Monthly Archives: March 2020

Saving Lives – Medical Manufacturing

Think for a moment about all the medical procedures that are available to us. From replacing joints and bones to all organs, the ability of modern medicine is no less amazing. However, when it comes to drug innovation and constant surgery, a number of industries must compensate for the surprising progress we have witnessed over the years. One such industry is the medical manufacturing industry.

Right around the turn of the 19th century, the process of anesthesia rapidly spread throughout the modern world, along with the spread of antiseptics (pioneered by Joseph Lister). With these two milestones and the widespread adoption of rubber gloves, the number of hospitals in operation spread and medical knowledge grew along with them. This laid the groundwork for one of the biggest booms in medical knowledge to occur during the 20th century.

For example, in 1926 the first pace maker design was devised. This device was not anywhere near the technology we might expect today. Back then, the early pacemaker was intended to be plugged into an electrical outlet, with a needle plunged into the cardiac chamber. After that, Albert Hyman – an American physiologist devised and coined the term for what would become a model for the modern pacemaker. His version was an electro-mechanical instrument that was powered by a spring-wound hand cranked motor. As the years progressed, this design was continually improved to the point where implantable pacemakers began to be manufactured for actual use.

Devices like the pacemaker and other intricately designed medical components put the medical manufacturing industry in a position to help medicine continue to innovate. While many aspects of the industry focus on actually producing these components, many of them also focus on the actual delivery and protection of high precision medical components ranging from pace makers and hip replacements to pins, rods, screws, and more. For instance, the medical device packaging industry has spent years researching operating room procedure to develop ideal packaging for critical medical devices. In the fast paced environment of the modern operating room, doctors and nurses can’t afford to waste time with unintuitive medical packaging, this is one area where the medical manufacturing industry helps streamline the process.

Care providers, doctors, nurses, and patients all rely on a wide variety of products – and medical products don’t all have to be incredibly advanced. While a pace maker is a good example of a high profile medical product, medical manufacturing also provides a number of additional necessities ranging from plastic products used throughout the hospital to medical foam used for therapy and rehabilitation. So next time you’re waiting in a doctor’s office or hospital, take a moment to consider the many years of innovation that have gone into making medical technology what it is today. From what modern doctors are capable of to the level of comfort we’ve come to expect for procedures ranging from a simple check-up to an organ transplant.

While many years of medical science and research are behind many of the things that might happen today, it is difficult to overlook the vital role played by modern medical manufacturing. Just imagine, without sophisticated medical manufacturing, the discovery of doctors and scientists around the world would not have the chance to change our lives. Pacemakers will not see the way to hospitals around the world, and medical technology conceptualized every year will not have the opportunity to develop in the real world.

Manufacturing

Manufacturing is a branch of industry which accounts for around a quarter of world economic activity. This is an application of tools and processing media for the transformation of raw materials into finished goods for sale.

Manufacturing includes all intermediate processes required for the production and integration of a product’s components. Some industries, such as semiconductor and steel manufacturers use the term fabrication instead.

The geographical concentration of the manufacturing industry is changing. The industrial capacity of many of the world’s wealthier nations is shrinking, accompanied by a corresponding loss of jobs, due to the relocation of enterprises to lower-wage countries.
Manufacturing objectives incorporate such things as cost, quality, delivery and flexibility and usually there are trade-offs between them. Trade-off decisions are also necessities in a number of key areas enabling patronage of the manufacturing objectives.

These decision areas may include plant and equipment; production, planning and control; labor and staffing; product design / engineering; and organization and management.

In manufacturing, quality control and quality engineering are involved in developing systems which ensure that products or services are designed and produced to meet or exceed customer requirements and expectations. These systems are often developed in conjunction with other business and engineering disciplines using a cross-functional approach.

Manufacturing requires that products’ specifications should be in balance with the needs and implications suggested by the consumers. Specification target values can be superficially founded to surpass the competition without regard to cost or the value proposition. Less pondering may be applied to trade-offs among product parameters because these just lead to additional cost and developmental effort.

Innovation-based companies try to focus on pushing a technology into the marketplace without truly comprehending and addressing customer needs. Boundless research should be conducted to meet the rapidly evolving consumer demands.

Manufacturing is under a lot of pressure. Since the realization that manufacturing actually has a strategic role to play in many firms, internal and external conditions continually pose pressure for fast and intelligent development of manufacturing. For many industrial firms, competitive environment is changing, getting tighter. The concept of manufacturing strategy is getting more imperative due to the forces of technological push and market pull.

Lately, an immense number of new concepts related to manufacturing have come to existence to further expand and challenge traditional perceptions of manufacturing, the content of manufacturing strategy and how decisions on manufacturing strategy should come about.

The ”best practice” or ”world class manufacturing” tradition is one perception which is being challenged from several angles. Another, is in the form of ”production philosophies”. These argue in a more conceptual manner for manufacturing systems beyond our traditional perceptions, as in vigorous, angular, and so on.

In short, the traditional ways that we have recognized as manufacturing are disintegrated and analyzed–to give way to mass production and customization, for instance, can be combined in the same manufacturing system.

To bring manufacturing to its supreme functionality, strategic emphasis should be shifted from cost to quality. As advances in manufacturing technologies come to be, its scope should also expand including the design of an organization’s production, product quantity for each facility, and scheduling rules.