Medical Imaging Device with Heat Dissipation and Method for Regulating Heat Generated within a Medical Imaging Device

1 . A medical imaging device, comprising a shaft comprising a distal tip, a proximal region, a longitudinal axis extending from the distal tip to the proximal region, an end face, and a shaft wall extending along the longitudinal axis and facing an environment; a light source for illuminating a viewing area, wherein the light source is accommodated in the distal portion of the shaft; an image sensor for recording image light captured from the viewing area, wherein the image sensor is accommodated in the distal portion of the shaft; a common heat transfer element with a first contact surface and a second contact surface; and a heat sink positioned proximally to the distal portion of the shaft; wherein the light source and the image sensor are respectively thermally connected to the first and second contact surface of the common heat transfer element, and an operating heat generated by the light source and/or by the image sensor is dissipated toward the proximal region to the heat sink by the common heat transfer element. 2 . The medical imaging device of claim 1 , wherein the light source and the image sensor are arranged in a sealed common compartment in the distal portion of the shaft, and wherein the heat transfer element is arranged at least partially in the common compartment. 3 . The medical imaging device of claim 2 , wherein the light source and the image sensor are arranged in a common plane. 4 . The medical imaging device of claim 3 , wherein a single cover glass is arranged in the end face for distally terminating the common compartment. 5 . The medical imaging device of claim 3 , wherein an imaging cover glass and an illuminating cover glass are arranged in the end face and distally terminate the common compartment. 6 . The medical imaging device of claim 1 , wherein the first contact surface and the second contact surface are arranged substantially parallel to each other, and wherein the end face and the contact surfaces are arranged inclined from an end plane arranged orthogonal to the longitudinal axis. 7 . The medical imaging device of claim 1 , wherein the first contact surface and the second contact surface are arranged at an angle to each other, wherein the first contact surface or the second contact surface is arranged parallel to the end face, and wherein the respective other contact surface is arranged substantially parallel to the longitudinal axis. 8 . The medical imaging device of claim 7 further comprising a prism or mirror, and wherein the light source or the image sensor is arranged on the first contact surface parallel to the end face and the image sensor or the light source is arranged parallel to the longitudinal axis, where the prism is configured to deflect the image light between the end face and the image sensor. 9 . The medical imaging device of claim 7 further comprising a prism or mirror, and wherein the light source or the image sensor is arranged on the first contact surface parallel to the end face and the image sensor or the light source is arranged parallel to the longitudinal axis, where the prism is configured to deflect an illumination light between the light source and the end face. 10 . The medical imaging device of claim 1 , wherein that the heat transfer element has a connection region directed toward the operating heat and a discharge region directed toward the heat sink, where the connection region is tapered relative to a shaft diameter and the discharge region is widened relative to the connection region. 11 . The medical imaging device of claim 1 , wherein the heat transfer element has a depression at the discharge region, the depression extending along the longitudinal axis and receiving at least a portion of the heat sink. 12 . The medical imaging device of claim 10 , wherein the heat transfer element has a depression at the discharge region, the depression extending along the longitudinal axis and receiving at least a portion of the heat sink. 13 . The medical imaging device of claim 11 , wherein the depression comprises a shared heat transfer surface in thermal contact with the heat sink, and wherein said heat transfer surface includes a surface parallel to the longitudinal axis. 14 . The medical imaging device of claim 12 , wherein the depression comprises a shared heat transfer surface in thermal contact with the heat sink, and wherein said heat transfer surface includes a surface parallel to the longitudinal axis. 15 . The medical imaging device of claim 1 , wherein the heat sink comprises of the shaft wall. 16 . The medical imaging device of claim 1 , wherein the heat sink comprises a heat pipe arranged along the longitudinal axis. 17 . A method for controlling and/or regulating a medical imaging device, comprising the steps of providing a shaft comprising a distal tip, a proximal region, a longitudinal axis extending from the distal tip to the proximal region, an end face, and a shaft wall extending along the longitudinal axis and facing an environment; providing a light source for illuminating a viewing area, wherein the light source is accommodated in the distal portion of the shaft; providing an image sensor for recording image light captured from the viewing area, wherein the image sensor is accommodated in the distal portion of the shaft; providing a common heat transfer element with a first contact surface and a second contact surface; providing a heat sink positioned proximally to the distal portion of the shaft; thermally connecting the light source and the image sensor respectively to the first and second contact surfaces of the common heat transfer element; and dissipating an operating heat generated by the light source and/or by the image sensor toward the proximal region to the heat sink via the common heat transfer element. 18 . The method of claim 17 , comprising the further steps of determining an operating temperature of the light source or an operating temperature of the image sensor by means of a first temperature sensor arranged in the light source or by means of a second temperature sensor arranged in the image sensor; comparing the determined operating temperature with a reference temperature to determine a differential temperature; and controlling or regulating a light output of the light source and/or an image output of the image sensor on the basis of the determined differential temperature. 19 . The method of claim 18 , wherein the light output or the image output is regulated such that the medical imaging device the differential temperature is essentially equal to the reference temperature. 20 . The method of claim 17 , comprising the further step of arranging the image sensor and the light source within a sealed common compartment.