Medical Facilities Looking To Increase Utilization And Organization Of Exam Gloves

Exam gloves are a vital component of every exam room. Doctors, nurses and other medical personnel rely on exam gloves to keep themselves protected against contracting and spreading germs and infections. Because of the need for exam gloves, it’s important to have a way to store them in exam rooms that will help to keep the room organized and yet keep the gloves readily accessible. The best way to do that is by using a glove dispenser that is made from high-quality materials, making it durable and able to last for many years.

Exam gloves, or medical gloves are one of the most common features of any doctor’s office, exam room or hospital room. Using exam gloves is important to decrease the possibility of the spread of infection. Germs are prevalent everywhere, whether a medical professional is working with a patient’s blood, other bodily fluids, or simply when the patient is sick. A glove dispenser keeps exam gloves readily accessible, in a place that makes them easy to use. Glove dispensers help to remind medical professionals to use exam gloves every time they come in contact with a patient. Most hospitals and clinics recommend or even require for exam gloves to be worn with every patient interaction, so glove dispensers make it easier for doctors, nurses and other professionals to observe these requirements.

Few things are as irritating to a physician as an exam room that is cluttered and unorganized. In order to provide patients with the proper medical care, it’s imperative for every tool to be in its proper place. Not only does this make examinations and procedures easier and more efficient, but it also reflects well on the reputation of the facility. A glove dispenser in every room will ensure that gloves are kept in a safe and organized place, which aids in keeping the rest of the room always looking its best. Because of the fact that all exam rooms are different, the glove dispenser can be placed in a room in many ways. It can be placed on a counter top or mounted to the wall. If the room has glass surfaces, the glove dispenser can even be mounted to the glass using suction cups to keep it in place.

Many of our glove dispensers are made of acrylic and some are even clear, allowing the medical staff to clearly see what’s inside. They also come in two, three or four pocket glove dispensers, so each office or hospital can choose the size that’s right for their needs. In addition to our acrylic models, we also offer steel glove dispensers and wire dispensers. There are many choices to suit any type of room design or preferences.

In order to promote the frequent use of exam gloves, as well as keep exam rooms free from clutter, it’s important to use glove dispensers in the rooms. Glove dispensers will help to keep medical personnel healthy by encouraging the frequent use of exam gloves. They will also provide a durable and organized solution for keeping exam rooms looking their best at all times. If you have any questions or comments regarding this post, please feel free to leave a comment below.

Holmium Laser Glasses: Protecting Your Eyes While Offering Excellent Visibility

Are you working around a Holmium:YAG laser system? If so, it is important to protect your eyes with Holmium laser safety glasses. These Holmium Laser Glasses not only provide eye protection but also excellent visibility through clear lenses, allowing you to distinctly see while working with this type of laser.

Laser radiation emitted by medium to high-powered laser systems can leave a permanent effect to your vision and damage your eyes. According to ANSI standards, it is highly recommended that those working around class 3B and class 4 laser system wear the appropriate protective eyewear. It is crucial that all medical staff follow their facility’s laser safety guidelines, which can be provided by your laser safety officer (LSO). The holmium laser safety glasses (also known as KG5 filters) will keep the eyes of medical staff protected as they work with this specific laser system.

During a procedure or exam it makes it easier for medical personnel when they can clearly see through the lens of their protective glasses. The lenses in the Holmium laser glasses are made up entirely of glass, giving more durability and longevity to the glasses. Since this filter is constructed of clear glass, the laser safety glasses will protect against a wider range of wavelength frequencies and will allow more visible light. The following chart illustrates the wavelength frequencies, optical density, lens color and visible light transmission for the Holmium laser glasses:

WavelengthOptical DensityColorVisible Light Transmission
900-1000nm5+ClearExcellent Visibility
1000-1500nm7+ClearExcellent Visibility
1500-2400nm7+ClearExcellent Visibility
2900-10600nm7+ClearExcellent Visibility

Holmium lasers are powerful laser systems that are commonly found in a variety of medical, clinical and cosmetic facilities today. We understand how important it is to offer medical staff full eye protection and excellent lens visibility. Our holmium laser safety glasses are high-quality protective eyewear used in many holmium laser applications.

If you have any questions or comments regarding this post on holmium laser safety glasses, please leave a comment below!

Traveling With Your Lead Apron?

Many radiology technicians, doctors and nurses are traveling more often from one medical facility to another. Since the importance of using lead aprons continues to grow, it’s necessary to have your lead apron safe while traveling. An efficient and safe way to travel with your lead apron is with an apron carry bag

Many medical professionals stress about damaging their lead aprons as they travel. The apron carry bag conveniently holds and protects your lead aprons. Its tube shape design allows for the apron to be wrapped around a sturdy cardboard tube, while keeping the apron safe and secure. It is equipped with a carrying handle and shoulder strap to make traveling with a lead apron easier. If you are traveling with a group of people or afraid of misplacing your apron carry bag we recommend selecting the embroidery option for your name or initials. This bag is offered in an assortment of colors and designs to allow for personalization.

