The obviously high level of surgical care as related to general development was not maintained in the following centuries.

Conservative medicine always remained the reserve of academics. However, this only meant drug oriented noninvasive medicine. Diagnosis and therapy were based upon the humoral pathology of Galenos. Accordingly, the only “invasive” procedure was phlebotomy (bloodletting). Human diseases were treated with drugs, ointments, diets, or similar conservative measures. Surgical tasks, such as the treatment of fractures, open wounds, and hernia, were completely left over to the surgeons. Surgeons at that time were looked down upon and avoided by physicians since they were considered unlettered, lower class men, who learned their graft by apprenticeship (Fig. 1.1). In addition to surgery they often practiced as barbers as well. The situation improved only gradually. In England and in France surgical guilds were created. A main impact came again from the military since it was evident that contemporary warfare needed qualified surgeons. In 1724 a collegium medico chirurgicum was founded in Berlin (Charité) to provide sufficiently educated surgeons for the army. However, it took another century until it developed to academic surgery with full integration into the medical studies at the university. Famous names like Joseph Lister (1827–1912), Bernhard von Langenbeck (1810–87), and Theodor Billroth (1829–94) are representatives of this historical progress. From then on surgery achieved one triumph after another and is still considered today as the spearhead of medicine. However, this formally unchanged position is currently heavily in danger: Interventional medicine of today is characterized by the idea of further trauma reduction. Increasingly, open surgical procedures are replaced by minimally invasive interventions or even by interventional gastroenterology and radiology. In this very competitive environment surgery is forced to improve continuously its own therapeutic armamentarium. Otherwise, surgery may not survive as a discipline of its own right.

As shown in Fig. 1.1, scientific surgery has existed as an academic discipline for only 150 years. Retrospectively, this comparatively short period of time can be subdivided into three different eras (Fig. 1.2).

In the beginning, surgeons learned to master the specific challenges of the different anatomical regions—beginning with the abdomen and ending with the brain. In the next phase, surgery was not any longer confined to resection/amputation, etc. but the focus was now laid on substituting deficits: Destroyed joints were replaced by artificial implants, so-called pouches were developed to take over the role of the stomach, the rectum after resection, etc. The final highlight of the era was the transplantation of whole organs (heart, liver, kidney).

The trend of today is to further minimize the surgical trauma—collateral damage to other organs, functional impairment, and pain. This third era of surgery started with the introduction of laparoscopic surgery. Laparoscopy was, however, only the beginning of a broad development in many medical disciplines toward less trauma and lower invasiveness. Many surgical operations are now substituted by new interventions that do not need skin incisions, general anesthesia, etc. One of the classical surgical emergency cases in former days was, e.g., gastroduodenal bleeding from peptic ulcers, forcing the surgeons frequently to spend another few hours in the operating room (OR) during nighttime. This type of surgery has almost vanished from the surgical departments, since upper gastrointestinal bleedings are now treated successfully by interventional gastroenterologists who have learned to stop the bleeding from inside. Another impressive example of how surgery became superseded by nonsurgical interventions is portal hypertension. Blood perfusion of the liver is impaired in the case of liver cirrhosis. Prehepatic blood is deviated and induces life-threatening bleeding into the esophagus. The surgical answer was to create artificial shunts (portocaval shunts). Admittedly, shunt surgery was highly demanding and complicated. If the patient survived, the functional results usually were not particularly satisfying. Today, shunt surgery is obsolete. It has been successfully replaced by a radiological intervention called transjugular intraparenchymatous shunt. Surgery of portal hypertension is no longer an issue in surgery. Many similar examples exist.

This development will certainly continue and it is doubtful what will be left for traditional surgery (Fig. 1.3). One thing, however, is clear: In order to achieve further progress in medicine, the surgeons and physicians need more than ever the active support of basic sciences, engineers, and computer scientists. Without innovative tools and methods—delivered by biomedical engineering (BME)—the medical doctors will be unable to further improve their armamentarium of interventional therapeutic approaches. This is why an intensive continuous dialogue between science, development, and medicine is today mandatory. It has been shown that the translation of innovative surgical devices into the OR is markedly improved by this interdisciplinary interaction [1].

Fortunately, a corresponding response can be observed on the technical/scientific side: The community of natural sciences developed the concept of BME.

The definition of BME in brief:

Admittedly, this definition is not very sharp and could include almost everything. As a matter of fact, BME is the intersection of at least three mighty disciplines: medicine, engineering, and basic science. Like surgery or perhaps it would be better to say interventional medicine, many of the natural sciences like chemistry, biology, and the engineering had a long way to go in academic history to achieve the status of becoming their own academic disciplines. Therefore, it is little wonder, that the overlap of these three disciplines appears to be academically doubtful since it resembles too much pure application rather than science for its own right.

It is the question now of whether BME has got the chance at all to achieve in the long run an equal academic status to the other now well-acknowledged disciplines. In other words, whether BME can be released of its ostensibly scientific interiority and gain a well-respected place in the academic community (“academic emancipation”).

Disregard of natural science or even more of engineering is based upon very old traditions. Greece was the cradle of the classical academy. It is well known that only theoretical work like philosophy was considered as science. The reputation of productive physical work like producing food or building houses or ships was considered low. This point of view dominated academic reality in European universities for many centuries. They mainly comprehended only four faculties: Theology, law, medicine, and fine arts. Of course, the societies acquired in parallel considerable technical knowledge in all fields—in particular in mining, ship building, navigation, etc.—but the academic value of these impressive intellectual efforts was not recognized.

It took until the French revolution to come to the first educational institution for practical/technical knowledge. The highly reputative École Polytechnique in Paris was originally founded in 1794 to provide the army with well-trained pioneers for the engineer units, but later on, civilian professions were trained as well (Fig. 1.4).