Choosing the Right Surgical and Exam Gloves

A high percentage of healthcare professionals suffer from glove-related hand allergies. Clinical evidence shows that over 80 per cent of allergic contact dermatitis is attributed to a chemical allergy.¹ 

A chemical allergy is a reaction to specific allergens such as chemical accelerators used in the glove manufacturing process of both latex and synthetic gloves.² Using an accelerator-free glove can help prevent a user from suffering an outbreak. 

Clinically speaking a chemical allergy will present itself as red, irritated, cracked and itchy skin on and around the area of contact.

The chemical allergy response begins when the antigens, such as residual chemical accelerators, leach from the glove and penetrate the skin, triggering the formation of T cells sensitised to the specific antigens.

Repeated exposure to the antigen in individuals who are allergic results in the reactivation of sensitised T cells and incites the inflammatory response causing the symptoms of red and itchy skin.²

There are many ways to identify a chemical allergy, such as patch testing, diagnostic skin testing and blood or allergy testing. Once the chemical allergy is determined as the cause, the primary treatment is avoidance or minimisation of exposure to the allergen; however, there are also some medications and moisturisers that can help alleviate the symptoms.

DID YOU KNOW?

of reported glove-associated allergic contact dermatitis is attributed to chemical accelerators.⁵

of 954 respondents at AORN congress indicated that staff continued to have allergy issues even when they switched to gloves without natural rubber latex.⁹

Chemical

Reaction

Role in Glove Munufacturing

Thiurams

Account for 60% of accelerator-related skin irritation and are the primary cause of chemical allergy.³

The universal vulcanising agent for rubber is sulphur. Thiurams are ultra-fast accelerators and are the preferred primary accelerator for sulphur-cured rubbers with low unsaturation content. Thiurams are used as vulcanising agents in the absence of sulphur; the vulcanisates attain high degree of state of cure, exhibiting high tensile strength, lower elongation at break, higher rebound resilience and lower tear resistance.³ Because manufacturers can produce gloves containing thiurams in high quantities, the overall cost is low.

Dithiocarbamates / Carbamates

Account for 30% of accelerator-related skin irritation.³

Dithiocarbamate accelerators are widely used as ultra-fast accelerators for natural rubber latex-based compounds that absorb sulphur and facilitate cross-linking. They can also find applications as primary or secondary accelerators in most dry rubber-based sulphur-cured compounds.⁴

Mercaptobenzothiazoles (MBTs)

Account for between 1% and 5% of accelerator-related skin irritation.³

MBTs are a fast curing accelerator suitable for most common rubbers and contribute to tensile strength; the presence of stearic acid and zinc oxide is necessary for good cures. MBTs cause fewer cases of contact sensitivity.⁴

Diphenylguanidine (DPG)

Allergic reactions to this chemical are on the rise according to some recent reports.³

Diphenylguanidine is used as a secondary foam stabiliser in the silicofluoride foam process. It does not show better activity than thiuram and dithiocarbamates, but it does have better stability and also contributes to tensile strength. It is used as a complexing agent for the detection of metals and organic bases.⁵

The Next Evolution in Surgical Gloves

1947

First surgical gloves to contain powder, natural rubber latex and chemical accelerators

1983

First powder-free surgical glove but still contains natural rubber latex and chemical accelerators

1990s

First surgical glove not made with powder and natural rubber latex, but still contains accelerators

2016

Medline introduces next-generation surgical glove not made with powder, natural rubber latex and chemical accelerators

Allergy Assessment

Whilst skin prick tests are available to assess sensitivity, these are costly and time-consuming.

Many patients and staff are unaware of their latex allergy, so this makes effective risk assessments difficult to perform.

With this in mind, healthcare professionals may choose to use latex-free gloves as a precautionary measure, particularly because it is fairly common for latex allergies to build up over time or develop suddenly and unexpectedly.¹

Hospital Impact

Every time there is an incident involving latex gloves, it affects health, productivity and finances. Healthcare workers who have a latex allergy may have to deal regularly with dry, itchy and irritated skin; this could cause them to miss work because their hands are in such poor condition they cannot wear gloves.

When the regular staff is absent, temporary or external staff need to fill in. This could slow down hospital productivity and efficacy because they are not as familiar with the rounds, patients or policies.

From a financial point of view, the use of latex gloves could cost the hospital more money for treatments and creams for those effected by the allergy and increase the wage bills to external agencies.

Staff Safety

The health of staff is directly connected to smoothly running hospitals. Infection control is understandably a key aspect of patient care, which should be prioritised, but perhaps other issues such as allergic reactions are not as widely understood.

Asthma and other breathing problems are connected to the use of powdered gloves because of the potential airborne nature of the powder. Conjunctivitis and joint inflammation are also most commonly connected to the use of powdered gloves.³ 

Dry skin, which can be exacerbated or turn into Irritant Contact Dermatitis (ICD),⁴ becomes difficult to manage and treat if powdered gloves continue to be used by healthcare professionals.

Prevention of Germ Transmission

Concerns around the use of powdered gloves are common in regard to wound closure too. The issue here is simply that any tape used to close a wound is more likely to stick to a powdered glove than a non-powdered one worn by the physician.

The powder that coats the gloves binds with sweat and any mucous and this contributes considerably to the risk of infection being spread across clinical spaces. As the powder comes into contact with equipment and fittings, infection or germs can begin to spread and are hard to isolate. More chemicals are contained in and are used for making powdered gloves. These chemicals can cause an allergic reaction and also make it harder for existing conditions to heal. This impacts the clinician’s ability to carry out frontline duties of care, which in turn may contribute to staff shortages and related cost issues, such as having to pay for external agency staff.

The smooth running of clinical spaces means meeting the needs of patients and staff in cost-effective and efficient ways. The challenge of providing a safe barrier against dirt and infection can be successfully overcome, as can ensuring that allergic reactions are kept to an absolute minimum, but investment and the openness for change are necessary. Non-powdered gloves are a sure way of impacting both of these challenges with instant and far-reaching results.⁵

The risk of exposure to blood-borne pathogens is a major concern for surgeons and operating theatre staff. Although often undetectable to the human eye, microperforations in surgical gloves are large enough to allow pathogens to pass between the glove wearer and the patient and cause infection.

A recent study reported that over 80 per cent of all surgical glove perforations go unnoticed.¹ Another study reported that the incidence of glove microperforations increased with duration of wear.²

A proven method to reduce these risks is to double glove with a dark-coloured underglove.

Double Gloving Technique

While wearing a single glove protects the wearer from blood-borne infections, more protection is needed when needles and sharp instruments are involved, due to the high risk of punctures. Wearing two pairs of surgical gloves greatly minimises the risk of cross-contamination by adding an extra layer of protection.

VIDEO

Double Gloving Technique

How Does the System Work?

The wearer dons the specially designed darker-coloured underglove as the first layer of protection followed by a light-coloured or translucent overglove.

In the event that the outer glove is breached during surgery, blood and other fluids seep between the two glove layers, and the contrasting colour of the dark green underglove alerts the wearer to change gloves.

Changing gloves immediately following the breach minimises the risk of transmission of pathogens between the wearer and the patient.

While double gloving combinations are often a personal preference, it is highly recommended to use a different coloured underglove in order to spot the breach more quickly if the glove is punctured.