It is important to travel with an apron carry bag to avoid damaging your lead aprons or vests. Folding or creasing lead aprons can result in cracking, which will allow harmful radiation to pass through. By traveling with your lead apron you’ll have peace of mind knowing that it will provide full protection because it fits you properly. If you travel without a lead apron, the other hospital may not have a lead apron for your size which can increase the risk of radiation exposure.

The next time you have to travel from one location to the next with your lead apron, consider the apron carry bag to help keep you organized and your lead apron safe! If you have any questions regarding this post, please feel free to post below.

Eliminating Room For Error: The Diode Extended Laser Safety Glasses

Are your medical personnel and patients being exposed to diode, UV excimer and inGaAs laser systems? The diode extended laser safety glasses will protect your eyes from harmful radiation caused by these lasers.

When laser safety glasses protect against multiple laser systems they’re called combination filters (sometimes referred to as a broadband or multi-wavelength combination filter). When your medical personnel are working with multiple laser systems during a procedure or treatment, combination filters are really the best approach. While wearing combination filters, there is less room for error for wearing the wrong glasses with the wrong laser. The adverse side of combination filters is that whenever a multi-wavelength glass or polycarbonate is created, the material will be slightly darker in color to incorporate the necessary protection.

Safety should be the first priority around all medical laser systems. Your facility can eliminate room for error by purchasing laser glasses that correlate with your laser system(s). The diode extended laser safety glasses and goggles will protect your eyes at the following wavelength ranges when working with your diode, UV excimer and inGaAs laser systems:

WavelengthOptical DensityColorVisible Light Transmission
190-420nm6+Green64%
660-780nm2+Green64%
745-1115nm3+Green64%
800-904nm5+Green64%
905-1075nm6+Green64%
10,600nm 6+Green64%

Since these laser glasses are protecting against multiple lasers at various wavelength ranges, the color of the lenses will be slightly darker. The lenses are a green color and transmit 64% visible light. Both medical personnel and patients should be required to wear these laser glasses. Medical laser systems are typically medium to high-powered systems, which if exposed to can have damaging effects on your eyes.

Medical laser systems will to continue to be an essential piece of equipment in many medical facilities. It’s important to ensure laser eye protection among both staff and patients when working around any laser system.

If you have any questions or comments regarding this topic, please feel free to post below!

Why Your Surgical Inventory Count Is So Important

Oftentimes surgical instruments can be accidentally thrown away, misplaced or lost on the operating room floor. In worst case, surgical instruments can be accidentally left behind inside a patient’s body following a surgery. Many believe that by implementing a thorough surgical inventory count process you will decrease reported foreign object (RFO) findings inside patients and will also reduce cost for lost inventory in the operating room.

Not only can retained surgical instruments risk your patient’s safety but it also runs the possibility of costing your medical facility a lot of money in the long term.

By establishing required inventory count guidelines in your facility you can eliminate the possibility of leaving surgical instruments behind. Hospitals and medical facilities will make their operating rooms safer for patients, more productive for surgeons, nurses and OR management and will produce less risk for hospital administrators. Depending on your facility’s inventory system, it is always important to keep a few basic rules in mind.

  • Initial count of surgical tools should match your final count.
  • Counting practices should be standardized across all operating rooms within a facility.
  • It is common that new tools can be added to a surgery, in which case these tools should be added to the count sheet or tracking system for final count purposes.
  • The OR team should know who is performing the inventory count prior to the start of surgery. It is typically performed by two or more people (circulator nurse, scrub nurse, technician, etc.) to ensure accuracy.
  • The surgery should not be reported as complete until the final inventory count is done and all surgical tools are accounted for.

There are many products that will assist in retrieving lost tools that may have been dropped on the floor. For example, the operating room attractor magnet can be used to easily pick up metal tools. This device can be very useful in the operating room since many surgical tools, such as suture needles and tips, can be extremely small in size and difficult to find. The operating room attractor magnet can pick up these objects from the operating floor or from underneath objects using its high lifting capacity of ferrous metal.

Standardized counting practices of your OR’s surgical tools will be beneficial to both the medical facility and patients. If you have any questions or comments regarding the importance of your surgical inventory count in the OR, please let us know below.

Retained Surgical Instruments In The Operating Room

A retained surgical instrument simply means that a surgical item was accidentally left behind in a patient’s body during surgery. Such incidences are suspected to be commonly under reported and are considered to be a preventable medical error.

