleep apnea, sleep coaching, sleep diagnostics, sleep medicine, sleep products, sleep therapy, thomas edison award, Wireless Life Sciences, zeo inc Tagged With: Wireless Life Sciences

Benchmarking Improves the Sleep Business

January 11, 2011 by SleepDT Leave a Comment

Sweeping reimbursement cuts and a depressed economy have created a perfect storm where payors are now applying more rigorous requirements and heightened scrutiny to billing claims, and referral sources are more discriminating than ever. Fortunately, benchmarking can identify emerging trends in the industry while helping you gain an advantage.

There are many organizations dedicated to providing information and resources to businesses. Many business associations provide market research, industry benchmarks and statistics, as well as training and educational resources. Do an internet search for business associations in your region, or consult your local Chamber of Commerce or phone book.

Have a frank conversation with your competition about what changes they have seen. There is no need for either party to divulge business secrets, and a general dialogue can benefit both of you, as well as your customers. You might even find ways to partner together to address customers’ unmet needs.

Reach out to businesses in your area that have been successful and arrange to tour and meet with their management to see how they’ve solved business challenges. Many organizational difficulties transcend industries, and you may learn valuable lessons in unexpected places.

Whether your business has well-established benchmarking practices or you’re just beginning to gather data, ResMed’s Sleep Market Panel is a valuable, low-maintenance data source. The Sleep Market Panel was designed to provide you with objective industry data in a simple report.

To join the Sleep Market Panel, email sleepmarketpanel@resmed.com, visit www.resmed.com/smp or call our Sleep Market Panel team at (800) 424-0737, ext. 306101. There are no fees associated with membership.

Filed Under: depressed economy, ResMed, sleep apnea, sleep buisness, sleep diagnostics, Sleep Market Panel, sleep medicine, sleep physicians, sleep products, sleep therapy

Somté Features Holter-Type Sleep System

January 11, 2011 by SleepDT Leave a Comment

When engineers from Australia-based Compumedics developed the Somté, they knew cardiology was likely to play a growing role within sleep medicine. With this in mind, they developed a Holter-type sleep system that earned a 2006 Frost & Sullivan award for Technology Leadership.

Combining home sleep diagnostics with the optional capability for Holter ECG monitoring and pulse transit time results, is one reason the down-under designers earned the award. Most other home sleep testing (HST) units do not have the option, because they don’t record electrocardiography (ECG) signals.

Jeff Kuznia, vice president of North American Sales and Marketing for Compumedics, says the unit’s ability to record reliable data means that the equipment fits well into the Type 3 recorder market. Holter ECG monitoring exists as a stand-alone product, but the software development required to combine it with sleep makes it difficult for other companies to make a similar device.

Compumedics’ involvement in the Sleep-Heart Health Study sparked the original Holter idea, and there are no regrets—but still some work to do. “ Most cardiologists are aware of the connection between sleep disordered breathing and cardiovascular disease. However I do not believe that many have firsthand experience with managing sleep disorders, and may not appreciate the impact that sleep disorders have on cardiovascular disease, but also the effect of treating Sleep Disordered Breathing ‘SDB’ when it comes to managing many patients who suffer from complex hypertension or cardiac arrhythmias.”

Filed Under: compumedics, electrocardiography, Home Sleep, Home Sleep Testing, hypertension, Jeff Kuznia, sleep diagnostics, sleep disordered breathing, sleep disorders, sleep heart health, sleep medicine, sullivan award, Type 3

	Randy Clare Managing Editor of SleepScholar and RespiratoryScholar
	Dr. Steve Carstensen Pankey Institute for Advanced Dental Education, American Academy of Dental Sleep Medicine.
	Ruchir Patel MD Founder & Medical Director at the Insomnia and Sleep Institute of Arizona.
	Dr. John S. Viviano AADSM Diplomate and member of various sleep organizations. Has lectured internationally on the treatment of Sleep-Disordered Breathing and the use of Acoustic Reflection.
	Jeffroy Wyscarver President, DDME Online, Sleep Lab Technology and Services for the Dental Community.
	Claude Albertario RPSGT, speaker, author and mentor in the field of sleep diagnostics with 25 yrs of management experience in one of New York's premier sleep centers.
	Joseph Anderson Co-Founder and Director of Education for Priority Health Education and Priority Scoring.
	Todd Austin Managed sleep labs and has 15 experience in sleep diagnostics and therapeutic systems. .
	Marietta Bibbs Sleep specialist and manager of Sleep and Neurodiagnostics at Morton Plant Mease Healthcare.
	Bradley Eli DMD, MS Director, San Diego Headache and Facial Pain Center / Sleep Treatment and Research Institute
	Edward Grandi Executive Director of the American Sleep Apnea Association.
	Edward Michaelson MD Board Certified in Pulmonary Medicine, Internal Medicine and Sleep Medicine
	Ashley Truitt Founder & Director of Dental Sleep Medicine Worldwide, Co-Founder of TPT Dental.

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