A breast pump is a mechanical device that lactating women use to extract milk from their breasts. They may be manual devices powered by hand or foot movements or electrical devices powered by batteries or electricity from the grid. Breast pumps, like lactation rooms, are most common in the United States.
Video Breast pump
History
On June 20, 1854, the United States Patent Office issued Patent No. 11,135 to O.H. Needham for a breast pump. Scientific American (1863) credits L.O. Colbin as the inventor and patent applicant of a breast pump. In 1921-23, engineer and chess master Edward Lasker produced a mechanical breast pump that imitated an infant's sucking action and was regarded by physicians as a marked improvement on existing hand-operated breast pumps, which failed to remove all the milk from the breast. The U.S. Patent Office issued U.S. Patent 1,644,257 for Lasker's breast pump. In 1956 Einar Egnell published his groundbreaking work, "Viewpoints on what happens mechanically in the female breast during various methods of milk collection". This article provided insight into the technical aspects of milk extraction from the breast. Many Egnell SMB breast pumps designed through this research are still in operation over 50 years after publication.
Archaeologists working at a glass factory site in Philadelphia, Pennsylvania, excavated a 19th-century breast pipe that matches breast pumping instruments in period advertisements.
The value of the global breast pump market is anticipated to be around US$ 2,100 Mn by 2027, expanding at over 4.6% CAGR during the forecast period 2017-2027.
Maps Breast pump
Reasons for use
Breast pumps are used for many reasons.
Many parents use them to continue breastfeeding after they return to work. They express their milk at work, which is later bottle-fed to their child by a caregiver. This use of breast milk is widespread in the United States, where paid family leave is one of the shortest in the developed world. American historian Jill Lepore argues that the need for so-called "lactation rooms" and breast pumps is driven by the corporate desire for parents to return to work immediately rather than mothers' wishes or babies' needs.
A breast pump may also be used to stimulate lactation for women with a low milk supply or those who have not just given birth.
A breast pump may be also used to address a range of challenges parents may encounter breast feeding, including difficulties latching, separation from an infant in intensive care, to feed an infant who cannot extract sufficient milk itself from the breast, to avoid passing medication through breast milk to the baby, or to relieve engorgement, a painful condition whereby the breasts are overfull. Pumping may also be desirable to continue lactation and its associated hormones to aid in recovery from pregnancy even if the pumped milk is not used.
In a 2012 policy statement, the American Academy of Pediatrics recommended feeding preterm infants human milk, finding "significant short- and long-term beneficial effects," including lower rates of necrotizing enterocolitis (NEC). When infants are unable to suckle, mothers can pump if they wish their babies to be fed (via naso-gastric tube) with the mothers' own milk.
Expressing milk for donation is another use for breast pumps. Donor milk may be available from milk banks for babies who are not able to receive their mothers' milk.
Efficiency
The breast pump is not as efficient at removing milk from the breast as most nursing babies.
Research done at Stanford University in 2009 showed the correlation of various factors with the volume of milk production in mothers of preterm babies (born before the 31st week of gestation). The research found that breast massage in addition to a breast pump (a technique called "hands-on pumping", or HOP), along with other factors correlated to higher milk production. The study found that mothers who used massage techniques and hand expression more than 5 times a day in the first 3 days after birth increased their milk production 8 weeks later, milk production increased 48%. The authors produced a video showing the technique and states that this technique is good for both mothers of premature infants as well as mothers that return to work or pump for other purposes.
A second article on the same study found that the combination of HOP techniques increased the fat content of the milk expressed.
Mechanical properties
Mechanically, a breast pump triggers the milk ejection response or "letdown". A misconception is that the breast pump suctions milk out of the breast. Pumps achieve letdown by using suction to pull the nipple into the tunnel of the breast shield or flange, then release, which counts as one cycle. Thirty to sixty cycles per minute can be expected with better-quality electric breast pumps. This section-release cycle can also be accomplished with hand pumps, which the nursing parent operates by compressing a handle.
Most manufacturers make multiple sizes of nipple tunnels ranging from 24mm to 36mm.
There are several pump mechanisms. Piston pumps draw a piston through a cylinder to create suction. These tend to operate at low speed, have high reliability, low noise, and long life. Rotary vane pumps use a cam with retractable vanes to create suction and are no longer widely used. Fast-diaphragm pumps use a diaphragm that is acted on by a lever, and can operate at thousands of cycles per minute. They tend to be noisy. Slow-diaphragm pumps use a larger diaphragm operated by a cam or lever to generate suction with each stroke. Pumps have also been designed that use venturi effects powered by a faucet or water stream, wall suction in hospitals, or oral suctioning.