What types of surgical instruments are being left behind? The list of possible retained surgical instruments is large including needles, clamps, scalpels, sponges, towels, scissors, tweezers, forceps, scopes, measuring devices, suction tips and tubes, etc. A surgeon is estimated to use between 250-300 surgical tools throughout a surgery. This number can drastically increase depending on the type of surgery and length of surgery time.

The contributing factors leading to the misplacement of surgical tools left behind inside a patient’s body can vary. Many consider that human factors such as fatigue for medical staff, chaotic environments and lack of tools for the inventory process have directly resulted in the loss of expensive surgical tools.

The effect of losing a surgical instrument in a patient’s body during surgery can range from essentially harmless to life threatening. Patients can experience infections, punctured organs and blood vessels, additional surgeries and other medical complications. The effect that this type of incident can have on a hospital or healthcare facility can be very serious. This can include possible legal ramifications or a high cost in lost equipment.

There are many products that will help assist your staff in retrieving lost tools. Surgeons, nurses and technicians oftentimes use radiopaque sponges and towels. Radiopaque items can be detected by an x-ray, which presents the OR team another way of detecting lost surgical items inside a patient’s body.

Remember that leaving behind surgical tools in a patient’s body after surgery can be prevented by implementing extra safety precautions throughout your facility. If you have any questions or comments about retained surgical instruments, please let us know below!

Fashion Forward Radiation Protective Eyewear

The current designs in radiation eyewear not only offer the highest eye protection, but also accommodate the latest eyewear styles of today. With this growing trend, it has become more common to find stylish lead glasses to protect your eyes against harmful radiation.

All medical personnel should feel comfortable wearing radiation glasses (commonly known as lead glasses) since it may be necessary to wear them for a long period of time. Considering individual preferences is an important factor in the medical workplace. Medical personnel directed to wear lead glasses often include physicians, radiologists, technicians and hospital staff.

Our most fashionable collection of lead glasses consists of the Wiley-X product line. Throughout this line you will find sleek wrap around designs offered in a few stylish colors. The variation of colors can be helpful to quickly identify a particular pair of glasses from others. The Jake Wiley-X Wrap Around glasses are available in both classic black and brown fade. With each uniquely designed frame you will find key features that set these lead glasses apart from many. The Wiley-X line also incorporates a sporty durable frame found in the Blink Wiley-X Nylon Wrap Around glasses, which will remain securely in place during any medical procedure or exam.

Many might question:  these stylish designed frames look and feel great, but are they going to fully protect my eyes against radiation? The answer is yes. We offer both style and safety in every pair of lead glasses. Each come with lead impregnated lenses that offer the industry standard .75 millimeter lead equivalency that will protect your eyes from harmful radiation.

To keep your lead glasses organized, a protective case, adjustable strap and microfiber pouch is included with many pairs. Remember to keep in mind lead glasses can be fashionable, stylish and functional.

Dye Laser Systems In The Medical Field

Are you working around a Dye Laser? This post will highlight why dye lasers are used along with some key safety measures to follow in your facility.

Dye Lasers, invented in the 1960’s, use an organic dye (usually in a liquid state) as the lasing medium. Dye lasers are widely used in scientific, medical, industrial and military applications. The organic dye molecules are dissolved in a solvent, which is continuously circulated through the laser chamber. The lasing medium is then pumped by flash lamps or other lasers, emitting laser radiation.

Dye lasers are used in a plethora of medical procedures and applications. Some of these medical applications include dermatology, cosmetic, cardiology, laser treatment of vascular lesions, laser angioplasty, lithotripsy, thermolysis, urology, laser cancer phototherapy and diagnostics.

Laser safety measures should be established in all health care facilities where Class 3B and Class 4 lasers are used. According to ANSI (American National Standards Institute) and OSHA (Occupational Safety & Health Administration), dye laser glasses should be properly worn during dye laser procedures. It’s important to match your laser glasses to your operating laser system, which will give you the highest protection. You should try to accommodate  individual preferences since frames are offered in a variety of stylish designs (goggles, wrap-around, aviator, fit-over, etc.)

To keep your laser safety glasses or goggles safe, it is recommended to store them in a protective unit. A unit similar to the Large Safety Glasses Dispenser, can hold up to 10 pairs of safety glasses and can be wall-mounted or set on a tabletop. All laser procedures should take place in a controlled area and it is important to properly identify these controlled areas with warning/safety signs. These signs should be easy-to-read and close to the entrance of the area to alert medical staff and patients.

The future of the dye laser will continue to be a prominent system used today. This technology has made significant advances in the medical industry since it was first invented. Remember, with all high powered laser systems you must consider all laser safety measures.

Attenuation Of Radiation

Is your radiation shielding really protecting you? Sometimes we see situations where no protection is needed. Other times a full wrap apron is required.  So as a patient, doctor, or radiology technician how does one know if they are being properly protected?

Radiation on a Molecular Level

In order to understand radiation protection we would like to briefly educate you on the science of x-rays and why they can be dangerous. Exposure to different energies can affect the human body in various ways. When we are exposed to high levels of energy there can be negative side effects. For instance light rays can blind, sound waves can cause deafness, and heat waves can burn. Similarly, negative side effects may result from exposure to x-ray energy, but why? All matter is made up of atoms. When x-ray energy collides with atoms its effect depends on the strength of the ray and the type of atom encountered. When the interaction causes an atom to lose an electron, an ion, or electrically charged atom is formed. This is the negative effect of radiation exposure because electrically charged atoms are able to break DNA chains. Broken DNA either dies or mutates, which can lead to cancerous cells and birth defects.  Due to the fact that alteration of human cells is a possible outcome of radiation exposure, it is imperative to take all proper protective measures against overexposure.

Proper Protection

When referring to radiation protection, a common misunderstanding is the thicker the protective barrier, the better. Yet, this is not true. Yes, thickness plays a role in protection, but the attenuation factor is the main focus. Remember, attenuation is the measurement of absorbed and deflected energy as it passes through a material. (To understand the basics of attenuation read our “What is Attenuation” blog post.) Let’s equate the attenuation theory to a well known item: sunglasses. If you are picking out a pair of sunglasses to protect your eyes from sun damage, your main focus is the tint of the lens, not its thickness. Light is absorbed by dark colors, so the darker the tint of the lens, the less light will pass through to your eyes. Thousands of sunglasses offer the same lens thickness, but the attenuation of light varies most with the lens’ tint. The same concept applies to radiation protection. Just like different lens tints attenuate light rays, different materials attenuate radiation energy.

So what are effective radiation attenuating materials? The truth is that even air attenuates radiation to a degree, because every element attenuates radiation to some extent. Through research and development, it has been concluded that when it comes to radiation attenuation, the most effective elements are the metals. When this fact was discovered, lead was inexpensive and readily available, so lead aprons were put to use.  Lead quickly became the industry standard for radiation protection and the term lead equivalency evolved as the measuring tool used to gauge the effectiveness of radiation protection. Lead aprons are comprised of a matrix of lead and PVC (to give the lead durability).

 This matrix is then formed into sheets and layered for stronger attenuation and increased flex. So what is the downside? You likely already know it – Protective Apparel that only uses lead as the attenuating metal is HEAVY! Prolonged use can cause back and shoulder injuries for personnel required to wear the aprons day in and day out.  The radiation protection industry solved this problem by developing light weight and non lead aprons that protect just as well as the original lead aprons. Lightweight aprons utilize a combination of lead and non lead elements to achieve effective protection levels. Non Lead Aprons use only nonlead elements to achieve effective protection levels. Some of the nonlead elements found in the lightweight and lead free aprons on the market today are tin, bismuth, aluminum, barium, and titanium. These metals are able to attenuate x-rays efficiently while still meeting the original lead equivalency standard. Tin, a lighter weight metal, is combined with lead to create light weight aprons, which reduces stress on shoulders and the lower back. Nonlead aprons not only provide the lightest weight option, due to their lack of lead content, they are considered non-hazardous and can be safely disposed of without fear of environmental impact. The reason there has not been a strong push for adopting these lightweight and nonlead forms of protection is due to a misunderstanding of the attenuation process. Many medical imaging personnel believe lead is the only material that can attenuate radiation effectively.  Now that you know that many metals effectively attenuate radiation energy, you can make a better informed decision about the protective apparel you choose.

Prior to revealing the dangers of cell mutation, uncontrolled amounts of x-rays were being used for various purposes. In fact, in the 1920s you could walk into a shoe shop and take an x-ray of your foot inside a shoe to find a perfect fit! Shielding ourselves is not the only precaution we can take to protect ourselves from harmful x-ray exposure. Equipment manufacturers have developed x-ray machines with the ability to: control the direction of the radiation beam, limit exposure time, and adjust the power of radiation. The main goal in medical imaging today is to expose patients to the bare minimum amount of radiation and still obtain optimal results. You may hear the term ALARA which stands for As Low As Reasonably Achievable. An example of this would be x-raying a child as compared to an adult. Because a child is smaller there is less mass present for the x-ray to penetrate. So the imaging professional can lower the typical adult power level of the x-ray machine and still obtain optimal results.

Anyone working around radiation should ensure they are aware of the levels and frequency with which they are exposed.  Understanding exposure and your risk will ultimately allow you to select the proper protection apparel. The attenuation concept is a major focus in radiology and the more we understand about its nature, the further we can advance radiation practices with the correct equipment and protection. If you are ever administering or receiving an x-ray and you are concerned about radiation protection, have no fear if lead is nowhere near. The attenuation concept is still in play when other metals are used. Product manufacturers are meeting standards to protect you from unnecessary radiation damage while preventing shoulder and back injuries!