Manual breast pumps
Manual breast pumps are operated by squeezing or pulling a handle in a repetitive fashion, allowing the user to directly control the pressure and frequency of milk expression. Though manual pumps are small and inexpensive, they can require significant effort and can be tiring because the user provides all the power. These pumps may not provide sufficient stimulation and emptying of the breast. "Bicycle-horn" style manual pumps can damage breast tissue and harbor bacteria in the rubber suction bulb, which is difficult to clean.
Foot-powered breast pumps use the same collection tubing and breast horns as electric breast pumps, but are powered by a foot pedal. This eliminates the work of pumping by hand or the need for finding an electrical outlet with privacy.
Electric breast pumps
There are two types of electric breast pumps, hospital-grade and personal-use. Hospital-grade pumps are larger and intended for multiple users. Personal-use pumps are generally intended for one user. Electric breast pumps are powered by a motor which supplies suction through plastic tubing to a horn that fits over the nipple. The portions of the pump that come into direct contact with the expressed milk must be sterilized to prevent contamination. This style provides more suction, making pumping significantly faster, and allows users to pump both their breasts at the same time. Electric breast pumps are larger than manual ones, but portable models are available (e.g. in a backpack or shoulder bag). Some models include battery packs or built-in batteries to enable portable operation of the pump. Some electric pumps allow multi-user operation, but recommend an accessory kit for each user to maintain cleanliness.
Rental pumps may be recommended when medical conditions temporarily preclude breastfeeding.
Some breast pumps are designed to be part of a "feeding system" so that the milk storage portion of the pump is the baby bottle used to feed the infant. This allows the milk to be collected in the same bottle that will feed the baby eliminating the need to transfer breastmilk. Freezable breastmilk storage bags are available that connect directly to some breast pumps and can then be used with disposable bottle feeding systems.
Pressure range and safety
Egnell in 1956 established a 220 mmHg safe maximum for automatic cycling pumps; however, there have been reports of sensitive breasts and nipples at much lower pressures. Hartman P, et al. in the 2008 study showed that the maximum comfortable vacuum enhances milk flow and milk yield.
Open collection systems vs. closed collection systems
Pump designs are referred to as either open or closed based on whether there is a barrier between where the tubing connects to the pump and where milk flows into the pump. The plastic tubing and horn of an electric breast pump are commonly referred to as the collection system and typically supply the pump's suction.
A closed collection system has a barrier or diaphragm that separates the pump tubing from the horn. In this design, the suction of the pump motor lifts the diaphragm to create a vacuum within the collection system to extract milk.
In contrast, an open system does not have a barrier between the tubing and the horn. Bacteria and viral filters may be present to prevent contamination or overflow into pump motor. The pump motor's suction is directly passed to the breast versus indirectly as with closed-diaphragm systems.
Open-collection systems can cause milk to overflow into the collection system tubing, and milk particles being drawn into the pump motor. If milk leaks into the pump's tubing, the tubes should be washed, sterilized and air-dried prior to using the pump again. Failure to thoroughly clean collection tubing may lead to mold growth within the tubing. Some models of pumps have bacteria and overflow filters which prevent milk from entering the tubing.
A subtype of the open-collection system is the single-user suction source. These pumps have added hygienic benefit in that all the parts that generate the suction and come in contact with breast milk stay with the mother. The parts that generate the suction are external to the pump, and can be removed, preventing cross contamination. These pumps are considered "hospital grade" and virtually eliminate the chance of cross contamination of the pump from user to user. However, it is important to clean the diaphragm as condensation or milk reaching this part can cause bacterial contamination.
A disadvantage of the diaphragm is that it may limit the amount of air/suction available to extract milk from the breast. It may also not be able to compensate for larger shield sizes.
There are no studies comparing the open- versus closed-system design. Most information in marketing materials by breast-pump manufacturers is offered without studies to back them up.
Milk collection and storage
Most breast pumps direct the pumped milk into a container that can be used for storage and feeding. Some manufacturers offer adapters to fit a variety of types and sizes of bottles, enabling more flexibility to mix and match products of different brands.
The expressed breast milk (EBM) may be stored and later fed to a baby by bottle. Expressed milk may be kept at room temperature for up to six hours (at 66-72 degrees Fahrenheit, around 20 degrees Celsius), refrigerated for up to 8 days, or frozen for 12 months in a deep freeze separate from a refrigerator maintained at a temperature of 0 degrees Fahrenheit or -18 degrees Celsius. Expressed milk may be donated to milk banks, which provide human breast milk to premature infants and other children whose mothers cannot provide for them.
See also
- Lactation suppression
- Wet nurse, a woman who feeds a baby who is not her own
References
External links
- Collecting and storing breastmilk - California Department of Health Services
- Storing Breast Milk/Thawing Frozen Breast Milk - City of Toronto Health Department
- La Leche League International
Source of the article : Wikipedia